1986_NEC_Linear_Products 1986 NEC Linear Products
User Manual: 1986_NEC_Linear_Products
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NEe NEe Electronics Inc. LINEAR' PRODUCTS 1986 • DISTRIBUTED BY IIkvshaII San Francisco Division 336 Los Coches Street Milpitas, CA 95035 Electronics Group Claude Michael Group (408) 943-4600 (408) 943-4700 NEe Electronics Inc. NEe 1986 LINEAR DATA BOOK February 1986 NECEL-000413 Stock No. 200100 ©1986 NEC ELectronics Inc./Printed in U.S.A. No part of this document may be copied or reproduced in any form or by any means without the prior written consent of NEC Electronics Inc. The information in this document is subjectto change without notice. Devices sold by NEC Electronics Inc. are covered by the warranty and patent indemnification provisions appearing in NEC Electronics Inc. Terms and Conditions of Sale only. NEC Electronics Inc. makes no warranty, express, statutory, implied, or by description, regarding the information set forth herein or regarding the freedom of the described devices from patent infringement. NEC Electronics Inc. makes no warranty of merchantability or fitness for any purpose. NEC Electronics Inc. assumes no responsibility for any errors that may appear in this document. NEC Electronics Inc. makes no commitment to update or to keep current the information contained in this document. . t-{EC ii ,..,EC II GENERAL INFORMATION QUALITY AND RELIABILITY II OPERATIONAL AMPLIFIERS II .. COMPARATORS II II II II II VOLTAGE REGULATORS D/A AND A/D CONVERTERS FUNCTIONAL BLOCKS CHARGE COUPLED DEVICES PACKAGING INFORMATION iii TABLE OF CONTENTS ,..,EC Page Section 1 - General Information Introduction ..................................................................................... 1-1 Ordering Information ............................................................................. 1-1 Temperature Range .............................................................................. 1-1 Selection Guide .................................................................................. 1-2 Operational Amplifiers .......................................................................... 1-2 Comparators ................................................................................... 1-5 Voltage Regulators ............................................................................. 1-6 Digital to Analog Converters .................................................................... 1-7 Analog to Digital Converters .................................................................... 1-7 Functional Blocks .............................................................................. 1-7 Charge Coupled Device (CCD Sensors) .......................................................... 1-7 Part Number Index ............................................................................... 1-8 Industry Cross Reference ....................................................................... 1-10 Full Product Line Guide ......................................................................... 1-12 Discontinued Products ......................................................................... 1-14 Section 2 - Quality and Reliability Introduction ..................................................................................... Electrical Testing and Screening .................................................................. Quality Control Flowchart ......................................................................... Periodical Reliability Test ......................................................................... 2-1 2-2 2-3 2-4 Section 3 - Operational Amplifiers Single jlPC301A General Purpose Operational Amplifier ................................................... 3-1 jlPC318 High-Speed Operational Amplifier ......................................................... 3-7 jlPC356 J-FET Input Operational Amplifier ....................................................... 3-11 jlPC357 J-FET Input Decompensated Operational Amplifier ....................................... 3-15 jlPC741 General Purpose Operational Amplifier .................................................. 3-21 jlPC811 J-FET Input Low-Offset Operational Amplifier ............................................ 3-25 jlPC813 J-FET Input Low-Offset Operational Amplifier ............................................ 3-27 jlPC4061 J-FET Input Low-Power Operational Amplifier ........................................... 3-29 jlPC4071 J-FET Input Low-Noise Operational Amplifier ........................................... 3-31 jlPC4081 J-FET Input Operational Amplifier ...................................................... 3-35 jlPC4250 Programmable Operational Amplifier ................................................... 3-39 Dual jlPC358 Dual Low-Power Operational Amplifier ................................................... 3-45 jlPC812 Dual J-FET Input Low-Offset Operational Amplifier ....................................... 3-49 jlPC814 Dual J-FET Input Low-Offset Operational Amplifier ....................................... 3-53 jlPC1458 Dual General Purpose Operational Amplifier ............................................ 3-55 jlPC4062 Dual J-FET Input Low-Power Operational Amplifier...................................... 3-59 jlPC4072 Dual J-FET Input Low-Noise Operational Amplifier ...................................... 3-61 jlPC4082 Dual J-FET Input Operational Amplifier ................................................. 3-67 jlPC4359 Dual High-Speed Programmable Current Mode Operational Amplifier..................... 3-71 jlPC4556 Dual Decompensated High-Performance Operational Amplifier ........................... 3-79 jlPC4557 Dual High-Performance Operational Amplifier ........................................... 3-83 jlPC4558 Dual High-Performance Operational Amplifier ........................................... 3-87 jlPC4559 Dual High-Performance Operational Amplifier ........................................... 3-93 jlPC4560 Dual High-Performance Operational Amplifier ........................................... 3-97 jlPC4570 Dual Ultra Low-Noise, Wideband, Operational Amplifier................................. 3-103 iv t-IEC TABLE OF CONTENTS (cont) Page Section 3 - Operational Amplifiers (cont) Quad tJPC324 Quad Low-Power Operational Amplifier ................................................. tJPC3403 Quad High-Performance Operational Amplifier ......................................... tJPC4064 Quad J-FET Input Low-Power Operational Amplifier .................................... tJPC4074 Quad J-FET Input Low-Noise Operational Amplifier .................................... tJPC4084 Quad J-FET Input Operational Amplifier ............................................... tJPC4574 Quad Ultra Low-Noise, Wideband, Operational Amplifier ................................ tJPC4741 Quad High-Performance Operational Amplifier ......................................... Definition of Terms ............................................................................ 3-107 3-111 3-115 3-117 3-121 3-125 3-127 3-131 Section 4 - Comparators tJPC311 Single Precision Voltage Comparator ............................•......................... 4-1 tJPC319 Dual High-Speed Voltage Comparator ..................................................... 4-7 tJPC339 Quad Low-Power Voltage Comparator ................................................... 4-13 tJPC393 Dual Low-Power Voltage Comparator .................................................... 4-17 Definition of Terms ............................................................................. 4-21 Section 5 - Voltage Regulators tJPC305 Precision Positive Voltage Regulator ....................................................... 5-1 tJPC317 Three-Terminal Adjustable Positive Voltage Regulator ...................................... 5-5 tJPC337 Three-Terminal Adjustable Negative Voltage Regulator ..................................... 5-9 tJPC2600 Series Three-Terminal Positive Voltage Regulator ....................................... 5-13 tJPC78LOOH Series Three-Terminal 0.1 A Positive Voltage Regulators.................. ............. 5-17 tJPC78LOOJ Series Three-Terminal 0.1 A Positive Voltage Regulators ............................... 5-23 tJPC78MOO Series Three-Terminal 0.5 A Positive Voltage Regulators................................ 5-29 tJPC7800 Series Three-Terminal 1.0 A Positive Voltage Regulators.. .. . . . . . ...... . . .... ..... . ... . . .. 5-35 tJPC79LOO Series Three-Terminal 0.1 A Negative Voltage Regulators................................ 5-41 tJPC79MOO Series Three-Terminal 0.5 A Negative Voltage Regulators............................... 5-45 tJPC7900 Series Three-TerminaI1.0A Negative Voltage Regulators ................................. 5-51 Section 6 - DI A and AID Converters Digital-to-Analog tJPC603 6-Bit High-Performance D/A Converter .................................................... 6-1 tJPC61 0 10-Bit Polarized DIA Converter ............................................................ 6-9 tJPC624 8-Bit High-Speed Multiplying D/A Converter .............................. ,.............. 6-17 tJPC6012 12-Bit High-Speed Multiplying D/A Converter ........................................... 6-27 tJPD6900 8-Bit CMOS Video D/A Converter ...................................................... 6-35 tJPD7011 8-Bit NMOS DIA Converter ............................................ . . . . . . . . . . . . . . .. 6-39 Analog-to- Digital tJPD6950 8-Bit CMOS Video AID Converter ....................................... . . . . . . . . . . . . . .. tJPD7001 8-Bit CMOS Serial Output AID Converter ..............................•................ tJPD7002 10-Bit CMOS Integrating AID Converter ................................. "............. tJPD7003 8-Bit CMOS High-Speed AID Converter ................................•................ tJPD7004 10-Bit CMOS Successive Approximation AID Converter.................................. 6-45 6-51 6-59 6-69 6-75 v TABLE OF CONTENTS (coni) ~EC Page Section 7 - Functional Block. pPC398 Monolithic Sample-and-Hold Circuit ....................................................... 7-1 pPC494 Switching Regulator Control Circuit ....................................................... 7-3 pPC751n52 Quad Addressable Read/Write Amplifier ...................................•......... 7-13 pPC754 Magnetic Servo Head Preamplifier ....................................................... 7-19 pPC1042 Switching Regulator Control Circuit .................................................... 7-21 pPC1060 Precision 2.5 Volt Reference Regulator .................................................. 7-27 pPC1555 Precision Timer Circuit ................................................................ 7-29 pPC1571 Compander ........................................................................... 7-35 pPC1663/1664 Ultra-Wideband Differential Amplifier .............................................. 7-41 pPC3423 Overvoltage "Crowbar" Sensing Circuit ................................................. 7-45 pPD5555/5556 CMOS Timers .................................................................... 7-51 Section 8 - Charge Coupled Device. pPD791 4096-Bit CCD Image Sensor ............................................................... 8-1 pPD7951024-Bit CCD Image Sensor ............................................................... 8-9 pPD799 2048-Bit CCD Image Sensor............................................................. 8-17 Section. - Packaging Information Packaging Information ............................................................................ 9-1 Thermal Information ............................................................................ 9-13 Taping Specifications........................................................................... 9-15 Surface Mounting Specifications ................................................................ 9-23 vi NEe GENERAL INFORMATION 1-A D GENERAL INFORMATION !\fEe Section 1 - General Information Introduction ....................................................................... 1-1 Ordering Information .............................................................. 1-1 Temperature Range ................................................................ 1-1 Selection Guide ................................................................... 1-2 Operational Amplifiers ........................................................... 1-2 Comparators .................................................................... 1-5 Voltage Regulators ............................................................... 1-6 Digital to Analog Converters ...................................................... 1-7 Analog to Digital Converters ...................................................... 1-7 Functional Blocks ................................................................ 1-7 Charge Coupled Device (CCD Sensors) ........................................... 1-7 Part Number Index ................................................................. 1-8 Industry Cross Reference ........................................................ 1-10 Full Product Line Guide .......................................................... 1-12 Discontinued Products ........................................................... 1-14 t-IEC GENERAL INFORMATION Introduction Ordering Information NEC's Linear Catalog illustrates the extensive line of components available to designers and manufacturers. The variety of devices allows greater design alternatives and the ability to choose parts that truly fit your product needs. NEC's components are designed to satisfy industrial, communication, instrumentation, and consumer applications. NEC integrated circuits may be ordered by contacting either the local NEC sales office, representative, or authorized distributor. Numbering System pPC 1234 Designed for easy reference, NEC's Linear Catalog is divided into the following sections. General Information - This section includes product selection guides, cross reference, ordering information, and handling precautions. Quality and Reliability - An explanation and detailed specifications of NEC's stringent Q&R product testing. Operational Amplifiers - Popular second-source operational amplifiers, and state-of-the-art J-FET input originals, complement a complete line of op-amps. Most are available in surface mount packaging. C "L...-Package B - Ceramic flatpack C - Plastic molded DIP 0 - Ceramic DIP/CERDIP G2 - Plastic miniflat H - TO-220 HA - Plastic SIP J - TO-92 '----Device Number '-------Product Family pPC - Bipolar Linear Circuits pPD - MOS Circuits Voltage Comparators - Some of the most popular comparators are available in either DIP or surface mount packaging. Temperature Range A/D-D/A Converters - A full line of DIA converters are available with 6-, 8-,10-, and 12- bits; also, 8- and 10-bit CMOS AID converters with full microprocessing capabilities. Ceramic Flatpack Voltage Regulators - All standard 3-terminal regulators are available in the 7800 and 7900 series, as well as the pPC305 DIP. Functional Blocks - A wide variety of special products are offered including, SMPS controllers, timers, precision voltage references, and Charge Coupled Devices (CCD Sensors). D High Reliability Industrial Commercial -40°C to +85 °C' -20°C to +70°C Ceramic DIP -40°C to +85 °C' -20°C to +10°C Plastic Miniflat -40°C to +85 °C' O°C to +70°C TO·220 -40°C to +85 °C' -20°C to +85°C Operating Temperature Plastic DIP O°C to 70°C Plastic SIP -40°C to +85 °C' -20°C to +80°C TO·92 -40°C to +85°C' -20°C to +85 °C Storage Temperature High Reliability Industrial Ceramic Flatpack Commercial -65°C to +150°C Plastic OIP -55°C to +125°C Ceramic DIP -55°C to +150°C Plastic Miniflat -55°C to +125°C -55°C to +125°C -55°C to +125°C TO·220 -55°C to +150°C Plastic SIP -55°C to +125°C 10·92 -65°C to +150°C • Available For Most Linear Devices. 1-1 ttlEC GENERAL INFORMATION Selection Guide Operational Amplifiers O'C to +70'C O'C to +70'C -20'C to +80'C Temperature Range: C Package (plastic molded DIP) G2 Package (plastic molded SO) D Package (ceramic cavity DIP) 'Unless otherwise specified, v± = ±15 V, TA = 25'C VCC' NEC No, Package Generic (+I-V) Rec, ICC (mA) Max, Vio liD (nA) Ib (nA) AWOL (dB) en2 (nVlJijZ) 'UNITY (MHz) Slew Rale (mV) Max, Max. Max. Min. Typ. Typ. Typ. (VIps) Single Operational Amplifiers /lPC301A C/8 LM301A 5·16 3 7.5 50 250 88 25 prog prog /lPC318 C/8 LM319 5·16 10 10 200 88 15 10 70 /lPC356 CIS LF356 5·16 10 5 0,05 500 0,2 88 20 5 12 /lPC357 C/8 LF357 5·16 10 0,05 0.2 88 20 20 50 (AV~ /lPC741 C/8 200 500 88 25 2,5 0.05 0,2 88 20 4 3.5 2,5 0.05 0.2 88 20 2·16 0,25 10 0.05 0,1 69 30 n071 5·16 2,7 10 0,05 0.2 88 18 13 TL081 5·16 2.8 15 0.1 0.4 88 25 13 LM4250 1·16 proD 6 prog proD 96 25 /lA741 7·16 2.8 LF411 5·16 3,5 LF412 5·16 TL061 (AV ~ 5) (GOWat 10 kHz) 0,6 0,5 G2I8 /lPC811' C/8 15 G2I8 /lPC813' C/8 25 G2I8 /lPC4061' C/8 G2I8 /lPC4071 C/8 G2I8 /lPC4081 C/8 G2I8 /lPC4250 C/8 G2I8 Noles: 1. Recommended supply voltage range. 2. Input equivalent noise density at 1 kHz (RS = 100 0). 3. New product (Preliminary data). 1-2 proD proD 5) NEe GENERAL INFORMATION Operational Amplifiers (cont) Temperature Range: G Package (plastic molded DIP) G2 Package (plastic molded SO) D Package (ceramic cavity DIP) 'Unless otherwise specified, v± = ±15 V, TA = 25°G NEC No, Package OOG to +70 o G OOG to +70 o G -20oG to +80 o G e.2 VCC' (+I-V) IcC (mA) V'O (mV) liO (nA) Ib (nA) AVOL (dB) 'UNITY (MHz) Slew Rate (nVlJiiZ) Rec. Max. Max. Max. Max. Min. Typ. Typ. Typ. 3·30 (Single Supply) 1.2 7,0 50 250 88 32 0.5 0.2 ORIG 5·16 6,8 3.0 0.05 0.2 88 20 4 15 Generic (V//ls) Dual Operational Amplifiers IlPC358 C/8 02/8 LM358 D • Specified at v± = +5 V, IlPC812 3 C/8,02/8 IlPC8f43 C/8 ORIO 5·16 6,8 3,0 0.05 0,2 88 20 8 25 IlPC1458 C/8 02/8 MC1458 7·16 5.6 6 200 500 88 25 0,6 0.5 C/8 n062 2·16 0.50 10 0.05 0.1 69 30 n072 5·16 5.0 10 0,05 0.2 88 18 3 13 n082 5·16 5.6 15 0.1 0.4 88 25 3 13 15 60 6.0 200 12 20 5,0 (AV~ (AV~ /lPC4062 3 3 02/8 IlPC4072 C/8 G2/8 IlPC4082 C/8 G2/8 /lPC4359 C/14 LM339 5·22 22 IlPC4556 C/8 ORIG 4·16 5.6 1500 70 500 86 02/8 10) (GBWat 10 kHz) IlPC4557 C/8 ORIO 4·16 5.6 6.0 200 500 86 12 2 IlPC4558 C/8 G2/8 RC4558 4·16 5.6 6.0 200 500 86 12 2 IlPC4559 C/8 RC4559 4·16 5.6 6.0 200 500 86 12 IlPC4560 C/8 ORIO 4·16 5.6 6.0 200 500 86 ORIG 4·16 8.0 5.0 200 1000 90 IlPC4570 3 C/8 G2I8 3 10 (GBWat 10 kHz) 02/8 4,5 10) 2,8 15 (GBW It 10 kHz) Notes: 1. Recommended supply voltage range. 2. Input equivalent noise density at 1 kHz (RS = 1000). 3. New product (Preliminary data). 1-3 t-IEC GENERAL INFORMATION Operational Amplifiers (cont) Temperature Range: OOG to +70 o G OOG to +70 o G -20 o G to +80 o G G Package (plastic molded DIP) G2 Package (plastic molded SO) D Package (ceramic cavity DIP) * Unless otherwise specified, V± = ±15 V, TA = 25°G NEe No, Package Generic Vee' (+I-V) Rec, lee Vio liD Ib AVOL en2 'UNITY (mA) Max, (mV) Max, (nA) Max, (nA) Max, (dB) (nV/JijZ) (MHz) Slew Rate (V//ls) Min, Typ, Typ, Typ, 0,5 0,25 Quad Operational Amplifiers /lPC324 CI14 G2I14 LM324 3·30 (Single Supply) 2,0 7,0 50 250 88 32 3·32 (Single Supply) 7,0 7,0 50 250 88 32 * Specified at v± = +5 v. /lPC3403 CI14 G2I14 MC3403 0,6 * Specified at v± = +5 V. /lPC4064 CI14 G2I14 TL064 2·16 1.0 10 0,05 0,1 69 30 /lPC4074 CI14 G2114 TL074 5·16 10,0 10 0,05 0,2 88 18 13 /lPC4084 CI14 TL084 5·16 10,0 15 25 13 /lPC4574 CI14 G2I14 OHIG ±15 12 /lPC4741 CI14 G2I14 HA4741 2·16 7,0 10 1.6 Noles: 1. Recommended supply voltage range, 2. Input equivalent noise density at 1 kHz (RS = 100 0). 3. New product (preliminary data). 1-4 5,0 0,2 0.4 88 200 1000 90 50 300 88 ftt{EC GENERAL INFORMATION Comparators Temperature Range: C Package G2 Package (plastic molded SO) 'Unless otherwise specified, V± = ±15 V, TA = 25°C NEC No. flPC311 [Single) Package Generic C/8 8218 LM311 VCC' (+I-V) 4·18 5-36 DoC to +70°C DoC to +70°C ICC Max, ViD Max, Ib Max. AVOL Typ. ISINK' Typ. Response Max, (rnA) (mV) (nA) (nA) (dB) (rnA) (ns) 7.5 7.5 50 250 106 8.0 200 12.5 8.0 200 1000 92 3.2 80 2.0 5.0 50 250 106 4.0 1300 1.0 5.0 50 250 106 4.0 1300 liD Time' II [Single Supply) flPC319 [Dual) C/14 82114 LM319 5-18 5-18 [Single Supply) flPC339 [Quad) C/14 LM339 G2I14 2-32 [Single Supply) • Specified at V+ flPC393 [Oual) = +5 V. C/8 G2I8 LM393 2-32 [Single Supply) • Specified at v+ = +5 V. Notes: 1. Recommended supply voltage range. 2. V+ = +5 V, VOL = 0.4 V. 3. 100 mV input step with 5 mV overdrive. 1-5 t-IEC GENERAL INFORMATION Voltage Regulator. Device Drilinal pPC305C 305 pPC317 pPC337 lM317 lM337 pPC2600 pPC78l05J pPC78L08J pPC78L12J pPC78L15J pPC78M05 pPC78M08 pPC78Ml0 Dperallng TemperalUre Range (OC) 11-+70 -20-+80 -211-+80 -30-+85 78L05 78108 -211-+1501 -20-+1501 78112 78115 -20-+1501 -211-+1501 78M05 78M05 -211-+80 -211-+80 -20-+80 78M12 78M15 pPC78M18 78M18 -211-+80 -211-+80 pPC78M24 pPC7805 78M24 7805 -211-+80 -20-+80 pPC7808 pPC7812 pPC7815 7808 -211-+80 -211-+80 pPC7818 7818 7824 pPC7824 pPC79L05 pPC79L08 pPC79L12 pPC79l15 pPC79M05 pPC79MOB pPC79MI2 pPC79M18 pPC79M24 pPC7905 pPC7908 pPC7912 pPC7915 pPC7918 pPC7924 7815 7905 7908 7912 7915 7905 7908 7912 7918 7924 7905 7908 7912 7915 7918 7924 (W) 0.05 0.35 4.3 40 1.5 20 5.10 4.3 12 40 28 1.5 0.5 0.1 20 20 0.8 82 10.5 30 0.1 14.5 17.5 35 35 35 0.1 0.8 0.8 0.1 0.5 0.8 20 10.5 4.5-30 +1.3-+30 -1.3--30 30 103 153 1&3 83 123 -53 -&3 -211-+1251 -211-+1251 TO·220 35 35 0.5 0.5 20 TO·220 TO·220 21 27 35 40 0.5 20 20 0.5 20 20 20 20 TO-220 20 TO-220 20 20 0.7 TO-220 TO·220 TO·220 TO-220 35 1.0 10.5 14.5 17.5 35 35 1.0 1.0 1.0 21 35 1.0 27 40 -20 -23 1.0 0.07 0.07 -27 0.07 0.7 TO-92 -30 -25 0.07 0.35 0.7 TO·92 20 -25 0.35 0.35 20 20 20 TO·220 TO-220 TO·220 TO-220 -7 -10.5 -14.5 35 -7 -211-+1501 -20-+1501 -123 -10.5 -14.5 -183 -17.5 -30 -30 -20-+1501 -243 -27 -38 0.35 0.35 -7 -35 1.0 -35 -35 -153 -10.5 -14.5 -17.5 1.0 1.0 1.0 -183 -21 -35 -243 -27 -40 2. Output voltage accuracy ±10%. 3. Output voltage accuracy ±5%. TO·92 TO-92 TO-92 TO·220 20 20 -83 -20-+80 -211-+80 TO·220 TO-220 TO-220 TO-92 0.5 0.5 -53 -211-+80 -211-+80 8 pin DIP 35 35 -17.5 -83 Package 12.5 14.5 17.5 -211-+1501 -20-+1501 Note.: 1. Junction temperature. 1-6 (A) -211-+80 -211-+80 -211-+80 PT Max. Max. 40 -20-+80 -20-+80 -20-+1251 -20-+1251 Max. Min. 8.0 -20-+80 pPC78M12 pPC78M15 7812 10 VOUT (V) -35 1.0 1.0 0.7 TO·220 TO-220 TO-22O TO-92 TO-92 20 20 TO-220 20 20 TO·220 TO·22O TO-220 20 20 20 TO·220 TO-220 TO·220 t-IEC GENERAL INFORMATION Digital to Analog Converters Part No. pPC603 Resolution 6 Bit Non-Linearity 0.4% Conversion Speed 3pS suppl, Voltage ±15 pPC610 10 Bit 0.2% 6pS ±15 Onboard VREF - Output Buller pPC624 8 Bit 0.19% 150 ns ±5 ±15 Current Output pPC6012 12 Bit 0.05% 400 ns +5-+15 -12/-15 Current Output pPC6900 8 Bit 1/2LSB 20 x 1()6 samples/sec +5 Current Output pPD7011 pPD7011C·l 8 BII 0.4% 0.2% 3pS +5 Current Output features Onboard VREF - Output Buller a Analog to Digital Converters Part No. pPC650 Resolution 12 Bit Non-Linearity 0.05% Conversion Speed 45pS Suppl, Vo"a.e +5 -15 pPC6950 8 Bit ±1/2 LSB 20 x 1()6 samples/sec +5 Parallel Output pPD700l BBit 0.8% 140ps +5 Serial Output pPD7002 pPD7002C·l pPD7003 10 BII 15 ms +5 Three State Output 8 Bit 0.2% 0.1% 0.49"/, 4pS +5 Three State Output pPD7004 10BII 0.15% 100ps +5 Serial/Parallel Output Parallel Output Functional Blocks· Device No. pPC398 Description Monolithic Sample and hold circuit pPC494 Switching regulator (SMPS) controller pPC751 Quad read/write amp for hard disk media pPC752 Quad addressable read/write amplifier Magnetic servo head preamp pPC754 pPC1042 Swllchlng regulator (SMPS) controller pPC1060 2.5 Vprecision voltage reference. for use with 0/Aand A/D converters Precision Timer (NE 555 direct replacement) pPC1555 pPC3423 Overvoltage "Crowbar" sensing circuit pPD5555/5556 CMOS 555 Timers ·Contact manufacturer for specifications. Charge Coupled Devices (CCD Sensors) Device No. pPD791D Description 4096 BII Array pPD795D 1024 Bit Array pPD799D 2048 Bit Array 1-7 GENERAL INFORMATION NEe Part "limber Index Page pPC301A General Purpose Operational Amplifier ...•.............................................•. pPC305 Precision Positive Voltage Regulator ....................................................... pPC311 Single Precision Voltage Comparator ••.••.••.......................•...................... pPC317 Three-Terminal Adjustable Positive Voltage Regulator ...............•......•............... pPC318 High~Speed Operational Amplifier ......................................•........•.••...... 3-1 5-1 4-1 5-5 3-7 pPC319 Dual High-Speed Voltage Comparator ...•.•........................•.•.................... 4-7 pPC324 Quad Low-Power Operational Amplifier ................................................. 3-107 pPC337 Three-Terminal Adjustable Negative Voltage Regulator .....................••.............. 5-9 pPC339 Quad Low-Power Voltage Comparator ................................................... 4-13 pPC356 J-FET Input Operational Amplifier ....................................................... 3-11 pPC357 pPC358 pPC393 pPC398 pPC494 J-FET Input Decompensated Operational Amplifier ............................•.....•.... 3-15 Dual Low-Power Operational Amplifier ................................................... 3-45 Dual Low-Power Voltage Comparator .................................................... 4-17 Monolithic Sample~and-Hold Circuit ....................................................... 7-1 Switching Regulator Control Circuit ..........•.............•.............•................ 7-3 pPC603 6-Bit High-Performance D/A Converter .................................................... 6-1 pPC610 10-Bit Polarized D/A Converter ............................................................ 6-9 pPC624 8-Bit High-Speed Multiplying D/A Converter ................................•.••..•...... 6-17 pPC741 General Purpose Operational Amplifier .................................................. 3-21 pPC7511752 Quad Addressable Read/Write Amplifier ............................................. 7-13 pPC754 Magnetic Servo Head Preamplifier ....................................................... 7-19 pPD791 4096-Bit CCD Image Sensor .....................................••.••••...............•... 8-1 pPD7951024-Bit CCD Image Sensor ............................................•.................. 8-9 pPD799 2048-Bit CCD Image Sensor .........•...........................................•....... 8-17 pPC811 J-FET Input Low-Offset Operational Amplifier ...•.••..........•.......................... 3-25 pPC812 Dual J-FET Input Low-Offset Operational Amplifier .....•..................•.•.•..•....... 3-49 pPC813 J-FET Input Low-Offset Operational Amplifier .........................••.......•......... 3-27 pPC814 Dual J-FET Input Low-Offset Operational Amplifier ...............•..•••.................. 3-53 pPC1042 Switching Regulator Control Circuit ..•..........•••............ ;....................... 7-21 pPC1060 Precision 2.5 Volt Reference Regulator.................................................. 7-27 pPC1458 Dual General Purpose Operational Amplifier ............................................ pPC1555 Precision Timer Circuit ................................................................ pPC1571 Compander ......•.•.......................................•..•..•.................... pPC1663/1664 Ultra-Wideband Differential Amplifier .•.•..••...................................... pPC2600 Series Three-Terminal Positive Voltage Regulator ........... :........................... 3-55 7-29 7-35 7-41 5-13 pPC3403 Quad High-Performance Operational Amplifier ........•...............••.......•...••.. 3-111 pPC3423 Overvoltage "Crowbar" Sensing Circuit ................................................. 7-45 pPC4061 J-FET Input Low-Power Operational Amplifier ........................................... 3-29 pPC4062 Dual J-FET Input Low-Power Operational Amplifier ........... ,.......................... 3-59 pPC4064 Quad J-FET Input Low-Power Operational Amplifier .....•................•............. 3-115 1-8 t\'EC GENERAL INFORMATION Part Number Ind.ex (coni) Page J.lPC4071 J.lPC4072 J.lPC4074 J.lPC4081 J.lPC4082 J-FET Input Low-Noise Operational Amplifier ........................................... 3-31 Dual J-FET Input Low-Noise Operational Amplifier ...................................... 3-61 Quad J-FET Input Low-Noise Operational Amplifier .................................... ·3-117 J-FET Input Operational Amplifier .....................................................• 3-35 Dual J-FET Input Operational Amplifier ........................•.•....................•. 3-67 J.lPC4084 J.lPC4250 J.lPC4359 J.lPC4556 J.lPC4557 Quad J-FET Input Operational Amplifier ...............................•............... 3-121 Programmable Operational Amplifier .•..............................................•.. 3-39 Dual High-Speed Programmable Current Mode Operational Amplifier ..........•.....•.... 3-71 Dual Decompensated High-Performance Operational Amplifier ........................... 3-79 Dual High-Performance Operational Amplifier .....................•..................... 3-83 J.lPC4558 Dual High-Performance Operational Amplifier ...............•................•.......... 3-87 J.lPC4559 Dual High-Performance Operational Amplifier ........................................... 3-93 J.lPC4560 Dual High-Performance Operational Amplifier ........................................... 3-97 J.lPC4570 Dual Ultra Low-Noise, Wideband, Operational Amplifier................................. 3-103 J.lPC4574 Quad Ultra Low-Noise, Wideband, Operational Amplifier ......•.......•....•............ 3-125 J.lPC4741 Quad High-Performance Operational Amplifier ...............•...............•......... 3-127 J.lPD5555/5556 CMOS Timers.................................................................... 7-51 J.lPC6012 12-Bit High-Speed Multiplying DIA Converter ..•..........•............................. 6-27 J.lPD6900 8-BitCMOS Video DIA Converter ......•••............................................. 6-35 J.lPD6950 8-Bit CMOS Video AID Converter ... . . . . . . . . . . . . . . . . • . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 6-45 J.lPD7001 8-Bit CMOS Serial Output AID Converter ......•.........••............................. J.lPD7002 10-Bit CMOS Integrating AID Converter .•............................•................. J.lPD7003 8-Bit CMOS High-Speed AID Converter ...........•............•.•...••...............•. J.lPD7004 10-Bit CMOS Successive Approximation AID Converter .........•.•...•....•........•.... J.lPC7011 8-Bit NMOS DIA Converter .....•••...........................••....................... 6-51 6-59 6-69 6-75 6-39 J.lPC78LOOH Series Three-Terminal 0.1 A Positive Voltage Regulators ............•............•.... J.lPC78LOOJ Series Three-Terminal 0.1 A Positive Voltage Regulators ..........................•.... J.lPC78MOO Series Three-Terminal 0.5 A Positive Voltage Regulators ......•...................•.... J.lPC7800 Series Three-Terminal 1.0 A Positive Voltage Regulators ..................•..•........... J.lPC79LOO Series Three-Terminal 0.1 A Negative Voltage Regulators ............................... J.lPC79MOO Series Three-Terminal 0.5 A Negative Voltage Regulators ...... . . . . . . .. . . . . . . . . . . . . . . .. J.lPC7900 Series Three-Terminal 1.0 A Negative Voltage Regulators ...............•................ 5-17 5-23 5-29 5-35 5-41 5-45 5-51 1-9 1·· NEe GENERAL INFORMATION Industry Cross Reference AMD NEG Motorola (cont) NEG AM 6012 pPC6012 UA 301A pPC301A OAC 08 pPC624 LM 305 pPC305 LM 311 pPC311 NEG LM 317 pPC311 UA 1458 pPC1458 LM 324 pPC324 UA 301A pPC301A LM 339 pPC339 pPC305 MC 3403 pPC3403 UA311 pPC311 MC 34072 pPC842* UA324 pPC324 MC 34074 pPC844* pPC339 LM 358 pPC358 LM 358 pPC358 MC 4558 pPC4558 UA393 pPC393 MC 4741 pPC4741 UA398 pPC398 LM 741 pPC741 UA 4558 pPC4558 MC 78XX pPC78XX UA494 pPC494 MC 78LXX pPC78LXX pPC1555 MC 78MXX pPC78MXX UA 733 pPC1663 MC 79XX pPC79XX UA 741 pPC741 Fairchild UA305 UA339 UA,555 UA 78XX pPC78XX National NEG UA 78LXX pPC78LXX OAC 08 pPC624 UA 78MXX pPC78MXX LM 1458 pPC1458 UA 79XX pPC79XX LM 2930 pPC2250 UA 79LXX pPC79LXX LM 301A pPC301A UA 79MXX pPC79MXX LM 305 pPC305 LM 311 pPC311 itPC317 Intersil NEG LM 317 lCM 7555 pP05555 LM 319 pPC319 pP05556 LM 320TX pPC79XX LM 324 pPC324 LM 337 pPC337 LM 339 pPC339 LM 340T pPC78XX LF 356 pPC356 LM 358 pPC358 LM 359 pPC4359 LM 393 pPC393 LM 398 pPC398 LF 411 pPC811 LF 412 pPC812 LM 4250 pPC4250 LM 555 pPC1555 ICM 7556 Motorola NEG OAC 08 pPC624 TL071 pPC4071 TL072 pPC4072 n074 pPC4074 n081 pPC4081 TL082 pPC4082 n084 pPC4084 MC 1403 pPC1060 MC 1408-8 pPC624 MC 1455 pPC1555 MC 1458 pPC1458 "New product - Data available May 86 1c 1O ftt{EC GENERAL INFORMATION Industry Cross Reference (cont) National (cont) NEG LM 741 IlPC741 LM 78XX IlPC78XX LM 78LXX IlPC78LXX LM 78MXX IlPC78MXX LM 79XX IlPC79XX PMI DAC OlC DAC02 DAC08 RGA NEG IlPC603 IlPC61 0 IlPC624 NEG CA08l IlPC4081 CA082 IlPC4082 CA084 IlPC4084 CA 1458 IlPCl458 CA 301A IlPC30lA CA311 IlPC311 CA 324 IlPC324 CA339 IlPC339 CA358 IlPC358 CA393 IlPC393 CA555 IlPC1555 CA 741 IlPC741 SGS NEG MC 1458 IlPCl458 12605 IlPC2605 L2610 IlPC2610 LS 301 A IlPC301A LM 317 IlPC317 LM 324 IlPC324 LM 339 IlPC339 LM 358 IlPC358 lM 393 IlPC393 LS 4558 IlPC4558 NE 555 IlPCl555 NE 571 IlPC1571 LM 741 IlPC741 SGS (cont) NEG L78XX IlPC78XX L78MXX IlPC78MXX L 79XX IlPC79XX Signetics NEG AM 6012 IlPC60l2 DAC08 IlPC624 MC 1408-8 IlPC624 MC 1458 IlPC1458 LM 311 IlPC311 LM 319 IlPC319 LM 324 IlPC324 LM 339 IlPC339 MC 3403 IlPC3403 LM 393 IlPC393 LF 398 IlPC398 NE 4558 IlPC4558 NE 555 IlPC1555 NE 5532 IlPC4570 UA 741 IlPC741 Texas Inst. NEG n061 IlPC4061 n062 IlPC4062 n064 IlPC4064 n071 IlPC4071 TL072 TL 074 Il PC4072 IlPC4074 TL08l IlPC4081 TL082 IlPC4082 TL084 IlPC4084 TL431 IlPC1093 MC 1458 IlPC1458 LM 301A IlPC301A LM 311 IlPC311 LM 319 IlPC319 LM 324 IlPC324 LM 339 IlPC339 LM 358 IlPC358 LM 393 IlPC393 HC 4558 IlPC4558 HC 4559 IlPC4559 II 1-11 NEe GENERAL INFORMATION Industry Cross Reference (cont) Texas Inst. (cont) NEG TL494 ttPC494 NE 555 ttPC1555 UA 741 ttPC741 UA 78XX ttPC78XX UA 78LXX ttPC78LXX UA 78MXX ttPC78MXX UA 79XX ttPC79XX UA 79LXX ttPC79LXX UA 79MXX ttPC79MXX Full Product Line Guide COMPARATORS SINGLE OP AMPS Part No. Package Description Part No. Package Description ttPC301A ttPC318 ttPC356 ttPC357 ttPC741 ttPC811 ttPC813 ttPC4061 ttPC4071 ttPC4081 ttPC4250 C·8 pin C·8 pin C·8 pin C· 8 pin C/G2· 8 pin C/G2· 8 pin C/G2·8 pin C/G2·8 pin C/G2· 8 pin C/G2· 8 pin C/G2· 8 pin General Purpose OP Amp High Speed Op Amp HET Input Op Amp J·FET Input Low Power. Op Amp General Purpose Op Amp JFET Input High Performance Op Amp JFET Input High Performance Op Amp J·FET Input. Low Power. Op Amp J·FET Input. Low Noise. Op Amp HET Input. Low Offset/8ias Current Programmable Op Amp ttPC311 ttPC31 9 ttPC339 ttPC393 C/G2·8 pin C/G2· 14 pin C/G2· 14 pin C/G2· 8 pin Precision Comparator (Single) High Speed Comparator (Dual) Low Power Comparator (Quad) Low Power Comparator (Dual) DUAL OPAMPS ttPC358 ttPC812 C/G2· 8 pin C·8 pin ttPC814 ttPCI458 ttPC4062 tt PC4072 ttPC4082 ttPC4359 ttPC4556 C·8 pin C/G2·8 pin C/G2· 8 pin C/G2· 8 pin C/G2· 8 pin C· 8 pin C/G2·8 pin ttPC4557 ttPC4558 ttPC4559 ttPC4560 ttPC4570 C·8 pin C/G2·8 pin C·8 pin C/G2·8 pin C/G2·8 pin Low Power Op Amp J·FET Input Low Offset Voltage. High Stability. Op Amp High Performance General Purpose Op Amp HET Input. Low Power. Op Amp J·FET Input. Low Noise. Op Amp HET Input. Low Offset/8las Current High Performance High Performance. Decompensated. Op Amp High Performance Op Amp High Performance Op Amp High Performance Op Amp High Performance Op Amp Ultra Low Noise. Wide Bandwidth Op Amp QUAD OPAMPS ttPC324 ttPC3403 ttPC4064 ttPC4074 ttPC40B4 ttPC4574 ttPC4741 1-12 C/G2 ·14 pin C/G2· 14 pin C/G2· 14 pin C/G2 ·14 pin C·14 pin C/GZ· 14 pin C/G2· 14 pin Low Power Op Amp Low Power Op Amp J·FET Input. Low Power Op Amp J·FET Input. Low Power Op Amp J·FET Input. Low Offset/Bias Current Ultra Low Noise. High Bandwidth High Performance Op Amp CCD = CHARGED COUPLED DEVICES FOR IMAGE SENSING ttPC603 ttPC61 0 ttPC624 ttPC6012 ttPD6900 ttPD7011 D·14 pin 0·18 pin D· 16 pin C· 20 pin C· 22 pin C·18 pin High Performance. 6·8it O/A Polarized. 1O·8it O/A Multiplying. High Speed. 8·Bit D/A Multiplying. High Speed. 12·Bit D/A Video DAC. 20 mHz CMOS Serial/Paratlell/O. NMOS 8·Bit D/A DIGITAL TO ANALOG CONVERTERS ttPD791 D·24 pin ttPD795 D·20 pin ttPD799 o. 24 pin 4096·BIt Linear Image Sensor. CCO. 7 ttm by 5 ttm Photo Element Size 1024·Bit Linear Image Sensor. CCO. 14 ttm by 9 ttm Photo Element Size 2048·Bit Linear Image Sensor. CCO. 14 ttm by 9 ttm Photo Element Size ANALOG TO DIGITAL CONVERTERS [CMOS] ttPD6950 ttPD7001 C· 24 pin C·16 pin ttPD7002 C· 28 pin ttPD7002(·I) C· 28 pin ttP07003 C· 24 pin ttP07004 C· 28 pin Video ADC. 20 mHz Flash CMOS Serial Output. 4 Channel Input. CMOS. 8·BIt Succesive Approximation A/D 4 Channel Input. CMOS. 8/1 O·Bit Integrating AID (Accuracy 0.2% FSR) Same as ttPD7002 with Higher Conversion accuracy (0.1 % FSR) High Speed. Parallel (FLASH). CMOS 8·Bit A/D (Conversion time 4 tts) 8 Channel Input. Serial or Parallel Output. CMOS 1O·Bit A/O ttlEC Full Product Line Guide (cont) GENERAL INFORMATION VOLTAGE REGULATORS Positive-3 Terminal Regulators-1.0 AMP Part No. Package Description I'PC317 TO·220 3 to 30 Volt. Variable I'PC7805 To·220 5 Volt. Fixed I'PC7808 TO·220 8 VOlt. Fixed I'PC7812 TO·220 12 Volt. Fixed I'PC7815 TO·220 15 Volt. Fixed I'PC7818 TO·220 18 Volt. Fixed I'PC7824 TO·220 24 Volt. Fixed FUNCTIONAL BLOCKS Package Description Part No. C· 8 pin Voltage Regulator Controller I'PC305 C· 8 pin Monolithic Sample and Hold Circuit I'PC398 I'PC494 C/G2 ·16 pin Switching Regulator (SMPS) Controller B/o· 22 pin Quad Read/Write Amp for Hard Disk I'PC751 I'PC752 8·22 pin 4 Input/Output. Hard Disk Amplifier C·16 pin Switching Regulator Control Circuit I'PC1042 I'PC1060 C· 8 pin 2.5 Volt Precision Voltage Reference. for use with o/A and A/D Converters C/G2 . 8 pin Precision Timer I'PC1555 C. 16 pin Compander I'PC1571 C. 8 pin Ultra Wide 8andwidth Differential Amp I'PC1663 C· 14 pin Ultra Wide Bandwidth Differential Amp I'PC1664 C. 8 pin Precision Timer I'PC3423 I'PC5555/6 C/G2 . 8/14 pin CMOS Precision Timers VOLTAGE REGULATORS Negatlve-3 Terminal Regulators-O.1 AMP I'PC79L05 To·92 5 Volt. Fixed I'PC79L08 To·92 8 VOlt. Fixed I'PC79L12 TO·92 12 Volt. Fixed I'PC79L15 TO·92 15 Volt. Fixed VOLTAGE REGULATORS Positive-3 Terminal Regulators-O.1 AMP I'PC78L05 TO·92 5 VOlt. Fixed I'PC78L08 TO·92 8 VOlt. Fixed I'PC78L1 0 TO·92 10 Volt. Fixed I'PC78L12 TO·92 12 Volt. Fixed I'PC78L15 TO·92 15 Volt. Fixed VOLTAGE REGULATORS Negative-3 Terminal Regulators-O.S AMP I'PC79M05 To·220 5 Volt. Fixed I'PC79M08 TO·220 8 Volt. Fixed I'PC79M12 To·220 12 Volt. Fixed I'PC79M15 TO·220 15 Volt. Fixed I'PC79M24 TO·220 24 Volt. Fixed VOLTAGE REGULATORS Positive-3 Terminal Regulators-O.S AMP I'PC2605 TO·220 5 Volt. Fixed Low Drop I'PC2610 10·220 10 Volt. Fixed Low Drop I'PC78M05 TO·220 5 Volt. Fixed I'PC78M08 TO·220 8 VOlt. Fixed I'PC78Ml0 10·220 10 Volt. Fixed I'PC78M12 TO·220 12 Volt. Fixed I'PC78M15 TO·220 15 Volt. Fixed I'PC78M18 TO·220 18 Volt. Fixed I'PC78M24 TO·220 24 Volt. Fixed Contact your local NEC sales office for more information VOLTAGE REGULATORS Negative-3 Terminal Regulators-1.0 AMP I'PC7905 10·220 5 VOlt. Fixed I'PC7908 10·220 8 Volt. Fixed I'PC7910 TO·220 10 VOlt. Fixed I'PC7912_ . 10-220 12 Volt. Fixed I'PC7915 10·220 15 Volt. Fixed I'PC7918 10·220 18 Volt. Fixed I'PC7924 10·220 24 Volt. Fixed Noles: C = Plastic DIP G2 = Plastic Miniflat DIP D = Ceramic DIP B= Ceramic Flat Pack II 1-13 t-fEC GENERAL INFORMATION Discontinued Products Old Part Number Replacement Old Part Number Replacement Old Part Number .eplacement IlPC550 None IlPC254 None IlPC616 IlPC3911 IlPC141C IlPC305 IlPC256 IlPC4558 IlPC617 IlPC1 555 IlPC151 IlPC741 IlPC646/647 None None IlPC259 IlPC271 IlPC4560 IlPC154 IlPC311 IlPC646 IlPC6012 IlPC156 None IlPC272 IlPC319 IlPC301 IlPC277 IlPC393 IlPC649 IlPC801 IlPC398 IlPC157 IlPC159 IlPC318 IlPC354 None IlPC802 IlPC4250 IlPC177 IlPC209 IlPC339 Il PC451 IlPC452 IlPC324 IlPC803 IlPC4082 IlPC4359 IlPC251 IlPC1456 IlPC454 IlPC3403 None IlPC804 IlPCl251 IlPC4084 IlPC358 IlPC253 None IlPC458 IlPC4741 1-14 IlPC4081 t-IEC QUALITY AND RELIABILITY 2-A II QUALITY AND RELIABILITY t\'EC Section 2 - Quality and Reliability Introduction •...................................•......••.......................... Electrical Testing and Screening ........••......................................•... Quality Control Flowchart ..............•••.....................................•... Periodical Reliability Test •..............•••........................................ 2-8 2-1 2-2 2-3 2-4 ftiEC QUALITY AND RELIABILITY Introduction Wafer Processing NEC Electronics is dedicated to producing the highest quality electronic components at competitive prices with on-time deliveries. In order to guarantee this high level of product reliability, it is essential to build quality into the product - at every phase of operation. During the wafer processing stage, the in-process quality inspections that occur are as follows: NEC has introduced the concept of Total Quality Control (TQC) across its entire semiconductor product line. By adopting TQC, NEC builds high quality into its products, thus assuring higher reliability. This concept and methodology of TQC are company-wide activities involving all levels of management, engineers, quality control staff, and support staff functions; NEC's goal is to further improve the superior product that is synonymous with its name. That's why extensive failure analysis tests are performed and corrective actions taken prior to marketing products. At the same time, research and development efforts to achieve even higher standards are an ongoing process. Process Inspection Item Wafer Resistivity, Dimension, and Appearance, Lot Sampling Inspection PhotoLithography Alignment and Etching, 100 percent inspection Diffusion and Oxidation Oxide Thickness, Sheet Resistivity, Lot Sampling Inspection Metallization and Passivation Thickness,Vth, C-V Characteristics, and Lot Sampling Wafer Sort and Scribe DC Parameters, 100 Percent Inspection Die Sort 100 Percent Visual Inspection Quality Control Implementation Building excellence into a product requires the earliest possible detection of failure in each phase. Immediate action must be taken to remove the cause of failure. Fixed-station quality inspection often precludes the ability to take immediate action. It is, therefore, necessary to perform quality control functions at each step - especially at the conceptual stage. Significant quality stages include: • • • • • • Product Development Wafer Processing Assembly Electrical Testing and Screening Pre-Inventory Inspection Reliability Assurance Test Product Development The product development phase includes product conception, review of the device proposal, organization and physical element deSign, engineering evaluations, and transfer of the product to manufacturing. Assembly The in-process quality inspections performed during the chip-mounting and packaging stage are as follows: Process Inspection Item Die Incoming Material Inspection Die Attach Appearance, Lot Sampling Inspection Wire Bonding Bond Strength, Appearance, Lot Sampling Packaging 100 Percent Appearance Inspection Fine Leak' Lot Sampling Gross Leak' 100 Percent Inspection Note: 'For ceramic package devices only. In every step of the product development phase, quality and reliability requirements must be satisfied. Utilizing the TQC approach has shortened the product development cycle by two to three months. At NEC, building superiority into the product is essential. 2-1 ttlEC QUALITY AND RELIABILITY Electrical Testing and Screening Reliability Assurance Testing Electrical testing and infant mortality screening are performed at this stage. The flow chart below depicts the process. (Please. note: The following diagram illustrates NEC's basic flow and is similar to most processes. Some product lines may have variations. However, in all cases NECstrives for zero defects.) A large part of NEC's Total Quality Control program involves various types of reliability assurance tests performed to ensure the highest product quality and reliability possible. Flow No Process Frequency 1st Electrical 100% 2nd Electrical 100% PDA 100% Pre-Inventory Inspection Every lot Reliability Assurance Tests Every lot or every month Warehouse/Finished Goods During the first electrical test, DC parameters are tested in accordance with electrical specifications, on 100% of each lot. This prescreen performance is prior to the infant mortality testing. . In the second ele.ctrical test, AC functional as well as DC parameter tests are performed. If the percentage of defective units exceeds a set limit, the lot is subjected to an additional burn"in. During this second burn-in, the defective units undergo a failure analysis. The results of this analysis are then fed back for appropriate corrective action. Pre-Inventory Inspection Prior to warehouse storage, lots are subjected to an incoming inspection according to the following sampling plan: Electrical test: DC parameters Function test Appearance 2-2 LTPD3% LTPD3% LTPD3% The High Temperature Operating Life Test is used to accelerate failure mechanisms by operating the devices at an elevated temperature. The data obtained is then translated to a lower temperature. Integrated circuits are highly sensitive to the general accelerating effect of humidity in causing electrolytic corrosion between biased lines. High Temperature and High HumidityTestsare performed to detectfailure mechan isms which are accelerated by these conditions. It is especially effective in accelerating leakage-related failures and drifts in device parameters due to process instability. Anothercommon test is the High Temperature Storage Test. In th is test, devices are su bjected to elevated temperatures with no applied bias. This test is used to detect any mechanical problems or process instability. The Environmental Test is performed to detect problems related to packaging, material, susceptibility to environmental extremes, and problems related to usage of the devices. Summary Building quality and reliability into products is the most efficient way to ensure product excellence. NEC's adoption of quality control functions at each process step forms a consolidated quality control system, which guarantees a superior product. With company-wide practice of Total Quality Control, NEC is committed to producing superior products. Through continuous research and development, extensive failure analysis and process improvements, higher standards of quality and reliability are continuously set and maintained. tVEe QUALITY AND RELIABILITY Quality Control Flowchart Industrial Cavity DIP Industrial Plastic DIP Commercial Plastic DIP 100% Electrical Sorting 100% Visuallnspeclion x 100 Magnification Bond Strength Test (Process Check) 100% Electrical Sorting Lot Sampling Electrical Testing L TPD 3% Shipping 83-001888C 2-3 t-IEC QUALITY AND RELIABILITY Periodical Reliability Test Industrial Miniflat IC Industrial Cavity DIP Test Items Environmental Test Life Test Test Items Test Conditions Temperature Cycle -65"C to +150"C, 10 cycles, 30 min each temp Thermal Shock 100"C and 0 "C, 15 cycles, 5 min each temp. Bias Temperature Test TA = 125"C, Maximum Rated Voltage, 1000 hours 260 "C, 10 sec, once -65"C to +150"C, 10 cycles, 30 min each temp Thermal Shock 100"C and 0 "C, 15 cycles, 5 min each temp Mechanical Shock 1500G, 0.5 ms, XYZ Axis, 5 times Variable Frequency Vibration 100 Hz to 2000 Hz, 20G, XYZ Axis, 4 times Constant Acceleration 2000G, XYZ Axis, I min each High Temperature, High Humidity Storage Test TA= 65 "C, RH=95%, 1000 hours Lead Fatigue 250 g, 90 degrees, 3 times, 3 or 4 leads Pressure Cooker Test TA = 125"C, RH = 100%, 48 Hr Solderability 230 "C, 5 sec, once, with rosin flux Bias Temperature Test TA = 125"C, Maximum Rated Voltage, 1000 hours Test Items Test Conditions Soldering Heat 260"C, 10 sec, once Temperature Cycle -65"C to +150"C, 10 cycles, 30 min each temp Thermal Shock 100"C and 0"C, 15 cycles, 5 min each temp Lead Fatigue 250 g, 90 degrees, 3 times, 3 or 4 leads Solderability 230 "C, 5 sec, once, with rosin flux Bias Temperature Test TA = 125"C, Maximum Rated Voltage, 1000 hours High Temperature Storage TA = 150"C, 1000 hours Test 2-4 230 "C, 5 sec, once Temperature Cycle Industrial Plastic Molded DIP Life Test Test Conditions Solderability Soldering Heat High Temperature Storage TA = 175"C, 1000 hours Test Environmental Test Environmental Test High Temperature, High Humidity Storage Test TA= 65 "C, RH=95%, 1000 hours Pressure Cooker Test TA = 125"C, RH = 100%, 96 Hr Life Test High Temperature Storage TA = 150"C, 1000 hours Test Note: 1. Periodical reliability test is carried out every three months for each product. ttlEC OPERATIONAL AMPLIFIERS 3-A II OPERATIONAL AMPLIFIERS ttiEC Section 3 - Operational Amplifiers Single pPC301A General Purpose Operational Amplifier .................................... 3-1 pPC318 High-Speed Operational Amplifier .......................................... 3-7 pPC356 J-FET Input Operational Amplifier .................................•...... 3-11 pPC357 J-FET Input Decompensated Operational Amplifier ........•........•...... 3-15 pPC741 General Purpose Operational Amplifier .................................... 3-21 pPC811 J-FET Input Low-Offset Operational Amplifier ...................•......... 3-25 pPC813 J-FET Input Low-Offset Operational Amplifier ............................. 3-27 pPC4061 J-FET Input Low-Power Operational Amplifier ............................ 3-29 pPC4071 J-FET Input Low-Noise Operational Amplifier ............................. 3-31 pPC4081 J-FET Input Operational Amplifier ....................................... 3-35 pPC4250 Programmable Operational Amplifier ..................................... 3-39 Dual pPC358 Dual Low-Power Operational Amplifier .................................... 3-45 pPC812 Dual J-FET Input Low-Offset Operational Amplifier .................•...... 3-49 pPC814 Dual J-FET Input Low-Offset Operational Amplifier ........................ 3-53 pPC1458 Dual General Purpose Operational Amplifier .............................. 3-55 pPC4062 Dual J-FET Input Low-Power Operational Amplifier ....................... 3-59 pPC4072 Dual J-FET Input Low-Noise Operational Amplifier ..............•.•....... 3-61 pPC4082 Dual J-FET Input Operational Amplifier .............................•.... 3-67 pPC4359 Dual High-Speed Programmable Current Mode Operational Amplifier ...... 3-71 pPC4556 Dual Decompensated High-Performance Operational Amplifier ............ 3-79 pPC4557 Dual High-Performance Operational Amplifier ............................ 3-83 pPC4558 Dual High-Performance Operational Amplifier ............................ 3-87 pPC4559 Dual High-Performance Operational Amplifier ........••.................. 3-93 pPC4560 Dual High-Performance Operational Amplifier ............................ 3-97 pPC4570 Dual Ultra Low-Noise, Wideband, Operational Amplifier .................. 3-103 Quad pPC324 Quad Low-Power Operational Amplifier .................................. pPC3403 Quad High-Performance Operational Amplifier .......................... JiPC4064 Quad J-FET Input Low-Power Operational Amplifier ..................... JiPC4074 Quad J-FET Input Low-Noise Operational Amplifier ...................... JiPC4084 Quad J-FET Input Operational Amplifier................................. JiPC4574 Quad Ultra Low-Noise, Wideband, Operational Amplifier ................. JiPC4741 Quad High-Performance Operational Amplifier .......................... Definition of Terms ............................................................. 3-B 3-107 3-111 3-115 3-117 3-121 3-125 3-127 3-131 NEe NEe Electronics Inc. JlPC301A GENERAL PURPOSE OPERATIONAL AMPLIFIER Pin Configuration Description The IlPC301A is a general purpose amplifier offering higher performance than 709 type operational amplifiers. This amplifier offers virtually foolproof operation with overload protection on both input and output to prevent latch-up when the common mode range is exceeded. In addition, circuit stability is assured by use of a single 30-pF capacitor. Frequency compensation can also be tailored to meet the needs of individual circuits with a single external capacitor. Features o o o o o o Wide common mode and differential voltage range Short-circuit protection No latch-up Offset voltage null capability Adjustable frequency and transient response characteristics LM301A direct replacement 83·Q02060A Equivalent Circuit c, C2 r-----------~------------_r------_+~----_+~B----~----------------~-ov+ R12 500 k ~------_+----r---~~+-~O, Output Offset Null +-----------+---1(' 012 0" 40 k 022 011 :1---+---+ .:t----------t 5k 20 k 40 k R, BO k 0, 020 "2 R, "6 R11 450 R, "3 R, 10 k ", 1k 250 83-0020598 3-1 ftiEC pPC301A Electrical Characteristics Ordering Information T A = 25°C, V± = ±5 V to ±15 V Limits Parameter Inpul Offsel Vollage InpUI Offset Vollage Drift Inpul Offset Current Input Offset Current Drift Inpul Bias Current Symbol Min. Typ. Vlo t.Vlo/t.T Max. Unit 2.0 7.5 mV RS:550kO 6.0 30 pV/oC Hi:5 50 kO, V = ±15V 3 50 nA 0.6 nAloC Package Operating Temperature Range pPC30lAC Plaslic DIP DoC 10 +70°C Absolute Maximum Ratings TA = 25°C Power Disslpalion DiHerenllal Input Vollage t.Viol t. T 0.02 V±=±15V Input Voltage (Nole 1) OUIPUI Short Circuli Duralion 70 Ib 250 Operaling Temperature Range nA Storage Temperalure Range 0.5 MO V±=±15V. Vo = ±IO V. RL <': ao AVOL 88 104 dB Supply Current ICC 1.8 3 mA OUIPUI Vollage Swing Vom ±12 ±14 V V±=±15V. RL2:10kO Output Vollage Swing Vom ±10 ±13 V V±=±15V. RL<':HO Common Mode Input Vollage Range Vicm ±12 V V±=±15V Common Mode Rejection Ratio CMRR 70 90 dB RS:550kO Supply Vollage Rejection Ratio SVRR 70 90 dB RS:550kO 3-2 Part Number Vollage Belween V+ and V110 Input Impedance Large Signal Voltage Gain Test Conditions 36 V 350 mW ±30 V ±15 V Indellnile 010 HO°C -5510 +125°C Nole: 1. For supply voltages less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ftiEC pPC301A Typical Characteristics TA = 25°C Standard Compensation and Offset Balance Circuit Single Pole Compensation /.IPC301A t--"II"""'---o v83-002061 A 83-oo2062A Open Loop Frequency Response Large Signal Frequency Response 120 32 v± = TA 100 ~ 80 iii' :!!. .~ " f "" v±1 =±1JV 28 T.~+25°~ - I 24 30PF~ ~=3PF 60 40 ~ 20 -20 ±15 V +25°C 10 1 100 1k """ "" " 10 k 100 k Frequency (Hz) \ C, =3pF \30 PF '\ "1 1M \ I 10 M I"......... "- 1'.. o 1k \ 10k 20 50 - 100k 200 500 1M I 10M Frequency (Hz) Voltage Follower Pulse Response 10 , E .• .~ III --2 -4 -6 y± = ±15 V TA = +25°C Av=1 - 1\ r- Input ; \ I ---/?utput 'i /" V \. \. "'--- --- , I I I I -8 -10 10 20 30 40 50 60 70 80 90 Time (pa) 3-3 ttlEC pPC301A Typical Characteristics (Cont.) TA = 25°C Open Loop Frequency Response Two Pole Compensation 120 v± = ±15 V -...... 100 TA= +25°C f\ \\ 80 Ic a I 60 1'\ 40 20 -20 10 1 83-002063A 100 1k 10 k Frequency (Hz) \ \ 20 16 f!l. 1\ 12 S ;e ~ o 10k 20 50 100k 200 i \ -2 I Output 'j I I "1 I __ A. v± +15V TA - +25~C A.., =1 C, =30pF -8 C2 -10 1M 500 \! -6 i ~ t-- Input-!- T\ -4 J\ r-I i\ ~ .E l! !l I 10M TA - +25°C 24 ..•8- ~ 1M 10 v± =±15V 28 ~. 100k Voltage Follower Pulse Response Large Signal Frequency Response 32 '""" 20 10 30 Frequency (Hz) 40 50 60 70 = 300 pF 80 90 Time (PS) Open Loop Frequency Response Feedforward Compensation 120 ~ 6 __ 1_ C2= 21T 1oR2 C, 150pF f TA i'-.. ...... 80 10 l!- v± = ±15V ........ 100 80 i'. ........ 40 "- 20 10= 3 MHz -20 83-002064A 10 100 1k 10k 100 k Frequency (Hz) 3-4 = +2SoC "" 1M 10 M 100 I ,..,EC IlPC301A Typical Characteristics (Cont.) TA = 25°C Large Signal Frequency Response 32 21 ... , 2. -; : ~ TA \ ~ 20 "'& Inverter Pulse Response 10 y±:::: ±15V 16 Y±=±15V = +25°C TA= +25°C ---. ~--. 1\ ~ f '\ & : 12 o 100k 500 200 ......... 1M Frequency (Hz) - ::1:-- --- I II il -. --- -- --- --- Output ~--- -I I AII=1 ( I I -2 ~ ~ --- Input -I -10 10M • Time lIAS) II Operating Characteristics TA = 25°C Input Current Supply Current 100 2.5 - 80 ~ , 60 j: ---- 10-. 0 1 1.5 q I 1111 _ 0 20 U 80 TA - 2.0 j .. ril -i Lzooc 25iC 10°C 1.0 0.5 o 80 ±5 I ±15 ±10 Ambient Temperature (Oe) ±20 Supply Voltage (V) Common Mode Rejection Ratio Common Mode Input VoHage Range 120 20,-----,------;-----,------,-----,-----, TA=+25°C ~ 1100 & 16~----~------~----4_-----4--~~~----~ ~ & : ~ Ii 12~----~------~--~~~--~~----+_----~ i i .5 ! ! .r-~~~----_r----_+------r_----+_----~ 8 8 ~ ~ 0±~5------~----±~1~0----~------±~,~5----~----~±20 Sup,"y voltage (V) J Rs:51 kO ~ '"", 80 80 U 20 10 100 1k 10k Frequency (Hz) "" r..... 100k '-- I 1M 3-5 ttiEC JlPC301A Operating Characteristics (Cont.) TA = 25°C -- --- -"'" "" "" Supply Voltage Rejection Ratio Current Umiting ±15 120 C1 =30pF TA ~ +25°C iii 100 '- ~ & 80 ~ t 60 ~ II: & 40 1 20 ~ -20 10 100 '" ~ ~lsUPPIY "" "'~i~ " 10k 1k 100 k 1\ TF+80'f\ i'... /".. 1M I 10 M Frequency (Hz) (for Singi. Pole Compensation Circuit) Voltage Gain 110 -20"C ---::: ~ 100 --- I ~ ~ f..-90 ~ ~ 80 ±5 ±10 3-6 - 25'C 8 0"C ±1. Supply Yo"g. (V) TA 25"C I ±20 \ -20"C Y±:::: ±15 V o 10 ,. 20 25 Output Current (mA) 120 ~ ~ 30 35 t-IEC pPC318 HIGH-SPEED OPERATIONAL AMPLIFIER NEe Electronics Inc. Pin Configuration Description Thef./PC318 isa precision high-speed operational amplifier designed for applications requiring wide bandwidth and high slew rate. It features a factor of ten increase in speed compared to general purpose operational amplifiers, without degrading the DC performance. By incorporating internal unity gain frequency compensation, external compensation components are eliminated. The high-speed and fast settling time of the f./PC318 make it ideal for use in D/A converters, oscillators, sample and hold circuits. Features D Very high slew rate D Maximum bias current of 500 nA D Operates from supplies of ±5 V to ±20 V D Internal frequency compensation D Input and output overload protected D LM318 direct replacement 83-002082A Equivalent Circuit C, C, 1 8 ~o-~------------~----~------~~+-----~~----r---~-------------------. - Input O-~--"t-'-----!:. R" 2. 6 '----+---r-+----Q Output +In.ul~--~~~==;====:;=~==E1J!--l-----=~--1 4 ~~'----------~--------~------~-+--~---+----~------~--~~---+--~----OV83-002081C 3-7 II t-fEC pPC318 Ordering Information Electrical Characteristics Part Number Package Operating Temperature Range pPC318C Plastic DIP DoC 10 +70°C TA = 25°C, V± = ±15 V Limits Absolute Maximum Ratings TA = 25°C Voltage 8nun V+ and V- 40 V Power Dissipation 500 mW Differential Input Current (Note I) ±lomA Input Voltage (Note 2) Output Short Circuit Duration Operating Temperefure Range Storage Temperature Range ±15V Indefinite DoC to +70°C -55 to +15O°C Notes: 1. The inputs are shunted with back-to-back diodes for overvoltage protection. Therefore, excessive current will flow If a differential input voltage in excess of 1 V is applied between the inputs unless some limiting resistance is used. 2. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Parameter Symbol Input Onset Voltage Vio Input Offset Current Input Bias Current Input Impedance RIN 0.5 3 MO AVOL 88 106 dB Slew Rate SR 50 70 VIIlS Output Voltage Swing YOM Common Mode Input Voltage Range Vicm ±11.5 Common Mode Rejection Ratio CMRR 70 100 dB Supply Voltage Rejection R.tio SVRR 65 80 dB Supply Current ICC Large Signat Voltage Gain Min. Typ. Max. Unit 4 10 mV tlo 30 200 nA Ib 150 500 nA ±12 ±13 5 V mA 10 Test Conditions RS=IOoO Vo=±loV. RL 2: 2 kO Av = 1 RL 2: 2 kO RL = 00, Vo = 0 V Typical Applications Feedforward Compensation for Greater Inverting Slew Rate Offset Balancing Circuit 5k Input o-~""'I\r~-~-~ 8 6 >~-+--O Output pPC318C 27 k 1% 27 k 1% 2.5 k • Slew rate typically 150 VIpS * Balance circuit necessary for increased slew 83-002083A 3-8 83·002084A t\'EC /lPC318 Operating Characteristics TA = 25°C Voltage Gain Input Current 2 5 0 r - - - - - - - , - - - - - - - - , - - - - - - - - , - - - - - - - - - - - - - - - - , 50 120 V±=±15V /!TA 200~------~------_+--------r_------_,------_+ ~ 1150 -;;;,----1~-=-:c-=~1-=""'~F:::::::=:::::;~~~~~ I .. o .~ 40 ;( 30 S 100 ~------~------_+--------r_------~------_+ 20 50~------~------_+--------r_------~------_+ O~ _______L______ ~ -20 115 ~c I ..". 0> ;; 40 10 100 95 =5 ±10 Supply Voltage Rejection Ratio -- L >~'"...... "S ... -- ~ ~ '" 1k 10 k 100 k a: 80 ~ 1. 60 " ~ -g ::; 1M Frequency (Hz) 40 ~ ''\..... -2 0 100 Q .2 40 -Nega';.e SUPPIY,(/ Positive Supply 20 i Rs:::: 2 k TA "'"" +25 C 100 :!O -, ~ " .2 g .. TA = -t-25°C ~ 60 ~ g " 0 I 20 12 ~ - 100 1k i 1 '" ,'l 0 . '" 200 \ ~ §i 1 25°C 4 \ \ ...... ......... -200 r\ \ -400 o o 10 15 Output Current (rnA) 10M TA = +25°C 400 1\ TA = +80 a C 1M 100 k Input Current 0> ~ .5 10 k Frequency (Hz) V+=-'-15V 10 , ~ 10M Current Limiting 14 II Common Mode Rejection Ratio 120 80 I ±20 Supply Voltage (V) 100 ~c - §i Ambient Temperature (0C) iii :!O L ,'l 105 ~ 0 80 60 ~ %:,,"c /so"c -20°C ./ ________L ________L______~ 20 / 110 ~ 20 25 -0.8 '-0.6 -0.4 -0.2 0.2 0.4 0.6 \ I ~ 0.8 DiHerentiallnpul Voltage (V) 3-9 NEe IlPC318 Operating Characteristics (Cont.) TA = 25°C Large Signal Frequency Response 2B Open Loop Frequency Response 120 V±= ±15V ""'\ 24 TA = +25°C 100 ~ 60 ~ 40 ;, ....... ~ 20 I -20 10 100M 10M 100 1k 10k I 13S K'-V \ 90 "" 1M 100 k Frequency (Hz) Voltage Follower Pulse Response 4S .......... 10M 100M Inverter Pulse Response 20 16 16 - € f i 180 ~ 20 & 22S " "- Frequency (Hz) 12 V+ = ±15V TA = +2S o C ,OL ~ r\ 1M .......... iD \ \ 100k ........ BO \ \ 10 k - ~ --I -- i\ 1\ /Ou pU1 I /'npu, -4 I -B I \/ I i!. i/ ~ _£ -1.. v+ ±15 V TA - +25°C -16 1.0 0.6 Tlme(ps) 3-10 :\ € 1.4 -4 -B IV X _...F- -12 I 1.8 I I 1\ UI S " - -- - -- -- -- ·r 1/ V 0.2 12 10- I / -12 -20 -0.2 -- \ /~utPut I /11"put 1/ 1/ / V±= ±15 V TA = +25°C - - - ", Feed Forward -16 -20 -0.1 0.1 0.5 0.3 Time (PS) 0.7 I 0.9 I !. !l J tt{EC JlPC356 J·FET INPUT OPERATIONAL AMPLIFIER NEe Electronics Inc. Description Pin Configuration The tlPC356 is a J-FET input operational amplifier with matched P-channel ion implanted J-FETs. In addition to the obvious advantages of J-FET inputs, the tlPC356 is designed for high slew rate, wide bandwidth, and extremely fast settling time. Features D Low input offset voltage: 5 mV max (trimming technique used) D Offset adjust does not degrade drift or CMRR D The NPN sink output stage allows use of large capacitive loads (10,000 pF) without a stability problem D Internal compensation and large differential input voltage capability D LF356 equivalent 63-002189A Equivalent Circuit 7 r-------~----------------~--------4_----------_Qv+ - Input + Input 0--+-------------, ., t----t-----j--l4----t----+_Q Output ., 50k ~~--~----~------~----~--~--------~~~---+----~--~-----+----~--o~ 83·002188 3-11 II ttiEC JiPC356 Absolute Maximum Ratings Ordering Information Part Number Package Operating Temperature Range IlPC356C Plastic DIP O°C 10 +70°C Inpul OHsel Voltage Vio Inpul OHsel Currenl lio Inpul Bias Currenl Ib Large Signal Voltage Gain AVOL BB Max. Unit mV 50 pA 200 pA 106 dB Supply Currenl ICC Common Mode Rejection Ratio eMRR 80 100 dB Supply Voltage Rejection Ralio SVRR 80 100 dB Oulpul Voltage Swing VOM Common Mode Voltage VICM Slew Rale Inpul Noise Voltage Gain Bandwidlh Products 10 Test Conditions RSS 50 0 RL 2: 2 kO. Vo = ±IO V OHsel Voltage Drill DiHerential Inpul Voltage ±30 V ±15 V Indefinite Siorage Temperalure Range -5510 +125°C Note 1. For supply vOltages less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Typical Application mA Offset Voltage Null Circuit SR V+ ±12 ±13 RI2:IOkO .................................... ±IO ±12 V +10±15.1 -12 V RI 2: 2 kO v83-002190A VIIlS Rise .................................... en 12 20 VIlls 20 nV/y'HZ Fall f= I kHz. RI = 100 0 Operating Characteristics TA = 25°C Open Loop Frequency Response 120 GBW MHz V±=±15V 100 Over Operating Temperature Range fnpul OHsel Voltage 350 mW Operating Temperalure Range 2 30 36 V Power Dissipation Oulpul Shorl Circuil Duration Limits Symbol Min. Typ. Vollage Belween V+ and V- Inpul Voltage (Nole I) Electrical Characteristics TA = 25°C, V± = ±15 V Parameter TA = 25°C Vio t>Viol t> T " iD ~ mV IlV/oC RSS500. TA = TOPT ~" 80 60 TA = TOPT !< !S Inpul Bias Currenl Ib nA TA = TOPT Inpul OHsel Currenl lio nA TA = TOPT ~ ,!l .s 8. 0 "" 40 " ......... i'-. 20 o 1 10 100 ,. i'-. " 10. Frequency (Hz) 3-12 ......... 100 k < '" 1M ~ 10M t-IEC pPC356 Operating Characteristics (Cont.) TA = 25°C Voltage FoUower Pulse Response Undistorted Output Voltage Swing 28 15 V±~±15V v± ~ ±15V Ay=1 RL=2 k 24 10 ~ \ ~ 10 k \ \ \ -15 -1 10M 1M / V -10 ! """ lOOk \ l'output \ o / ".put 2 3 Timo (jAs) Frequency (Hz) Input Equivalent Noise Voltage Swing 40 200 RL=2kO: Y±=±15V As = 100n 160 ~ ~ I ~ 120 '" 80 V "- Z 40 o V '" '\. V "'-"-.. 120 10 - 1k ... V ,/ ~ 10k ~ ~ o o 100k ~ 15 ±10 ±20 Supply Voltago (V) Freq......y (Hz) Input Bias Current Voltage Swing 10 34 V±=±15V V±~±15V 32 ~ V --- co s ~ il i !; ~ o. 1 V V 4 V 0.1 1 ~ i 1.0 Output Load (Idl) 10 ~ 0.0 1 20 10 10 20 ....- 30 ~.,. 40 50 ...V 60 Ambient Temperature (Oe) 3-13 t-fEC J.lPC356 Operating Characteristics (Cont.) TA = 25°C Common Mode Rejection Ratio Input Bias Current --......"- 100 300 V±=±15V iD 250 i I ,; 200 / 150 III iS 100 ---- 50 o 10 / V ~ I 80 8 ;;. ~ 60 I 40 V±=±15Y RL= 2k "'- J / . "" ~ ~ E U o 10 "'- 20 10 1k 100 "" 100k 10 k Common Mode Voltage (V) Frequency (Hz) Supply Voltage Rejection Ratio Supply Current ~ 10M 1M ,...,.~20oe ~ - -- i-"'" o ±5 I ±15 ±20 Output Sink Current Output Source Current 15 V± ~ ±15V ~ 10 ·r -20°C v± = ±15V ......... -10 ~~ UI & & ~ !! 25°C i 'S ~ I 70 0 e 0 I til 10 15 20 25 Output Source Current (rnA) 3-14 TA - +70°C Supply Voltage (V) 15 ..·r TAj5 0 e V ±10 Frequency (Hz) ~ A ~ ~ V V 2 ~ 30 35 40 70 0 e -20°C 25 c C -5 o o 10 15 20 25 Output Sink Current (rnA) 30 35 I 40 NEe NEe Electronics Inc. pPC357 J·FET INPUT DECOMPENSATED OPERATIONAL AMPLIFIER Description Pin Configuration The JlPC357 is a decompensated operational amplifier with matched P-channel ion implanted J-FET inputs. When the closed loop gain is greater than five (Av > 5) the JlPC357 has a slew rate of 50 V per microsecond and a bandwidth of 20 MHz. This device is ideal for applications which require high-input impedance and high-frequency operation. Features o o o o o o Low input offset voltage: 5 mV max Offset adjust does not degrade drift or CMRR High slew rate: 50 VI JlS (Av > 5) Wide bandwidth: 20 MHz Suitable for high-speed inverting amplifiers and active filter applications LF357 equivalent 83-002205A Equivalent Circuit r-------~----------------~--------~----------_Ov+ - Input 0--+------------, + Input +-----+-----!----1I4----+-..+_o output 013 R5 5k L--..+--~----+_ ______ ~ ____ R, 5k R, 50k +_--~--------+_~~_+----~--~~_+----+_--O~ 83-002188 3-15 II t\'EC pPC357 Ordering Information Part Number pPC357C Package Plallie DIP Electrical Characteristics = 25°C, V± = ±15 V, TA Oplratlng Tlmperatura Ranga DOC 10 +70°C Limits Paramater InpUI0Il811 Vol.... Input OHaIl Curl'ltll Absolute Maximum Ratings TA = 25°C VOI"'I BBlwHn v+ lid V- 36V 350mW Power DIsI".uon DllI8rlnllallnput VollIgl +30 V +15V lodlllall8 Input Vol".1 (S88 nOllI output Sbert Circuli Durliion Operating Tampanlll1 Ringe s....... T.mparllull Ringe Nota: For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification Is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Typical Application Offset Voltage Null Circuit Input Bias Currant Large SlgOlI Vol.... Gila Supply Currant Common Mode Rejacllon Rilla Supply Vollage Rljlclloa Rilla Oulput Vol".1 Swing Cammon Mod. VOIlagI Slaw RIIa V+ Input Naill Valilgl Symbol Min. Typ. Max. UIII Via 2 5 mV lio 3 50 pA Ib 3D 200 pA AVOL 88 5 ICC dB 106 10 V83-002190A 3-16 RS:55DO RL<::2kO, VO=±IOV mA CMRR 80 100 dB SVRR 80 100 dB .~~~. ;!;I.~ ..........~ .... ~! ~ ".0. ~~.. . ±IO ±12 Vlem SR In V ±10+15.1 -12 V/fJS 50 V/fJS Rise Fall 1= I kHz. nV/.JHi RI = 1000 20 MHz mV Via AVlo/AT RI <:: 2 kO V 50 Gain 8andwldlh GBW 20 Praduell Over Operating Temperature Range InpUI 0II1II Vol.... on... Vol.... Drift Inpul BIIS CUrr.1d Input 01IIII Currlnl Test COldlllons RS:5 50 0, TA = TOPT pV/oC TA = TOPT 5 Ib 8 nA TA = TOPT 110 2 nA TA = TOPT NEe Il PC357 Operating Characteristics TA = 25°C Open Loop Frequency Response Undistorted Output Voltage Swing 120 28 v± 24 100 '"'" iC ~ .~ 80 ",!!! 0 0> 60 ~ .§" [ 40 0 20 o 10 1 100 ~ 20 0> .j 16 en '"'" 10 k 1k 100 k J 12 ~ , % ,~ 0 ~ 1M o 10 k 10 M 1M 100 k 10 M Frequency (Hz) Frequency (Hz) Voltage Follower Pulse Response II Input Equivalent Noise 15 200 V±=±15V I 10 V± = ±15 V Rs = 100 n Av= 1 160 / Input"-..,. ~ 0 0> 'g," ~;; I'output % - 5 1 oS / 0 ~ J \ ~ 0 I'\. """ 60 ~ Z 40 V -1 120 'S \ V -10 o 10 "'--r-1k 120 28 RL ..,-2kO l,...-- I""'" V±-±15V 24 10-' 0: 30 ~ ·r ·r J /' en 20 en V 'S 10 "if ~ V "- % 0 ~ I 20 / 16 / ~ i . . .V 12 // 0 ,/' ~ ij o o 100 k Voltage Swing Voltage Swing 40 ~ 10 k Frequency (Hz) Time{Jls) 8. ±15V RL. = 2 k AR= 5 V±=±15V g ±10 Supply Voltage (V) 15 ±20 / 0.1 1.0 I 10 Output Load (kO) 3-17 !VEe pPC357 Operating Characteristics (Cont.) TA = 25°C Input Bias Current Input Bias Current 10 300 V±=±15V V± = ±1S V 250 C ~ s l a . iii 'S ]" - 0.1 .......... V 0.01 20 10 10 20 30 IJ ,..V 1 200 / 150 / 100 - 50 40 50 o 70 60 ~ 10 Common Mode Rejection Ratio 80 :!!. ia: ...t 60 "" . ~ a: " g ~ 10 100 1k b..... 10 k 10 60 !I 40 1M ~ c---...... i'... V±=±15V ~ '" i'... ....... Neg~ '" ~ """ 100 k 80 . 1 ~ 20 o iii 100 :!!. .2 ~ E i-- V± = ±15 V Rl = 2 k 40 . " / 120 a: ,.~ / Supply Voltage Rejection Ratio 100 r--.... r--.... V Common Mode Voltage (V) Ambient Temperature (OC) iii" / Supply Positive ~PIY ......... ......... 2: Ji o 10 """"" 20 100 1k 10k Frequency (Hz) ","" 1M 100 k Frequency (Hz) Supply Current "" 10 M Output Source Current 15 v± ~ 6 ,. V ii 5 u icil 5 ,..,..- 4 2 I-""'" ,..,.. - ,..-~ ,..- .......- ~ I8- ATAJ5 C 20°C ~ 0 TA 10 25°C ~ 1 'S = -t-70°C WC 0 ~ I g o ±5 ±10 Supply Voltage (V) 3-18 .......... ~20OC ±15V ±15 ±20 10 15 20 25 Output Source Current (rnA) 30 35 I 40 NEe J,lPC357 Operating Characteristics (Cont.) TA = 25°C Output Sink Current -15 ~ v± = ±15V ......... -10 ~ \"'7O'C -20'C 25'C -5 o o 10 15 20 25 30 35 I 40 Output Sink Current (mA) II 3-19 pPC357 3-20 NEe NEe NEe Electronics Inc. IlPC741 GENERAL PURPOSE OPERATIONAL AMPLIFIER Description Pin Configuration The JlPC741 is a general purpose operational amplifier which incorporates internal frequency compensation (C1 = 30 pF). It is intended for a wide range of analog applications where high quality and low cost are required. High common mode voltage range and latchfree operation make this amplifier ideal for use as a voltage follower. Features D D D D D D Internal frequency compensation Short-circuit protection Offset voltage null capability Large common mode and differential voltage range No latch-up JlA741 direct replacement 83-002015A Equivalent Circuit ,-----~------~------~--------~--~------~------------~__ov+ Input o-----f------+---+----. R, 30 n + Input Output R10 25 n C, 30 pF Q" Offset Null 0---4 o---{---+ 5 R, R, 1k 5k 4 L--~--~--+----+----~--+---~-~----~---+-__oV 83-002014C 3-21 II ttiEC Il PC741 Ordering Information Part Number Package Electrical Characteristics = 25°C, V± = ±15 V TA Operating Temperature Range pPC741C Plaslic DIP DoC to +70°C pPC741G2 Plastic Miniflat DoC to +70°C Limits Absolute Maximum Ratings TA = 25°C Voltage Between V+ and V 36 V Power Dissipation. C Package 350 mW Power Dissipation, G2 Package 440 mW Differential Inpul Voltage ±30 V Input Voltage (Note 1) ±15 V Outpul Short Circuit Duralion Indefinite Voltage Between Offsel Null and VOperating Temperature Range ±0.5 V 010 +70°C Siorage Temperature Range -55 to +125°C Notes: 1. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Typical Application Offset Voltage Null Circuit Symbol Input OHsel Voltage Vio Input Offset Current Input Bias Currenl 83-002016A Max. Unit 1.0 6.0 mV lio 20 200 nA Ib 80 500 nA large Signal Voltage Gain AVOl Offset Voltage Adjustable Range Min. Typ. Test Conditions RS:Sl0kO 106 dB Rl2: 2 kO, Vo = ±10 V ""Vi. ±15 mV VR1=10kO Supply Current ICC 1.5 2.8 mA Power Consumption Po 45 85 mW Common Mode Rejection Ratio CMRR Supply Vollage Rejection Ratio SVRR Output Voltage Swing VOM Outpul Voltage Swing VOM OUlput Short Circuit Currenl IlPC741C/G2 3-22 Parameter ISHORT 88 dB RS:S 10 kO dB RS:Sl0kO ±12 ±14 V Rl2: 10 kO ±10 ±13 V Rl2: 2 kO 70 90 89 20 103 mA Rl = 0 t\'EC JlPC741 Operating Characteristics TA = 25°C Open Loop Frequency Response Large Signal Frequency Response 120 32 TA:::: 25°C 11 0 V±=±15V 100 0 . 70 ~ 40 RL;;:::10kO .......... 0 I~ TA=25°C V±=±15V- 28 r...... t"-.. a6 E5 \ \ .......... 0 i'. 0 0 " '" ~ 0 0 0 100 10 1k 10k '" " lOOk Frequency (Hz) o 1M ~ "- r'--..... o 10k 1k 1M 100k Frequency (Hz) Output Voltage Swing II Output Voltage Swing RL2::2kO 30 40 iE ~ ./ ., 'j ./ & J!! ./ ~ 20 ....... 1' J o v± 0,1 10 ...... 1' V' ±15V 100 00 ±20 ±10 Supply Vonage (V) Load Resistance (kO) Power Consumption Supply Current 100 I i E 50 ! J - - ./' L ./ ~ ./' V /' ".,... 0 L V v '/ V ~ ±10 Supply VoRage (V) ±20 ±10 ±20 Supply Voltage (V) 3-23 ttlEC pPC741 Operating Characteristics (Cont.) TA = 25°C Supply Current Output Short Circuit Current 0 V± = ±15V V± = ±15V 0 I j -~ 0 ~ 1~--t---+---+---+---+---1---1---1----r--~ J - r- 0 - - r---r-~--~---+---t---t--~---r---r--,I oL_~20~~--~--~--2~0~~--~~~~--~60~--~~ao 0 20 20 40 Ambient Temperature (OC) Ambient Temperature (OC) Power Consumption I 50r---r---t---t---+---+---+---+---+----r--~ I 20 20 40 60 60 Ambient Temperature (OC) Input Offset Current V±-±15V 60 40 i 20 u ............. ......... t--. """- £ I 0 -20 -40 3-24 20 20 40 Ambient Temperature (0C) V± = ±15V \. "' 100 .......... ........... ......... 0 0 20 20 -......... 40 Ambient Temperalure (DC) 80 cS I'\. '\ I I I .5 150 ~ e 60 Input Bias Current 100 r---r---r----,----,----,---,----,----....,.----r----, V±=±15V t j 60 60 ao 60 60 NEe NEe Electronics Inc. pPC811 J-FET INPUT LOW-OFFSET OPERATIONAL AMPLIFIER PRELIMINARY INFORMATION Description Pin Configuration The tlPC811 operational amplifier offers high input impedance, low offset voltage, high slew rate, and stable ac operating characteristics. NEC's unique highspeed pnp transistor (fT = 300 MHz) in the output stage solves the oscillation problem of current sinking with a large capacitive load. Zener-zap resistor trimming in the input stage produces excellent offset voltage and temperature drift characteristics. Features D Stable operation with 10,000 pF capacitive load D Low input offset voltage -2.5 mV max -7 tlV/oC temperature drift D Low input bias and offset currents D Low noise: en = 20 nV/VHZ D Output short-circuit protection D High input impedance D Internal frequency compensation D High slew rate: 15 V/tlS Equivalent Circuit L -_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ Ordering Information Pari Number JlPC811C JlPCallG2 7 v+o-------~--------~----- ~83.~0 1~902~. Package Operating Temperature Range 8·Pin Plastic DIP -2010 +7DoC a·Pin Plastic Miniflal -2010 +70°C -Input 6 Output Trimmed R2 4 V-o-~~--~---------+--~ 83-001901A 3-25 IIiJII fttIEC pPC811 Recommended Operating Conditions Parameter Supply VOllage Symbol Min. V± ±5 Typ. Absolute Maximum Ratings TA = 25°C Max. Unit ±16 V VOllage Belween V+ and V- pF Power Oissipalion, CPackage (Note II 350mW rnA Power Dlsslpallon, G2 Package (Note 21 440mW Capacitive Load CL 10,000 Oulpul Currenl 10 10 Oillerenliallnpul VOllage Common Mode Inpul Vollage (Note 31 Electrical Characteristics TA = 25°C, V± = Oulpul Shorl Circuli Duralion ±15 V LImits Parameter Symbol Min. Typ, Max. Unit Input Ollset Voltage Vlo I 2.5 mV Input Ollset Current 110 25 100 pA Input Bias Current Ib 50 200 pA Voltage Gain AVOL BB 106 dB Test Conditions Rs = 50 0 RL=2kO, VO=±IOV Supply Current Icc Common Mode Rejection Rallo CMRR 70 100 dB Supply Voltage Rejection Rallo SVRR 70 100 dB Output VOllage Swing Vom ±12 ±13.5 V RL=IOkO Output Voltage Swing Vom ±10 ±12 V RL = 2 kO Common Mode Input VOllage Range Vlem ±11 V Slew Rate Input Equivalent Noise VOllage en Unity Gain Frequency 2.5 3.4 rnA 15 VIpS Av=+1 20 y1iZ 1= I kHz 4 MHz nVI Rs= 1000, Over Operating Temperature Input Ollset Voltage Vio Input Ollset Voltage Drift Ll.Vio/Ll.T mV Rs = 50 0, TA = Topt /lV/·C TA = Topt Input Bias Current Ib 7 nA TA = Top! Input Ollset Current 110 2 nA TA = Top! 3-26 Operallng Temperature Range Storage Temperature Range 36V ±30 V ±15V Indefinite -20 to +70·C -55 to +125·C Notes: 1. Thermal derating factor is 5 mW/·C when ambient temperature is higher than 55 ·C. 2. Thermal derating factor is 4.4 mW/·C when ambient temperature is higher than 25 ·C. 3. Forsupply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Rati ngs" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. NEe NEe Electronics Inc. J.lPC813 J-FET INPUT LOW·OFFSET OPERATIONAL AMPLIFIER PRELIMINARY INFORMATION Description Pin Configuration The t/PC813 operational amplifier is a high-speed version of the t/PC811. NEC's unique high-speed pnp transistor (fT = 300 MHz) in the output stage yields a high slew rate of 25 V/t/s under voltage-follower conditions without an oscillation problem. Zener-zap trimming in the input stage produces excellent offset voltage and temperature drift characteristics. With ac performance characteristics that are two times better than conventional bi-FET op amps, the t/PC813 is ideal for fast integrators, active filters, and other high-speed circuit applications. Features o o o o o o o o High slew rate: 25 V/t/s Stable operation with 220 pF capacitive load Low input offset voltage -2.5 mV max -7 t/V/oC temperature drift Low input bias and offset currents Low noise: en = 20 nV/$z Output short-circuit protection High input impedance Internal frequency compensation 83-001902A Ordering Information Part Number Package IJPC813C 8-Pin Plastic DIP Operating Temperature Range 8-Pin Plastic Miniflat Equivalent Circuit 7 v+o-------~----------~---, -Input Output R1 Tdmm",rl R2 4 V-o---~---+----------+---~ 83·0Q1901A 3-27 II ftt{EC JlPC813 Recommended Operating Conditions Typ. Max. Absolute Maximum Ratings Unit TA = 25°C Symbol Min. Supply Voltage V± ±5 ±16 V Voltage 8etween V+ and V- Capacitive Load CL 220 pF Power Dissipation. C Package (Note IJ 350 mW OutpUI Current 10 10 rnA Power Dissipation. G2 Package INoie 21 440 mW Parameter Differential Input Voltage Electrical Characteristics Input Voltage INote 3J TA = 25°C. V± = ±15 V Output Short·Circuit Ouration Limits Parameter Input Offset Voltage Input Offset Current Input 8ias Current Symbol Min. Typ. Max. Unit I Vio 2.5 mV liD 25 100 pA Ib 50 200 pA 88 d8 RL = 2 kO. Vo=±IOV rnA Both channels Supply Current Icc Common Mode Rejection Ratio CMRR 70 100 d8 Supply Voltage Rejection Ratio SVRR 70 100 d8 Output Voltage Swing Vom ±12 ±13.5 V RL = 10 kO Output Voltage Swing Vom ±10 ±12 V RL = 2 kO Input Voltage Range Vicm ±II Slew Rate en Unity Gain Frequency 3.4 25 V//ls Av = 1 20 y'HZ I = I kHz nVI R8=1000. MHz Over Operating Temperature Range Input Offset Voltage Vio Input Offset Voltage Drift t:.V i01 l'.T mV Rs = 50 O. TA=Topt /lVI 'C TA=ToPt Input 81as Current Ib nA TA=Topt Inpul Oflset Current liD nA TA = Topt 3-28 ±15 V Indefinite Operating Temperature Range Storage Temperature Range -55 to +125'C Notes: 1. Thermal derating factor is 5 mW/oC when ambient AVOL 2.5 ±30 V R8 = 50 0 Voltage Gain Input Noise Voltage 106 Test Conditions 36 V temperature is higher than 55'C. 2. Thermal derating factor is 4.4 mW/'C when ambient temperature is higher than 25'C. 3. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. NEe NEe Electronics Inc. J.lPC4061 J-FET INPUT LOW-POWER OPERATIONAL AMPLIFIER PRELIMINARY INFORMATION Description Pin Configuration The pPC4061 is a J-FET input low-power operational amplifier featuring low supply voltage operation from ±1.75 V. Supply current is ten times smaller than pPC4081 type J-FET input op-amp. With very low input bias current characteristics, the pPC4061 is an excellent choice for hand-held measurement equipment and other low-power application circuits. Features D D D D D D D D Low supply current: 230 pA Very low input bias and offset currents High slew rate: 3 Vips High input impedance Low supply voltage operation Output short-circuit protection Internal frequency compensation TL061 direct replacement 83-002015A Equivalent Circuit V' R4 Rl R9 OS~______________________~~0=9______~________~~~__________~r- ____, 011 -Input R. +Input 017 010 Q12 01. RS R7 Cl 013 07 Rl0 OFFSET 1 NULL OFFSET 5 NULL 0----+----------. R2 06 R3 :1------+ 019 R6 V-· 6 Output 83~002820B 3-29 II ~EC pPC4061 Ordering Information Part Number pPC4061C pPC4061G2 Absolute Maximum Ratings TA Operating Temperature Range -20 to +70°C -20 to +70°C Package Plaslic DIP Plaslic Minillal Recommended Operating Conditions Limits Parameter Symbol Min. Typ. Supply Voltage V± OUlpUI Currenl 10 Source 10 Sink ±2 load Capacitance (Voltage Follower) Max. Unit ±16 V 5 3.5 mA 220 = 25°C Voltage Belween V+ and VPower Dissipation INoie I), C Package Power Dissipation INote 2), G2 Package Dillerenliallnpul Voltage Inpul Voltage, INoie 3) Oulpul Shorl Circuit Duration Operating Temperalure Range Storage Temperature Range Test Conditions 36 V 350 mW 440 mW ±30 V ±15 V Indelinile -2010 +70°C -5510 +125°C Notes: 1. Derate at 5 mW/oC above 55°C. 2. Derate at 4.4 mW/oC above 25°C. 3. For V± < ±15 V, VIN (max) = V±. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated inthe operational sections of this speCification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. pF Electrical Characteristics TA = 25°C, V± = ±15 V Limits Parameter Inpul Ollset Voltage Input Ollset Voltage Input Ollset Voltage Drift Input Ollset Current Input Ollset Current Input Bias Current Input Bias Currenl Symbol Min. Typ. Unit 10 mV HS = 50 15 mV RS = 50, TA = TOPT pvrc HS = 50, TA = TOPT Vio Vio 2 AViol AT 10 5 50 pA 1.5 nA 10 100 pA lio lio Ib Ib 3 AVOL Supply Currenl Common Mode Rejection Ralio ICC CMRR 70 95 dB Supply Voltage Rejection Ratio SVRR 70 95 dB Vom ±12 ±14 V Vicm 10 Source 10 Sink SR ±12 +15,-13 V Outpul Voltage Swing Common Mode Input Voltage OulpUI Currenl Slew Rale Input Noise Voltage 230 +5 -3.5 en d8 75 30 Gain Bandwidlh Producls GBW Over Operating Temperature Range 260 TA = TOPT nA large Signal Voltage Gain 69 Test Conditions Max. RIN = 10k, Vo = ±1O V pA mA HIN = 10k Vom=±10V Vips HIN = 10k nV/y'Hz f = I kHz MHz large Signal Voltage Gain 66 d8 __ ~~ ____ ~__________ ~~ T~A~=_T~O~PT~_________________ AVOL ______________________________________ CMRR 70 Common Mode Rejection Ratio 90 d8 __________-'----___________________________________________________ TA = TOPT. _ _ _ _ _ _ _ _ __ Supply Voltage Rejeclion Ratio SVRR 70 90 d8 OulpUI Voltage Swing Vom ±3.8 ±4.1 V Common Mode Inpul Voltage Vicm H.7 -2.8 +5.2 -3.5 3-30 TA=TOPT NEe NEe Electronics Inc. IlPC4071 J-FET INPUT LOW-NOISE OPERATIONAL AMPLIFIER Description Pin Configuration The J-FET input operational amplifier of the tJPC4071 is designed as low-noise versions of the tJPC4081. The features ofthetJPC4071 have more improved input equivalent noise voltage, input offset voltage, and input bias current, than those of the tJPC4081. The tJPC4071 is an excellent choice for a wide variety of applications, including preamplifier and active filter circuits. Features o o o o o o o o Low noise: en = 18 nV/VHZ Low input bias and offset currents Output short-circuit protection High input impedance: J-FET input stage Internal frequency compensation High slew rate: 13 V!jj.S Latch-free operation TL071 direct replacement 83-00224SA Equivalent Circuit ,---------~----------~----~----~------~-------ov~ - Input R8 + Input 0----1----------+----' ~-'V'oIV--+------+--------o Output R, 013 0 ,5 03 ....------,. OFFSET NULL o--+-----/----~ R, R, L---~----~ ____ R5 ~ __________ 0, R, ~ __ ~~ ____ 4 ~----~~--~__ov- 83-0022446 3-31 t¥EC JlPC4071 Absolute Maximum Ratings Ordering Information Part Number TA Operating Temperature Range Package IlPC4071 C Plastic DIP IlPC4071 G2 Plastic Minillat = 25°C Voltage Between V+ and V- 36 V Differential Input Vollage Input Vollage Isee Note 0° to +70°C ±30 V 11 ±15 V Power Dissipation, C Package 350 mW 440mW Power Dissipation. G2 Package Recommended Operating Conditions Limits Parameter Symbol Supply Voltage V± Capacitive Load IAv = +IJ Outpul Currenl Min. Typ. Max. Unit ±5 ±16 V CL 100 pF 10 10 rnA Indefinite Outpul Shorl Circuit Ouration Operating Temperature Range Test Conditions o to +70°C Storage Temperature Range -55 to +125°C Note: 1. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA = 25°C, V± = ±15 V Limits Parameter Symbol Min, Typ, Max, Unit Test Conditions Input Offsel Vollage Vio 10,0 mV Input Offsel Current lio 50 pA TA = 25°C Isee Note IJ 200 pA TA = 25°C Isee Note IJ dB RL~2 2.7 mA Input Bias Current 30 Large Signal Vollage Gain AVOL Supply Current ICC 88 106 2.0 Common Mode Rejection Ratio CMRR 70 86 dB Supply Vollage Rejection Ratio SVRR 70 86 dB Output Vollage Swing Vom ±12 ±13.5 Output Vollage Swing Vom ±IO ±12 Common Mode Input Voltage Range Vicm ±IO Slew Rate Input Noise Vollage Unity Gain Bandwidth SR kQ, Vo =±10 V RL~ 10 kQ RL ~ 2 kQ V V 13 AV = 1 V//ls .... ,e? ..... , ........ 1.8..•.......... n.V!~ ............ ~~ ~ .1.0.0.1?:.f .~.I. ~~~ ................. . 4 RS = 100 Q, I = 10Hz to 10kHz GBW 3 MHz Over Operating Temperature Input Offset Vollage 13 Average Input Offset Voltage Drift Input Bias Current Input Offset Current liD mV /lvrc 10 2 RS:S 50 Q, TA = TOPT TA = TOPT nA TA = TOPT nA TA = TOPT Note: 1. Input bias currents are temperature sensitive. Short time measuring method is recommended to maintain the junction temperature close to the ambient temperature. 3-32 ttiEC pPC4071 Typical Application Offset Voltage Null Circuit 6 3 V83-003074A Operating Characteristics Power Dissipation 600 Open Loop Frequency Response 120 I V±=±1SV RL=2 kO 500 i g 100 G Package ;;g c ............ C Package ~c . l"'-... ...... -......:: 300 200 80 ~ 60 ~ ~ 40 100 o '" ...... 400 J ~ ~ o o 20 40 80 60 "-'- 100 1 10 100 Large Signal Frequency Response 100 k """'1M 10 M Output Voltage Swing 40 V± = ±15 V RL RL.=10kO = 10 kO ~ 20 'i'" '" . " \1+ '"8, = ±10V \ ~ > ;; 10 ~ 0 o 1k ~ ~ 2k 10 k Frequency (Hz) 30 / 20 , ~ \. \ V± - ±5 V 100 10 k 1k "-'- Frequency {Hz} {eel 30 g' "'-i'.. 20 Ambient Temperature ".;: II = 25°C TA 0 I\. 1M 10 ./ o 10M o ,/ / V ./ ,/ ±10 ±20 Supply Voltage (V) 3-33 ftIEC pPC4071 Operating Characteristics (Cont.) TA = 25°C Voltage Follower Pulse Response Output Voltage Swing 30 V±=±15V ./ V o 100 / ~ / 3k 1k Input Bias Current Input Equivalent Noise Voltage ~ ! 10 1 E V '" 0.1 103r-----t-----+-----+-------i 110 f-----t-----+-----+-------i z ..c i ./ ......... V V±=±15V Rs =100 n J 1l / ~ ",; 1.0 1 2 10 r~::::::::~~~~~~~~~~~~~~ f- ~ 1L-_ _ _ _L -_ _ _ _ 0.01 -20 20 40 80 60 Ambient Temperature (OC) Supply Current 1--:::l:==:::::::::~;;;;;;;;==1==.--1 " ! ~ 1.5 f - - - - - + - - - - - + - - - - - + - - - - - I f-----+------+----+-----i !l- UI 0.5 r - - - - - t - - - - - - j - - - - - + - - - - - - - i 0~ o _ _ _ _L __ _ _ _ ±5 ~ ____ ±10 Supply Voltage (V) 3-34 10 100 ~ ~ ____ ±15 ~ I ±20 ~ _ _ _ __ L_ _ _ _~2 1k Frequency (Hz) 2.5.------,------,.-------,------, 1.0 I ,l. 10'.------,-----,-----,-----, v± = ±15V "a = ±15 V Time (,us) 100 2.0 V± 10 Load Resistance (0) I RL=2kO CL = 100 pF 1\ 1\ V / 300 Output 10k lOOk ftt{EC tJPC4081 J-FET INPUT OPERATIONAL AMPLIFIER NEe Electronics Inc. Pin Configuration Description ThepPC4081 is a single operational amplifier with a combination of matched ion implanted P-channel J-FET inputs with standard bipolar transistor technology. The very low-input bias current and high slew rate (ten times that of general purpose operational amplifiers) makes this device an excellent choice for integrators, active filters, and pulse amplifier applications. Features D Wide common-mode and differential input voltage range D Low input bias and offset currents D Output short-circuit protection D High input impedance: J-FET input stage D Internal frequency compensation D High slew rate: 11 VIps typical D Latch-free operation D TL081 direct replacement 83~002245A Equivalent Circuit r---------~----------4r----~----~------~-------Ov+ -Input R, + Input 6 0-------,1----------+----' +--'VII'r----+-------f-------~ Output R, Q, OFFSET NULL Q15 -r-----.. 0----+----1-------+ R, R. Rs R, L---~----~----+-----------~ R11 D, 4 ____~----~----__~--~--~v83-0022448 3-35 II ttlEC pPC4081 Electrical Characteristics Ordering Information TA = 25°C, V± = ±15 V Limits Parameter Symbol Min. Typ. Max. Unit Input 011811 Vollagl Vio 5.0 15.0 mV Input 011811 Currenl 110 5 200 pA Inpul Bias Curranl Large Signal Vollage Gain Supply Curranl Common Mode RejeCiion Rlilo Ib AVOL 3D BB ICC 400 2.0 2.B RS:;:; 50 0 CMRR 70 76 Plastic Minillat DOC to +7o°c 36 V Power Dissipalion. CPackage 350 mW Power Dissipation [Note I). G2 Package 440 mW Dinerenlial Input Voltage ±30V ±15V Output Short Circuit Durliion Indallnlte operliing Temparatura Range Storage Temperature Range YOM ±12 ±13.5 OUlpul Voltage Swing VoM ±Io ±12 Common Mode Inpul Voltage Swing Vicm ±Io V Slew Rlla SR 11 V/(..IS Input Equlvalenl Noise Voltage en 25 Unity Gain Bandwidth GBW 3 70 76 dB v RL2::lokO -55 to +125°C Notes: 1. For supply voltages less than ±22 V. the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Typical Applications Offset Voltage Null Circuit Av= I b MHz 100 k v- Vlo t.Viol t.T Input Bils Curranl lio pPC4081C/G2 nV/y'iiZ f = I kHz. RS=loOO Over Operating T8mperature 3-36 IlPC4oBIG2 Voltage Belween V+ and V RL 2:: 2 kO, Vo=±loV dB Output Voltage Swing Input 011811 Curranl Plastic DIP Input Voltage [Nole I) SVRR Input Offset Voltage Drill Package IlPC40BIC Operating Temparature Range Absolute Maximum Ratings mA Supply Vonage RejeCilon Rallo Input 0ff181 Voltage Part Number TA = 25°C pA dB 106 Test Comlitions 20 mV RS:;:;500. TA=ToPT 10 nA TA = ToPT 5 nA TA = TOPT 10 83·002246A ttiEC pPC4081 Operating Characteristics TA = 25°C Large Signal Frequency Response Open Loop Frequency Response 120 30 V± = ±15 V RL -2kO 100 iii " 0 " "- 60 ~ ~ 40 \ " o 1 10 100 ~ 10 k 1k " '" 100 k Frequency (Hz) " '" I 1M o 10M 100 10 k 1k 30 20 0 10 ./ o V / V o I 10M II OutputVoHage Swing - V± = ±15V ~ 1 ~ 1M 30 RL=10kO & 100 k Frequency (Hz) Output Voltage Swing I \. "\ V±=±5V 40 -t \ V±=±10V 20 a. RL=10kO = ±15V " ""- 80 :2- ~ V± V / ~ ./ /' V / I ±10 o ±20 / 100 Supply Voltage (V) 300 10 3k 1k Load Resistance (kQ) VoHage Follower Pulse Response Input Bias Current 100 ./ -5 V ""- Output r\ V±=±15V RL=2kO CL=100pF v± = ±15V 10 ~ '\ !II r·~ I I III o 1 2 nme~) 3 4 J 1.0 i5 ~ 0.1 ~ 0.01 -20 - /" V V" 20 ./ 40 80 80 Ambient Temperature (Oe) 3-37 t\'EC pPC4081 Operating Characteristics (Cont.) TA=25°C Input Equivalent Noise Voltage Supply Current 10' 2.• Y± = ±15V R.~1000 2.0 ~ 103 :c g ~ f :> 102 ·i Z i J r----r---- /' 1.• u i: ! 1.0 10 D•• 1 10 100 1k Frequency (Hz) 3-38 10 k I 100 k 0 ~ 0 ±. ±10 Supply VoHag. (V) ±1. ~ ±20 t-IEC pPC4250 PROGRAMMABLE OPERATIONAL AMPLIFIER NEe Electronics Inc. Pin Configuration Description The pPC4250 is a very versatile monolithic operational amplifier. The quiescent power dissipation, input offset and bias current, slew rate, and gain bandwidth product are determined by a single external programming resistor. Because this device is individually programmable, a large variety of circuit functions can be realized by stocking a single operational amplifier type. In addition, this device operates from as little as ±1 V, making it ideal for portable applications. Features o o o o o o o ±1 V to ±18 V power supply operation Standby power consumption as low as 500 nW Programmable electrical characteristics Internal frequency compensation Offset-voltage nulling capability Short-circuit protection LM4250 direct replacement 83-002256A Equivalent Circuit r-----------------------------------------~------------------------Ov+ 140k R6 2.Sk 6k Rs 5k R10 RII Q. QIO r o-+-~------~~------------------~~----~ ~~ET + 10k R, 10k R2 -Input R13 + Input 0-----+--------1: Q, o:u~ """"'' ' ' -0 100 k 6 Output 0--+---------; 10k Rs ~~05--+---~5~k~--~-------------+--------~----------~--------------+-----OV Null 83-002255C 3-39 II t-IEC pPC4250 Ordering Information Absolute Maximum Ratings TA = 25°C Volll1811a1w8111 V+ Ind VPower Dil8ipatlon. CPlcklge Powlr Dll8lpatlon. 82 Plcklgl Dllllreniial Input Volla88 Input Volllll (NOla I) 350 mW 440 mW ±30V ±15V 150pA Indefinitl o to +70°C -55 to +125°C ISET CarnRl Oulput Short Circuit Duration Oplrating Templraturl RIIIII Storlgl Temparatun Range Note: Part Number 36 V pPC4250C pPC4250G2 Package Operating Temperature Range Pllslic DIP Plastic Mlnillal DOC 10 +70°C o·C 10 +70·C 1. For supply voltages less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA = 25°C. V± = ±15 V Limits Paramatsr Symbol Typ. Max. Unit 5 mV ISET= I pA. RS::; 100kO 110 ...................~ ...... ~~ ....I~~! .~.I.~~ .................................... . Ib .............................................................................. 20 10 .................. io· ..... Input Bias Cumld Test Conditions :::::::::::::::::::~:::::: ~~::: :I~ri:~ :(~~.:!~ ~ ~I:.~:~ :R~:~: ~~~ ~~:::::::::::::: 6 mV ISET=IOpA.RS::;IOOkO ···················6······ ~v··· ·lsET ·~·I·O~A: v±· ~ ±1.5 v: RS·;';· ioo to············· Input onaet Voillge Input Ollaat CurreRI Min. nA nA ISET = 10 pA ISET= I pA ~A·· . ·ISET·~ ·1· ~;.: v± ~ ±1.5·V .•....................... 75 nA ISET = 10 pA ··················75······ ~ ... ·lsET·~ ·I·O~A: Voltage Gain AVOL 11 ICC ~ ±1·.5"V························· ...~~ ..................... ~~ ....Im.~ .I.~~.. !~.~ .~~~ .V: ~~:~. ~~~ ~~ .............. . 95 Supply Curnnt v±· dB pA ISET = 10 pA. Vo = ±Io V. RL = 10 kO ISET = I pA :::::::::::::::::::~::::: :~~::: :I~ri:~ :(~~: !~: ~ ~Iy~::::::::::::::::::::::::: 100 pA ISET = 10 pA 330 pW ISET = I pA ··················90····· .~;. ... ·lsET ·~·I·O~A: v±· ~ ±1.5 v························· ··················24····· ·~w··· ·ISET·~·I·~;.:v± ~ ±1.5·V························· Power Dll8lplllon 3-40 Po .............................................................................. 3.000 pW ISET = 10 pA ................. ·iio···· ·~w··· ·ISET ";';I·O·~A: v±· ~ ±1".5 v························· NEe JlPC4250 Electrical Characteristics (Cont.) TA = 25°C, V± = ±15 V Limits Parameter Symbol Min. Typ. Max. ±13.5 V . ':1:0:6' .................... 'v ... Input Voltage Range Yicm Test Conditions Unit ISET = I pA '1' ~A" vi ~ ±1·.5 'v' ........................ . .............................................................................. ±13.5 V 'ISET'~ ISET = 10 pA .·:1:0:6·····················v··· 'lsET'~ 'I'O'~A" v:t'~' ±1'.5 ·Y························· Output Yoltage Swing Yom Common Mode Rejection Ratio CMRR ... ~~ ..................... ~~ ....Im.=: .I.~~ .. ~~ .~.I.O. ~~.......................... . Supply Voltage Rejection Ratio SVRR 74 dB ISET = I pA. RS S 10 kO .............................................................................. 70 dB 74 dB ISET = 10 pA. RS S 10 kO ISET = 10 pA. RS S 10 kO II Typical Application v+ v+ 7 pPC4250C/G2 6 RSET ~ ISET vISET = v- v+ + lv-I - 0.5 ISET= v+ - O~ RSET RSET 83-0022578 Offset Null Circuit 500 Nano-Watt x 10 Amplifier v+ 3.3 M -1.0 V v83-002258A 8?,-002259A 3-41 NEe JlPC4250 Operating Characteristics TA = 25°C Input Bias Current Input Bias Current .0 1000 30 100 C- C- oS oS ~ 3 V±=±1.5V 10 i;; v± =±1.5 v ISET= 10pA ~ 20 i;; 10 V±=±15V 3 V± ±15V= t t f - - ISET lpA ~1.5V - V± I 0.1 0.1 10 -10 100 -20 20 r--- j15Y V± 60 .0 80 Ambient Temperature (DC) ISET (PA) Input Offset Voltage Input Offset Current 10 1111111 ±1.5V:S;V±:S;±15V 'PA~ISETd'0pA .53. II :!l I 1 - - s ±1.5Y" C C 20 .3. en ~ 10 ...... ...... ...... " V V ±4 ±10 ±12 ±14 II1II' ±1.5V L'2. I ±8 ±6 = ±1.5 v V± iJl g ±2 V± 10 8 ./ !l ;3 ~ ./ 1l. ~ ~ 100 ~ 0.1 10 0.1 ±16 100 ISET (,uA) Supply Current (,uA) Supply Current II Open Loop Voltage Gain 100 t----80 f.-- v± 1011A ISET ±15V ~ f.-- ±1.5V i f.-- 0. .§ l o 100 kO . 10 1l. v± RL v± ±15 v, Yo ±10V ......rI . i-' 10 .".. '::1 J,u' IJJ I ±O.6~ 0 ISET = 1 pA V± = ±15 V V± 0 -20 40 20 60 10' 80 0.1 1.0 Ambient Temperature (OC) Gain Bandwidth Product Slew Rate r- is. 100 k v± ~ .; ~ ~ ~ ±15V .......: ~ 10 k V± RL 10 kO 1.0 ./.~p RL. = 100 kO il 100 10 . ~e 10 ISET (PAl 1M 0- I ./ ±1.5V v± !'" = ±1.5 V ~ ±15V 0.1 v± ±1.5V 0.01 1k 0.1 1.0 10 ISET(JJA) I 100 0.001 0.01 1.0 10 100 ISETWA) 3-43 ~EC pPC4250 Operating Characteristics (Cont.) TA = 25°C Phase Margin RSET 100M II RL= 100kCl 80 ...- 60 ~ - 40 r- 20 o K±=±15V 0.1 i-"'" ~ I V±= 1M 1.0 v± = ±15V 10 .V±.=.±15V 1.5 ........... j ........ 100k ISET (PA) 3-44 ~ I > S ".. /' r-.. ........ 10M I 100 ~ &! 10 k 0.01 0.1 10 Supply Current (IIA) 100 ftiEC pPC358 DUAL LOW-POWER OPERATIONAL AMPLIFIER NEe Electronics Inc. Pin Configuration Description The tJPC358 is designed to operate from a single power supply, with the option to operate from split power supplies. This amplifier offers the circuit designer low power supply current drain, input common mode voltage, and large output voltage swing both of which include ground. Features D Internal frequency compensation D Large output voltage swing: o V to (V+ - 1.5 V) D Input common-mode voltage range includes ground D Wide power supply range: single supply 3 V to 30 V DC D Dual supplies: ±1.5 V to ±15 V DC D LM358 direct replacement J.(PC358C/G2 83-002285A Equivalent Circuit 112 Circuit 8 r-------------------~----~----~----~--~---ov+ 100 llA Cc -Input RSC 1,7 Output 3,5 + Input 0---------+--------+--------' t-------------"---l:"" Q" QlO t-----I----t::: an Q" 50pA 4 '--------+------------------'~-------+-------+-----~'--_o GND IV-J 83-0022848 3-45 II t-IEC JlPC358 Ordering Information Part NumbBr pPC358C PackagB Operating Temperature RangB Plasllc DIP O°C 10 +70°C pPC358G2 Plaslle Minilla! O°C 10 +70°C Absolute Maximum Ratings TA = 25°C Voillge 8e1ween v+ Ind V DiHerenlial Inpul Vollllge InpPl Voillge Power Dissipllion, CPickage Power Dissipllion, G2 Pickage Oulpul Sholl Circuli Durllion Operlling Temperllure Ranga Slorlge TemparllUre Range 32 V 32 V -0.310 +32 V 350 mW 440 mW Indellnl.. 010 +70°C -5510 +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics = 25°C, V± = ±15 V, TA Parameter InpulOH88I Voillge Inpul 811s Currenl InpPl OHael Currenl Common ModelnpPl Volilge Ringe Supply Currenl Voillge Glln Oulpul Voilige Swing Common Mode RelaCiion Ralio Supply Voltege RelaCilon Ralio Channal Separllion Oulpul Currenl (Source) Oulpul Currenl (Sink) 3-46 limits S,mbol Min. T,p. Max. Vio 2 Ib 45 lio Vlem 0 0.7 ICC Unit mV Test Conditions RS:50n 250 nA 50 nA V+ -1.5 V 1.2 mA RL = 00 d8 RL::::: 2 kn V RL:::::2kn AVDL 88 YOM 0 CMRR 65 70 d8 SVRR 65 100 dB 120 db I = 1kHz 10 20 kHz 10 SOURCE 20 40 mA +Inpul = 1 V -Inpul = 0 V 10 20 mA +Inpul = 1 V 12 50 +Inpul = 1 V pA -Iopul = 0 V Vo = 200 mV CS 10 SINK 100 V+ -1.5 -Inpul = 0 V .................................... ~EC jlPC358 Operating Characteristics TA = 25°C Supply Current Input Bias Current 100 75 "~ S 8 - - 50 ~ ! ~ 25 ~===t=~:::r::::~::+~~ !l OL-__~__- L__~__- J_ _ _ _L -_ _~_ _J -_ _~g o 10 20 30 o 40 o 10 --- c ~ ,.... RL "~ §. 60 r--+-.. RL ~ 20 kO .3;; 2 kO 80 % 50 0 E ..:!! g ~ 40 40 r---- r--- ij 00 ~ 10 20 30 40 30 - 20 20 Supply Voltage (V) 100 ~ Open Loop Frequency Response --- i 60 ::; 40 100 ~-"~""",_---t------__j 80t------t--"~~~--__j 60t------t------t---"~~~--,_-----,----_,----_1 0 § E E 80 120 t------t------t------__j 80 f----------+--------+---------~--.~--- 8 1'- 60 40 ,40r-----~----,------r-----------,~0~M~O~-------- a: ~ ----r---- Ambient Temperature (0C) Common Mode Rejection Ratio ~ 11 Current Limiting 0 iii' 40 30 70 120 120 TA:::: +25°C 20 Voltage Gain 160 ",'1'" ~ Supply Voltage (V) Supply Voltage (V) ..~ f' V- 40~----t------t------+-"~~._---T----_T----~ 20 ~---------+----------~--------~--------~~ ~ 1oLo----------1Lk---------1~OLk---------,~00Lk---------,~M~ Frequency (Hz) 10 100 1k 100 k 1M Frequency (Hz) 3-47 fttIEC JlPC358 Operating Characteristics (Cont.) TA = 25°C Voltage Follower Large Signal Pulse Response Large Signal Frequency Response 20 a: 15 ·r t ,g 10 ! U> f V,N \ " '"V 'S ~ V· -'-' 15 V +15V ~~ + +7V t; / ~ 10. 1• 1M 100 k J ~v 2. "-f'.., 5 0 I RL> 2 kO 100 k Frequency (Hz) ru o Current Sinking 10 1\ \ 20 40 30 Time(ps) Current Sourcing 10 ) v+ = 15V :E: J ,g ! 0 1.0 ./V+ 0.1 / 0.01 0.001 V 0.01 ·~'rtt' r + 0.1 1.0 Output Sink Current (rnA) 3-48 10 Vo i ~ @ 100 0 0 .001 1.0 Output Source Current (rnA) 10 100 ttiEC pPC812 DUAL J-FET INPUT LOW-OFFSET OPERATIONAL AMPLIFIER NEe Electronics Inc. PRELIMINARY INFORMATION Description Pin Configuration Dual operational amplifier pPC812 offers high input impedance, low offset voltage, high slew rate, and stable ac operating characteristics. NEC's unique highspeed pnp transistor (IT = 300 MHz) in the output stage solves the oscillation problem of current sinking with a large capacitive load. Zener-zap resistor trimming in the input stage produces excellent offset voltage and temperature drift characteristics. Features o o o o o o o o Stable operation with 10,000pF capacitive load Low input offset voltage: 3 mV max 7 pV;oC temperature drift Low input bias and offset currents Low noise: en = 20 nV/y"Hz Output short-circuit protection High input impedance Internal frequency compensation High slew rate: 15 Vips Equivalent Circuit pPC812C/G2 Ordering Information Part Number IIPC812C IIPC812G2 112 Circuit Package Operating Temperature Range 8·Pin Plastic DIP -2D 10 +70'C 8-Pin Plastic Miniflal -2010 +70'C V+~------~----------~---. Input 1.7 Output Q10 83·001901A 3-49 NEe tJPC812 Absolute Maximum Ratings Electrical Characteristics TA TA = 25°C Parameter Voltage Belween V+ and VPower Dissipation Differential Input Voltage Common Mode Input Voltage (Note 3) Symbol jJPC812C V+-V- 36 36 V Po 350 (Note 11 440 (Nole 2) mW Vid ±30 ±30 V Vi em ±15 ±15 V Indelinite Indefinite Output Short Circuit Duration Operating Temperature Range Storage Temperature Range = 25°C, V± = ±15 V jJPC812G2 Unit Limits Parameter Vio I 3.0 mV Rg = 50 n lio 25 100 pA TJ=25'C Input Bias Current Ib 50 200 pA TJ=25'C dB RL = 2 kn. Vn = ±IO V rnA Both channels AVOL 80 106 -20 to +70 -20 to +70 'C Supply Current Icc Tstg -55 to +125 -55 to +125 'C Common Mode Rejection Ratio CMRR 70 100 dB Supply Voltage Rejection Ratio SVRR 70 100 dB Vom ±12 ±13.5 V RL = 10kn Output Voltage Swing Vom ±IO ±12 V RL = 2 kn Input Voltage Range Viem ±11 V Slew Rate Input Noise Voltage Recommended Operating Conditions Channel Separation Symbol Min. V± ±5 Capacitive Load Output Current Typ. 6.8 Output Voltage Swing rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Supply Voltage Test Conditions Input Offset Current Topt Ratings" may cause permanent damage to the device. This is a stress 3-50 Unit Input Offset Voltage Voltage Gain Note: 1. Thermal derating factor is 5 mW/'C when ambient temperature is higher than 55'C. 2. Thermal derating factor is 4.4 mW/'C when ambient temperature is higher than 25 'C. 3. Forsupply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Parameter Symbol Min. Typ. Max. en 15 V/jJs Av=+1 20 Jill nVI Unity Gain Frequency Rg=IOOn, 1= I kHz MHz CS Max. Unit ±16 V CL 10.000 pF Input Offset Voltage Vio 10 10 rnA Input Offset Voltage Drift t.Viol t.T 120 dB f= I Hzto 20 kHz mV RS=50n. TA = Topt Over Operating Temperature jJV/'C TA=Topt Input Bias Current ib 7 nA TA = Topt Input Offset Current lio 2 nA TA=Topt fttIEC pPC812 Operating Characteristics TA = 25°C Voltage Follower Pulse Response Voltage Follower Pulse Response RL RL=OO CL=O GND J \ I ~ GND \' I ",I 5 VIdlv Vertical Voltage Follower Pulse Response CL = 220 pF ~ I ~ \, .I I = 2,200 pF 5 Vldiv Vertical 2 j.ls/div Horizontal Voltage Follower Pulse Response GND CL \ \ 1 tAs/div Horizontal I = 2,200 pF \ \ . 2 kO CL GND \ \ l I l , I\, \ J ~ 5 VIdlv Vertical 5 V/div Vertical 8 J.ls/div Horizontal 2 #S/div Horizontal Voltage Follower Pulse Response CL = 10,000 pF I GND I. II J ~ , .\. \ I 5 VIdly Vertical 10 ps/div Horizontal 3-51 II tJ PC812 3-52 ttiEC fttIEC NEe Electronics Inc. JlPC814 DUAL J-FET INPUT LOW-OFFSET OPERATIONAL AMPLIFIER PRELIMINARY INFORMATION Description Pin Configuration Dual operational amplifier pPC814 is a high-speed version of the pPC812. NEC's unique high-speed pnp transistor (fT = 300 MHz) in the output stage yields a high slew rate of 25 Vips under voltage-follower conditions without an oscillation problem. Zener-zap resistor trimming in the input stage produces excellent offset voltage and temperature drift characteristics. Having ac performance characteristics that are two times better than conventional bi-FET op amps, the pPC814 is ideal for fast integrators, active filters, and other high-speed circuit applications. Features D High slew rate: 25 Vips D Stable operation with 220-pF capacitive load D Low input offset voltage: -3 mV max -7 pV/oC temperature drift D Low input bias and offset currents D Low noise: en = 20 nV/y'Hz D Output short-circuit protection D High input impedance D Internal frequency compensation jiPC814C 83-001903A Ordering Information Part Number Package !,PC814C 8-Pin Plastic DIP Operating Temperature Range -20 to +70'C Equivalent Circuit (112 Circuit) Tr!mmed R2 4 V-o---~---+----------+---~ 3-53 II ,..,EC pPC814 Absolute Maximum Ratings Electrical Characteristics TA = 25°C TA Voltage Between V+ and V- = 25°C, V± = ±15 V Limits 36 V Power Dissipation Parameter 350mW Symbol Min. Typ. Max. Unit Test Conditions mV RS Differential Input Voltage ±30 V Input Offset Voltage Vio I Common Mode Input Voltage (Note I) ±15 V Input Offset Current liD 25 100 pA Input Bias Current Ib 50 200 pA Output Short Circuit Ouration Indefinite Operating Temperature Range -20 to +70'C Storage Temperature Range AVOl 88 106 d8 Rl = 2 kn, Vo=±IOV rnA Both channels -55 to +125'C Note: 1. Forsupply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damageto the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Recommended Operating Conditions Paramater Voltage Gain Min. Supply Voltage V± ±5 Capacitive load Cl 220 pF Output Current 10 10 rnA Typ. Supply Current ICC Common Mode Rejection Ratio CMRR 70 100 dB Supply Voltage Rejection Ratio SVRR 70 100 dB Output Voltage Swing Vom ±12 ±13.5 V Rl = 10 kn Output Voltage Swing Vom ±IO ±12 V Rl = 2 kn Input Voltage Range Vicm ±11 V Slew Rate Symbol Max. Unit ±16 V = 50 n Input Noise Voltage 6.8 25 Vips Av=+1 en 20 VHZ CS 120 nVI Unity Gain Frequency RS = 100 n, f = I kHz MHz Channel Separation dB f = I Hzto 20 kHz mV RS = 50 n, TA=T opt Over Operating Temperature Input Offset Voltage Input Offset Voltage Orilt pV/'C TA = Topl Input Bias Current Input Offset Current 2 nA TA=T opl nA TA=T opt Operating Characteristics TA = 25°C Voltage Follower Pulse Response Voltage Follower Pulse Response Rl-OCl RL-2kO CL=O CL = 220 pF I I( GND I I \ \ J , - I I GND ,J 1 I l 1\, \ i I 5 V/div Vertical 500 ns/div Horizontal 3-54 .. \ 5 V/div Vertical 500 ns/div Horizontal NEe NEe Electronics Inc. JlPC1458 DUAL GENERAL PURPOSE OPERATIONAL AMPLIFIER Pin Configuration Description The pPC1458 ia a dual general purpose operational amplifier which incorporates internal frequency compensation. This circuit was designed for a wide range of general applications. Large common mode voltage range and latch-free operation make this device ideal for voltage-follower applications where quality and cost are major concerns. Features o o o o o Internal frequency compensation Short-circuit protection Large common mode and differential input voltage No latch-up MC1458 direct replacement pPC1458C/G2 83-002118A Equivalent Circuit 112 Circuit v- 2.6 R, 300 R5 39 k 1.7 Output R" 250 R, 50 k C, 30 pF R, 1k R3 SOk R, R, R12 R11 1k Sk SOk SOk v83-002117C 3-55 II t-IEC pPC1458 Ordering Information Part Number Package Operating Temperatur. Range pPC1458C Plastic DIP DoC to +70°C pPC145882 Plastic Minillat DoC 10 +70°C Electrical Characteristics = 25°C, V± = ±15 V TA Limits Parametar Input Onset Voltage Input OHsat Voltage Drift Absolute Maximum Ratings TA = 25°C Voltage BatweBtl V+ and V- 36 V Power Dissipation. CPackage 350 mW Power Dissipation. 82 Package 440 mW DlHerBtltilllnput Voltage ±30 V Input Voltage (Note I) ±15V Output Short Circuit Duration Indelinl" Operating Temperature Ringe oto HO·C Siorag. TempBrltun Range -55 to + 125·C Note: 1. For supply voltages less than ±15 V,the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 3-56 Symbol Min. Typ. 1.0 Vio Unit 6.0 mV RS:510kO pYrc RS:510kO ll.Vlo'll.T Input OHsat Current lio 20 200 nA Input Bias Current Ib 80 500 nA Large Signal Voltage Gain AVOL 88 104 dB RL2:2kO, VO=±IOV dB 1= 10 Hz, RL =2kO Channel Separation CS 120 Supply Current ICC 3.0 5.6 mA Power Consumption PD 90 170 mW Common Mode Relectlon Ratio CMRR Supply Voltag. Relectlon Ratio SVRR Output Voltage Swing Yom Output Voltage Swing Input Impedance 70 Test Conditions Max. 90 dB RS:510kO dB RS:510kO ±12 ±14 V RL2:10kO Vom ±10 ±13 V RL 2: 2 kO RIN 0.3 89 103 MO !\fEe JlPC1458 Operating Characteristics TA = 25°C Open Loop Frequency Response Large Signal Frequency Response 120 32 TA=25°C 110 TA = 25 c C v± =±15 v r--... 90 iii' :!!. c ~ 8, ~ I' 80 ±15 V RL.2: 10 kO "- 70 60 . 20 ·f ""'- ....... V §. Ii ,/ ae .3" .• ./ 100 V Ii. o - ...- o ,.,... V ./ ./ ±10 Supply Voltage (V) ±20 o o '" V lL" ../ ±10 ±20 Supply Voltage (V) 3-57 ftt{EC JlPC1458 Operating Characteristics (Cont.) TA = 25°C Tcc ~ Oulput Short Circuit Current TA Characteristics V±=±15V V±=±15V - - t-- i-- ....... 0 0 20 -20 40 80 60 20 ~-20 150 \. t--r-+-+--+---t--t---+----j v± = ±15 V i '\. ~ .s 5 a 100 "iii~ 0 1 ; If. 20 40 80 Input Onset Current V± = ±1S v 0 ~'" l"- I 0 -20 -40 -20 20 40 Ambient Temperature COe) 3-58 ........... ......... r--....... -20 20 --- 40 Ambient Temperature COC) 0 0 "'- 50 0 60 Ambient Temperature (0C) o~ 80 V±=±15V " 100 I 20 60 Input Bias Current Power Consumption 200 I 40 Ambient Temperature ("e) Ambient Temperature (OC) 60 80 60 80 NEe NEe Electronics Inc. pPC4062 DUAL J-FET INPUT LOW-POWER OPERATIONAL AMPLIFIER PRELIMINARY INFORMATION Description Pin Configuration ThepPC4062 is a low-power, J-FET input, operational amplifier featuring low supply voltage operation from ±1.75 V. Supply current of pPC4062 is 1/10 the supply current of a pPC4083 op-amp. With very low input bias current characteristics, the pPC4062 is an excellent choice for hand-held measurement equipment and other low-power application circuits. Features D D D D D D D Low supply current: 400 pA Very low input bias and offset currents High slew-rate: 3 Vips High input impedance Low supply voltage operation Output short-circuit protection Internal frequency compensation pPC4062C/G2 83·0Q2118A Equivalent Circuit 112 Circuit y+ R9 R4 Rl 09 R8 017 Q10 Q12 018 RS R7 Cl 013 Rl0 07 06 R2 R3 019 R6 y- 1,7 Output 83-0028206 3-59 II ttiEC jlPC4062 Absolute Maximum Ratings Ordering Information Part Number TA Operating Temperature Range Package /lPC4062C Plastic DIP /lPC4062G2 Plastic Minillat oto +70°C oto +70°C Limits Symbol Min. Typ. Supply Voltage V± Output Current 10 ±1.15 Load Capacitance (Vllltage Follower) Max. Unit ±16 V 5 mA 100 pF 36 V Power Dissipation INote 1). C Package 350 mW Power Dissipation (Note 2). G2 Package 440 mW Dillerentiallnput Voltage ±30 V Input Voltage (Note 3) Recommended Operating Conditions Parameter = 25°C Voltage Between V+ and V- ±15 V Output Short Circuit Duration Indefinite oto +70°C Operating Temperature Range Test Conditions Storage Temperature Range -55 to +125°C Notes: 1. Thermal derating factor is 5 mW/oC for T A> +55°C. 2. Thermal derating factor is 4.4 mW/oC for TA > +25°C. 3. For supply voltages less than +15 V, the absolute maximum input voltage is equal to the supply voltage. Electrical Characteristics TA = 25°C, V± = ±15 V Limits Parameter Symbol Min. Typ. 2 Unit 15 mV 20 mV RS = 50. TA= TOPT /lV/oC RS = 50, TA = TOPT InpUI Onset Voltage Vio Input Onset Voltage Vio IRllut Onset Voltage Mio/AT Input Offset Cu rrent liD 50 pA Input Onset Current liD 1.5 nA Input Bias Current Ib Input Bias Current Ib 10 100 pA 3 nA 500 /lA large Signal Voltage Gain AVOl Supply Current Common Mode Rejection Ratio Icc CMRR 70 95 dB Supply Voltage Rejection Ratio SVRR 70 95 dB Output Voltage Swing Yom ±12 ±14 V +15 V Common Mode Input Voltage Output Current Slew Rate Input Noise Voltage Gilin Bandwidth Products Channel Separation 3-60 69 Viem ±12 10 SR ±5 -13 V rnA 3 RS = 50 dB 75 400 Test Conditions Max. en 30 V//ls nVI y'llZ GBW 1 MHz 120 dB Vom =±10V f = 1 kHz f = 1 to 20 kHz fttfEC pPC4072 DUAL J-FET INPUT LOW-NOISE OPERATIONAL AMPLIFIER NEe Electronics Inc. Pin Configurations Description The J-FET input operational amplifiers of thetJPC4072 are designed as low-noise versions of the tJPC4082. Features of the tJPC4072 include improved input noise voltage, input offset voltage, and input bias current compared to the tJPC4082. These features make the tJPC4072 an excellent choice for a wide variety of applications including audio preamplifier and active filter circuits. Features D D D D D D D Low noise: en = 18 nV/y'HZ Low input bias and offset currents Output short-circuit protection High input impedance Internal frequency compensation High slew rate: 13 V/tJs typical Latch-free operation pPC4072C/G2 83-002275A Ordering Information Pari Number pPC4072C pPC4072G2 pPC4072HA Package Plastic DIP Plastic Minillat Plastic SIP Operallng Temperalure Range Dto +70°C oto +70°C oto +70°C 83-OO2822A 3-61 II t\'EC JlPC4072 Equivalent Circuit 112 Circuit r-----------~----------~----~r_----~------~--------~v+ -Input R, 3,S + Inpul 0-----+----------+----' 1,7 t-.......'VIr--I-------j--------- 40 ~ RI.. == 2 kO t".... ......... 200 100 "" i'.. 20 20 60 40 o 100 80 1 100 10 1k Large Signal Frequency Response " 1M 1 " ~ 20 . ·i "':i' V± - ±10V 15 , > 10 \ V"I. - ±5 V 1k V± = ±15 V RI.. = 10 kO Ii ~ \ 0> 2k 10k Frequency (Hz) 10M g> ./ 20 . ", J)l 0 > , , \ ~ "" 1M 0 ~ ~ 10 V o 2 100 10M / ~ / 1k 300 10k 3k Load Resistance (kO) Output Voltage Swing Voltage Follower Pulse Response 40 . g ~ RI.. - 10 kO ./ 1: 30 ~ / 0> C ~ f 20 > io 10 ,/ ~ ,/ , 3" 0 / '" ±10 Supply Voltage (V} 3-64 ~ 2 30 V± = :!:15 V 100 lOOk ~ r-... Output Voltage Swing 30 o 10k i'.. Frequency (Hz) Ambient Temperature (OC) j .5 i'.. 0> J)l -5 / r-- ~~ Output 1\ \ ±20 Time (Ils) RI.. = 2 kO: CL = 100 pF V±=±15V I "" t-IEC pPC4072 Operating Characteristics (Cont.) TA = 25°C Input Bias Current Input Equivalent Noise Voltage 100 104 ~ 10 ~ V±=±15V RS=1000 ~ V±= ±15 V 103 & ai 1.0 J i V o. 1 . /~ 0.01 -20 ~ / > .~ t ./ 20 102 Z w 40 60 80 I Ambient Temperature ("C) 10 i I 1 ~------~I~OO~------~lk--------~IO~k--------'~OOk 10 Frequency (Hz) II Supply Current 5.0 4.0 / 1 1: 3.0 ~ ~ 8: 2.0 ril 1.0 ~ 0 0 ±5 ±10 ±15 ~ ±20 Supply Vohage (V) 3-65 pPC4072 3-66 NEe NEe NEe Electronics Inc. JlPC4082 DUAL J-FET INPUT OPERATIONAL AMPLIFIER Pin Configuration Description The ,uPC4082 is designed around matched ion implant P-channel J-FET inputs, along with standard bipolar technology. Featuring very low input bias current and ten times the slew rate of general purpose operational amplifiers, this device is well suited for active filters, integrators, and pulse amplifier applications. Features o o o o o o o o Wide common-mode and differential input voltage ranges Low input bias and offset currents Output short-circuit protection High input impedance: J-FET input stage Internal frequency compensation High slew rate: 13 Vips typical Latch- free operation TL082 direct replacement ,uPC4082C/G2 83-002275A Equivalent Circuit 112 Circuit 8V+ 2.6 -Input 0----....- 3,5 + Input 0-----+-------+---' 1.7 +---'VIIV--t---+-+--o Output R, R, C, R, R5 R, L--~--~---~----_+--~---~-~-+__oV- 83-0022748 3-67 II t-IEC JlPC4082 Ordering Information Part Number Package pPC4D82C Plaslic DIP pPC4D82G2 Plaslic Minillat Electrical Characteristics TA = 25°C, V± = ±15 V Operating Temperature Range DOC 10 Limits +7D o C O°C 10 +70°C Absolute Maximum Ratings TA = 25°C Voltaga 8atwaen V+ and V 36 V Powar Dissipation, CPackage 350 mW Power Dissipation INota 1). G2 Package 440 mW Differential Input Voltage Input Voltaga INota 1) ±30 V ±15 V Output Short Circuit Duration Indefinile Oparating Tamperature Range oto +70°C Storaga Tamparature Ranga -55 to +125°C Note: 1. For supply voltages less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Commenl: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Parameter Symbol Min. Typ. Max. Unit 5.0 15.0 mV 200 pA 400 pA Input Offset Voltage Vio Input Offset Currenl lio Input 8ias Current Ib Larga Signal Voltage Gain AVOL 30 88 106 Test Conditions RS:::; 50 d8 RL 2: 2 kO, Vo = ±1O V mA 80th ainpliliers Supply Current ICC Common Mode Rajection Ratio CMRR 70 76 d8 Supply Voltage Rejection Ratio SVRR 70 76 d8 Outpul Voltage Swing Yom ±12 ±13.5 V RL 2: 10 kO Output Voltage Swing Vom ±10 ±12 V Rl 2: 2 kO Common Mode Inpul Voltage Range Vicm ±10 4.0 Slew Rale SR 13 Input Equivalenl Noise Voltage en 25 Unity Gain 8andwidth GBW Channel Separation CS 5.6 Vips Av= 1 $I I = 1 kHz. nVI Hz RS=1000 MHz 120 dB Over Operating Temperature Range Input Offset Voltage Input Offset Voltage Drift 3-68 20 Vio t.Viol t. T Input 8ias Current Ib Input Offset CUrrent 110 10 10 mV RS:::; 50 O. TA = TOPT pV/oC TA = TOPT nA TA = TOPT nA TA = TOPT ftffEC pPC4082 Operating Characteristics TA = 25°C Large Signal Frequency Response Open Loop Frequency Response 120 30 v± = ±15 V RL - 2 kO .. 100 ......... 80 iii .. i'... ~ c " 60 0 E ;g 40 "'" ~ ......... 20 100 10 10. 1• f\ ~ ~ 100 k 10 0 i'... Frequency (Hz) "''" 1M 100 1• Frequency (Hz) 30 ~ 10 ,/ o /' /' / / V .. /' ~ 20 .'"• c "' f ~ 10 0 i ~ ~ o I 10 M II Output Voltage Swing V± = ±15 V ~ f 1 '" 30 RL = 10 kO 20 ~ 1M 100 k 10. Output Voltage Swing ·r"' \. "\ V±= ±5V o 10M 40 .. \ V±=±10Y 8, ,!l o 1 20 ·r"' '""' RL=10kO: V±=±1SV ±10 ±20 V o V / 100 ./ V-- 3. 1• 300 .....- Supply Voltage (V) Load Resistance (kO) Input Bias Current Voltage Follower Pulse Response - 10 100 V±=±15V / 10 1 ~ U 1.0 V ~ iii ! 0.1 ~ 0.01 -20 - ./ V 20 -5 V >- Output ~ ", Rl = 2 kO: Cl=100pF V±=±15V /" 40 Ambient Temperature (0C) 60 80 Time (ps) 3-69 ftt{EC pPC4082 Operating Characteristics (Cont.) TA = 25°C Input Equivalent Noise Voltage Supply Current 10' 5.0 V±=±15V Rs=1000 4.0 / C So 3.0 1 r----r--- ~ ~ 2.0 1.0 ~ ij 1 0 10 100 1k Frequency (Hz) 3-70 10 k 100 0 ±5 ±10 Supply Voltage (V) ±15 ±20 pPC4359 DUAL HIGH-SPEED PROGRAMMABLE CURRENT MODE OPERATIONAL AMPLIFIER ~EC NEe Electronics Inc. Pin Configuration Description The pPC4359 consists of two current differencing input amplifiers. Design emphasis has been placed on obtaining high frequency performance while providing user programmability. Each amplifier provides high gain-bandwidth product, high slew rate, and stable inverting operation in closed loop designs with a gain of ten or greater. Features D User programmable gain bandwidth product, slew rate, input bias current, output stage current D High gain bandwidth product: 300 MHz for Av = 10 to 100 30 MHz for Av = 1 D High slew rate: 60 VIps for Av = 10 to 100 30 VIps for Av = 1 D Operates from a single 5 V to 22 V supply D Current differencing inputs allow high common-mode input voltages D LM359 direct replacement pPC4359C 83-002096A Ordering Information Number Package Operating Temperature Range pPC4359C Plastic DIP DOC to +70°C Part Equivalent Circuit 112 Circuit 12 r---~--------------~------~--~--------~------ov+ 3 Compo---------+ ISET 6,10 -Input o---------~_r:: ~----------+-----+----+------o Output 7,9 +Input O---t---..., 4,11 L-----~~~~__~__~____~~--~----------~--__~__~----__oGND 83-00209SA 3-71 II NEe pPC4359 Absolute Maximum Ratings TA = 25°C 22 V 20 rnA Supply Voltage Hange v+ Input Current 11M 2mA 570mW oto +70°C Set Current ISEl Power Dissipation Po Operating Temperature Hange. Topt Storage Temperature Hange. Tstg -55 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA = 25°C. ISET = 0.5 rnA, V± = ±12 V Umlts Parameter Tesl Symbol Min. Typ. AVOL 62 15 200 70 30 300 30 60 80 1.0 1.0 1.0 1.1 1.1 1.1 pA/pA pA/pA ISEl - 5pA ISEl: 5pA +Inputs = 2 rnA +Inputs = 0.2 mA Isn: 5pA +Inputs = 20 mA 3.0 5.0 % Isn: 5pA +Inputa : 20 rnA to 0.2 mA Input Bias Current 5.3 30 15 pA pA -Inputa -Inputa Input Hesistance 2.5 kO -Inputs 3.5 10.3 0.002 65 4.7 4.5 17 48 0 10: 15. mArml• f = 1 MHz HL : 600 O. all inputs grounded Open Loop Voltage Gain Gain Bandwidth GBW Slew Hate SH Channel Separation CS Mirror Gain Mirror Gain Output Resistance High Level Output Voltage Low Level Output Voltage Output Source Current -Input +Input {-Input) "\+Input HO 9.5 ISOURCE Output Sink Current ISINK Supply Current ICC SVRH Supply Voltage Hejection Ratio 3-72 0.9 0.9 0.9 16 1.5 40 Max. Unll dB f=I00Hz.HL=1 kO MHz MHz HIM = 1 kO. CCOMP = 10 pF. AV = 1 HIM = 50 to 200 o. AV = 10 to 100 HIM: 1 kO. CCOMp: 10 pF. AV: 1 VIpS VIpS 0.05 dB pA/pA V V rnA mA 22 Conditions rnA dB HIM :s200 0 f: 100 Hz to 100 kHz. HL : 1 kO TA: 25°C TA: TOPT TA: TOPT TA = 25°C TA = TOPT HL : 600 O. -Inputs = 100 pA. +inputa grounded HL = 100 O. all inputs grounded Vo = 1 V. VCOMP : 0.5 V. +Inputs grounded Vo = 1 V. -Inputs = 100 pA. +inputs grounded HL : 00. +Inputs grounded f : 120 Hz. +inputa grounded ~EC JlPC4359 Operating Characteristics TA = 25°C Open Loop Gain Open Loop Frequency Response 100 0 T~~ J~.I~" 90 ISET= a.SmA 'I 10 kHz = ISET= 0.5 mA V+=+12V 80 RF=5kO r.. V -~ L 0 "" 20 I 10 o 100 1k 10k 100k 1M 0 100M 10M Gain Bandwidth Products II Slew Rate 100 t--- I---- i i!- ~ 20 Supply Voltage M 1000 ..t I 15 10 Frequency (Hz) TA 25°C Av=100 fo = 10 MHz TA 25°C Av- 1O RI=50n I" !:NO=2V L..-- I' ./ 100 L. .- 10- ·Ii ] ~ ~ V I / 10 0.1 0.01 /" ~ 1 0.01 1.0 Phase Gain and Phase Feedback Gain = -10 TA - 25°C ISET=O.5 rnA V+ = +12 V All = 100 RF=5kO r--... .......... 80 iii" :2c ~ ....... ! ~ o ........... 60 40 ........... .... ill 180 .Ill 150 90 in :E. 30 60 ~ I CF= 1 pF 10M 0. ! Frequency (Hz) <~ ~ ~ 20 10 100 k, ~ = 25°C C'"l°rl ISET::; 0.5 mA Vi =+12V All = 10 R'=5t 1.0M V C'=2~F/V TA r- C,-OpF/ C'=0.5~F,..1::::: 120 30 Gain 20 1.0 Set Current (mA) Gain and Phase Feedback Gain = -100 I ~ 0.1 Set Current (rnA) 0.1 M CF = 0.5 pF Ic,l,~~ I II 1 /~ ~ Gain CF=2pF 1.0M 10M J 180 150 120 90 60 30 I 100M Frequency (Hz) 3-73 t-IEC /1PC4359 Operating Characteristics (Cont.) TA = 25°C Mirror Gain Inverting Input Bias Current 2 I I liN ;=GND ISET 0 v+ = 0.5 rnA +12 V 1.00 .-t-- ...... t--.... 8 --- I-.. '" 0.90 TA -v _ISET 0.80 -20 +40 +20 t60 +80 ·-25°C t12 V 5"A I 0.1 1.0 10 Mirror Current - Temperature (OC) (rnA) Supply Rejection Mirror Gain 0 1.00 "~ 21"A IIN- 200IJA 50 0 0.90 0 I- ~A f-- Isr '-25°C ·12 V S(A 0.8 0 20 ·20 ..-40 ... ·60 Temperature (0C) I TA 10 e-V' "j=mllill I 0 100 Channel Separation (Amp1 - Amp 2) ,. iii' 5 v 0.5 rnA 0 1 Av2 100 RL2 "" 25°~ I I III t-25°C = TA = V± = ±12 V RL -:::: 100 kO II 0 "'\ RK = 1 kO RL1 \ \ 5 \ 1500 0 \ 111111 10 0 12 0 r.. I'. 60 ~ a 1M 100 k Output Swing " I 10 k 1k Frequency (Hz) 0 TA VIN-<-0 1-+++l+I-l+t--+++-+++lH-H-+l+l+l+----++-l-l++l ISET AVl t-25°C +12 Voc -;-" 1 Vp_p " , f\. '- i""- I- 0 100 1k 10 k 100 k Frequency (Hz) 3-74 1M 10 100 k 1M Frequency (Hz) 10 t\'EC JlPC4359 Operating Characteristics (Cont.) TA = 25°C Supply Current Supply Current 100 i----- 30 :;; .s - 10 ~ /'v----'f VOIDC) AVIAC) = RF/(Rs AVIAC) = RF/Rs VOIDC) = VBE + RF [v+ - VBE Rs 'E = 0.026111+ (ill+) + ISH] VOIDC) 83-002112A Inverting AC Amplifier (Self Biasing) V+ eo VOIDC) AVIAC) VOIDC) = RF/(Rs + rEI = VBE (1 .~ RF) 'E: Emilie, Resistance of 01 ISI)'RF Rs 83-002114A 3-76 + 'E) = VSE (1 'E: Emilie, Resistance of 01 = 0.2 mA, 'E = 130 0) RF + Rs) + lSI ).RF 83-002113A ~EC pPC4359 Typical Applications (Cont.) Video Line Driver Application +12V t---------~~----------i RF 7.5 k + 6 20 k 100/lF 2 + eOut Coaxial II r_-- R2/R4 - 2R4' 5 MHz 83-002291 A Electrical Characteristics TA = 25°C. V± = ±15 V Limits Parameter Symbot Input Offset Vollage ViO Input Offset Current liD Input Bias Current Ib Vollage Gain Power Dissipation Min. Typ. 0.5 Max. Unit Test Conditions 6.0 mV 200 nA 180 500 nA AVOL 100 86 d8 RL PD 90 170 mW Both channals dB RSS10kO 103 dB RS S 10 kO RSS 10 kO ~ 2 kO. Vo Common Mode Rejection Ratio CMRR Supply Vollage Rejection Ratio SVRR Output Vollage Swing YOM ±12 ±14 V RL Output Vollage Swing YOM ±1O ±11.5 V 10 = ±25 mA Common Mode Input Voltage Range Vicm ±12 ±14 V 5 VIlls Slew Rate SR Input Noise Voltage en Channel Separation CS 3-80 70 90 89 IlV,P-P 105 dB ~ = ±10 V 2 kO Av ~ 10 [20 dBI Rs=1 kn.f=1 Hztol kHz f = I kHz ttlEC pPC4556 Operating Characteristics TA = 25°C Open Loop Frequency Response Large Signal Frequency Response 120 V± 100 ~e 80 " g'" 60 " " "-""- 40 20 1 10 100 v' ±15 V 9. ::t15 V I 24 -;; ~ 20 ~. " "-i'.. "- 10 k 1k _co 32 28 ~ 0 o -= 100 k '" ~ 16 il .g "- ~ 12 ~ 1M \ 100 10 M 10 k 1k 1M 100 k Frequency (Hz) Frequency (Hz) Output Voltage Swing Input Bias Current 20,---------,---------,---------,---------, V+' = ±15V -----. V±=±15V 200 1 160 ~ 120 0 iD 80 0. e < 40 ~ 9@ 40 60 80 20 Output Current (rnA) 40 60 80 Ambient Temperature (0C) Common Mode Input Voltage Range Supply Current 20 . i. ~ r ~ 10 ....-f-- ,W ~ ............. o I o ±10 Supply Voltage (V) -20 ±20 o V ....-V ~ r- ........... - r-.. ............. r-. ±10 Supply Voltage (V) 3-81 ftt{EC JlPC4556 Operating Characteristics (Cont.) TA = 25°C Input Noise Voltage Pulse Response 10 1000 V± = ±15 V \ \ "-5 20 Time {tLs) 3-82 300 ~8, 100 ~ ~ "0 Z 30 10 -10 10 ~ 30 40 1 ~ "( ~ "--- 10 ~ 2 100 Frequency (Hz) 1k ttlEC pPC4557 DUAL HIGH·PERFORMANCE OPERATIONAL AMPLIFIER NEe Electronics Inc. Pin Configuration Description The pPC4557 is a dual operational amplifier which features higher output drive current than that of the pPC4558. This feature allows driving of headphone speakers directly. Other characteristics of this device are low noise and no crossover distortion, which make it the ideal choice for audio applications. Features D Internal frequency compensation D Large common-mode and differential input voltage ranges D No latch-up D Low noise II Ordering Information Number Package pPC4557C Plastic DIP pPC4557C Oparatlng Temperature Range Part 83-002298A Equivalent Circuit 112 Circuit 8 v+o---------~--------~----------~--~------~--_. Os~--------~------~~---1--~1( 1,7 ~~~-r-----r----+--oOu~t Rs t--; I---t--~--_,._---+----C 012 +---;::: 0,. C, R, R. R, D 4 v-o-----~--~--~----~------~------_+------+_----~--~ 83-0021568 3-83 ttlEC pPC4557 Absolute Maximum Ratings Electrical Characteristics TA = 25°C TA = 25°C, V± = ±15 V Voltage Batwlln V+ and V- 36 V Power Diaalpatlon (Nota II Limits 700mW Parameter DlHerential tnput Voltage ±30V Input Vottage (Note 21 ±15V InpulOHsel Voltaga Output Short Circuit Duration 5s Operating Temperatura Ringe oto +70°C Storage Temperature Ranga -55 to +125°C Notes: 1. When the ambient temperature is more than 25°C, derate linearly at 7 mW/oC, (TJmax) = 125°). 2. Forsupply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device a!lhese or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Noise Measurement Circuit 100 k +15 V 1k CRT >---'-OVo 50 n 1k -15V InpulOHsal Current Symbol Min. Typ. liD Input Bias Currant Lallla Signal Vollage Gain AVOL Power DiS8ipation Po 86 Max. Unit 0.5 6.0 mV 5 200 nA 180 500 nA 100 90 170 RL <': 2 kO, VO=±IOV mW 80lh channels d8 RS:5 10 kO pV/V RS:5 10 kO Supply Voltaga Relaction Ratio SVRR Oulput Voltage Swing Yom ±12 ±14 V RL<':2kO Output Voltaga Swing Yom ±IO ±11.5 V 10=±25mA Common Mode Inpul Voltage Ranga Vlcm ±12 ±14 V Slaw Rate SR Input Noisa Voltage en Channel Separation CS 70 90 30 150 1.0 105 Channel Separation =20 log ( -1 - .V02 - ) 1000 VOt Vips Av = I pVp_p RS=lkO. f I Hz to 1 kHz dB to k 50 k 3-84 dB CMRR Channel Separation Measurement Circuit n RS:510kO Common Mode Rejactlon Ratio 83-002172A 50 Test Conditions = f=lkHz t\'EC pPC4557 Operating Characteristics TA = 25°C Large Signal Frequency Response Open Loop Frequency Response 120 36 V±=±15V v± = ±15 V 100 m 80 . 60 !< 40 "- ·i "" ~ :: ""- l!- ",g:'" . ! "- "'-""- 20 o 32 1 10 100 1k 10 k f> ~ '\ \ \ \ 20 16 i 12 0 "- " o 10 1M 100 k Frequency (Hz) 100 \ 10k 1k '-....... ............ 1M 100 k Frequency (Hz) Output Voltage Swing II Input Bias Current 20r----------,---------,----------,----------, V± 120 v± = = ±15 V 100 ! 80 u 60 I ±15 V "--r-- r6 ! 40 ~ L -_ _ _ _ _ _ ~ 20 ______ ~ ________ 40 ~ 60 ______ 20 ~ ~g o 80 -20 20 40 60 80 Ambient Temperature (OC) Output Current (mA) Common Mode Input Voltage Range Supply Current 20 . :E go &! r 10 i ~ !< . V I--- ....-v -'" V ;; ~ 1l "'-. :Ii 1 -10 ~ o J o ±10 Supply Voltage (V) ~ ±20 -20 o r-- r- -- "'-. r-.. "'-. 10 Supply VoHage (V) 3-85 ftt{EC JlPC4557 Operating Characteristics (Cont.) TA = 25°C Input Noise Vollage Density Voltage Follower Large Signal Pulse Response 1000 10 V±=±15V / V \ ~ 300 ~ \ ~ ~ ·z1 I 100 30 10 ~ " ~ I---- 10 100 Frequency (Hz) d 8 0 Head Phone 1000 2.5 ~W typical maxImum power Note: NEe cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement. Input Output dBm VRMS mW +6 1.55 2.0 0 0.775 0.5 -6 0.388 0.125 83-0023036 3-86 ~EC JiPC4558 DUAL HIGH·PERFORMANCE OPERATIONAL AMPLIFIER NEe Electronics Inc. Pin Configuration Description The tJPC4558 is a dual operational amplifier with internal frequency compensation. Using low noise lateral PNP input transistors on the amplifier inputs allows the use of this device for signal processing applications, such as low-noise audio preamplifiers and signal conditioning circuits. The simplified output stage eliminates crossover distortion under any normal load conditions. Features D D D D D D Internal frequency compensation Short-circuit protection Large common mode and differential voltage range No latch-up Low noise RC4558 direct replacement tJ PC4558C/G2 83-002157A Equivalent Circuit 112 Circuit 8 v+o---------~--------~--------~~--~------~--_. R, 05~------~--------~~---+--~~ R, 1.7 t--'V\tv---+------j-----t--oOutput R, -:- Inputo-----+-------~---' I-+--~~~~----t:" 012 R, 4 V-o-----~--~--_+----_+------~------~----~~--~~--~ 83-0021568 3-87 II NEe JlPC4558 Electrical Characteristics Ordering Information TA Operating Temperature Range Part Number Package /lPC4558C Plastic DIP /lPC4558G2 Plastic Miniflat = 25°C, V± = ±15 V Limits Parameter Symbol Min. Typ. Max. Input Offset Voltage Vio Input Offset Current lio Absolute Maximum Ratings Input Bias Current Ib TA = 25°C Large Signal Voltage Gain AVOL Po Voltage Between V+ and V- 0.5 60 6.0 mV 200 nA 500 nA B6 350mW Power Consumption Power Dissipation, G2 Package 440mW Common Mode Rejection Ratio CMRR Supply Voltage Rejection Ratio SVRR Output Voltage Swing Yom Differential Input Voltage ±30 V Input Voltage (Note I) ±15 V Output Short Circuit Duration Indefinite Operating Temperature Range, C or G2 Package Storage Temperature Range, C or G2 Package 90 70 Note: 1. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Vicm Slew Rate SR Input Noise Voltage en Channel Separation CS 90 30 -55 to +125°C Common Mode Input Voltage Range 170 150 Rs 0:: 10 kO dB RL? 2 kO, Vo=±lOV mW Both channels (see note) dB Rs 0:: 10 kO 36 V Power Dissipation. C Package Test Conditions Unit /lV/V Rs 0:: 10 kO ±12 ±14 V RsO::IOkO ±10 ±13 V RS 0::2 kO ±12 ±14 V V//ls Av= 1 1.0 Rs =lkO, /lVp.p f = I Hz to I kHz 105 dB f= I kHz Note: The total of internal power dissipation. Channel Separation Measurement Circuit Noise Measurement Circuit 50 k 100 k 500 +15 V 1I2/lPC4558C/G2 1k CRT >---4-0Vo Channel Separation 1/2/lPC4558C/G2 500 10 k = 20 log (_1_ • Vo, V02) 1000 1k Noise _ Vo Voltage - 2000 -15 V 83-002172A 3-88 83-002173A t-IEC pPC4558 Operating Characteristics TA=25°C Large Signal Frequency Response Open Loop Frequency Response 120 36 V± = ±15V V±~±15V 100 "- "- 80 Iii' i "\ "- ~ ~ ::. 60 40 '""- 20 o 32 1 10 100 10k 1k 1 \ " " 100k Frequency (Hz) 1M f'...... ~ ~ o 10M 100 ! 1M 11 120 2S V±=±15V ~~ V±~±15V 100 /' ~ I 100k '" Input Bias Current Output Voltage Swing OJ 10k 1k ~ Frequency (Hz) 30 ·r. f , \ 20 (l 60 '-- - .,,; ,/ 10 80 i V IS ~ I ~ 5 100 1k Load _ 40 20 ~ o 10k ...nco (Q) -20 40 20 60 80 Ambktnt Temperature (Oe) Common Mode Input Voltage Range Supply Cunent 0 ~ 1 u 2 ~--1----r---+--~----~--+---1----r---+--~ J ~ O~~~~__~__-L__~__L-~__~__-L__~~ ±10 I 0 j i lr---+---+---1---~--~--~--~---r--~----1 Supply Voltage (V) 0 I 1 o i ±20 8 -1 0 -20 V V l.--' r-.. t--. t-... V -- l.--' J...-' ........ t--. r--.... 10 t--. ~ ! 20 Supply VoltaGe (VI 3-89 ttiEC pPC4558 Operating Characteristics (Cont.) TA = 25°C Input Noise Voltage Density Voltage Follower Large Signal Pulse Response 10 1000 V± = ±15V / V \ ¥ 300 . \ ? i ~ 100 ~ 1\ .~ z ..~ 30 ~ "-. 10 ---- 10 100 Frequency (Hz) 100pF Input >----4--li:j--t-OOutput o--"IW-;;::I-,....-+--I 2.2 kO 10 k AIAA Preamp Au = 32.5 dB Distortion 0.03% (Vo = 1 YRMS. f = 1 kHz Noise 1.0pVRMS (Input EQUIV, Input EaUIV Short Peak Del. Average Indication) Vo - Distortion Characteristics 10r-------,--------r-------, V±=±15V TA= +25°C .= RL= 10kO: 1 kHz 1 . 0 1 - - - - - - - - - - 1 1 - - - - - - - t - - - - - -..... l I 0.11----------1po....,------t---------,H 0.01'-----_ _-'-_ _ _ _ _ _-'-_ _ _ _ _ _- ' 0.01 0.1 1.0 Output Voltage (YRMS) 3-90 10 83·0021668 NEe jiPC4558 Peak Level Meter This circuit converts the peak voltage (about ±10 mV to ±10 V) of the input signal to a DC voltage (about 0.2 V to 1.3 V) and drives the meter. Since the output voltage is proportional to the logarithmic value of the peak voltage of the input signal, indication of a much wider dynamic range can be obtained compared to conventional linear indicating methods. Peak Level Meter 1$953 30 k 100 k 30 k 30 k 15 k 1$953 20 k II 51 k -40 dB ~ (0 dB -r5 dB = 1 Vp) 3.3 J1F lOOk 30 k 30 k 15 V Log Compression Note: 200 k 15 V Full Wave Rectification 10 k -15 V l' 20 k Peak Hold Meter AMP NEe cannot assume any responsibility for any circuits shown or represent that they are free from patent infringements. 83-0021708 3-91 pPC4558 3-92 ttlEC NEe NEe Electronics Inc. J.lPC4559 DUAL HIGH·PERFORMANCE OPERATIONAL AMPLIFIER Description Pin Configuration The pPC4559 is a dual operational amplifier featuring improved slew rate and gain bandwidth product when compared to the pPC4558. With low noise and internal frequency compensation, this device is a good choice for active filter designs and audio applications. Features o o o o o o Internal frequency compensation Large common mode and differential input voltage ranges No latch up Low noise Output short-circuit protection RS4559 direct replacement ~PC4559C Ordering Information 83-002304A Part Number Package Operating Temperature Range /lPC4559C Plastic DIP 0° 10 +70°C EquivGlent Circuit 112 Circuit • ~O---------~--------~----------~--~------~---. ., o,~------~--------~~---+--~~ 015 •• o. 1,7 . •• ~_'V\IV_-+----_+----+___oOutpul 3,5 + Inpulo-----+--------+-----' ., , +--il---t--~---..,...---+---i: 012 .2 c, ., ., 4 V-o-----~--~--_+----_+---- •• o __~------~----__~--~~-----' 63-0021568 3-93 II NEe pPC4559 Electrical Characteristics Absolute Maximum Ratings TA = 25°C, V± = ±15 V TA = 25°C Voltage Between V+ and VPower Dissipation Differential Input Voltage Limits 36 V 350mW ±30V ±15V Indefinite Input Voltage (Note II Output Short Circuit Duration Operating Temperature Range Storage Temperature Range oto +70°C -55 to +125°C Paramalar Symbol Min. Typ. Vlo 0.5 6.0 mV Input Ollsat Current 110 5 200 nA Input BI.s Currant Ib 60 500 nA Large Signal Vollage Glln AVOL Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. POWIr Consumption Po 100 k +15 V 1k CRT >-4-0Vo 1k Noise Vo Voltage = 2000 -15V 83-002172A Channel Separation Measurement C;'cuit 50 k 50 Q Channel Separation 10 k = 20 log V02) 1 ( 1000· V01 B3-Q02173A 3-94 Unit Input DHaIl Voltlge Note: 1. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Noise Measurement Circuit Max. Common Modi Relectlon Ratio CMRR Supply Vollagl Relectlon Rllio SVRR Output Vollage Swlng Yom Output Voltaga Swing Common Mode Input Voltlge Range 86 100 90 70 dB 170 90 Tast Conditions RS:510kn RL:2::2kn. VO=±IOV mW dB RS:510kn dB RS:510kn ±12 ±14 V RS:2:: 10kn Yom ±IO ±13 V RS:2:: 2 kn Vlcm ±12 ±14 V Slew Rill SR 2.0 VlpI Av= I Input Noise Voltage an 6 pVp_p RS = !kn, f= I Hz to I kHz Channel Separellon CS 105 dB 89 103 f= I kHz ttlEC pPC4559 Operating Characteristics TA = 25 C C Large Signal Frequency Response Open Loop Frequency Response 32 "0 V±=±15V V±=±15V 100 iE "- 80 ~ 60 ~ 40 "- 'Q, """- "- :!!. f -t 1 100 10 1k \ 24 1 20 16 • f ""- '0 o 2. 10 k """- I'-. " 100 k 1M \ > 12 '5 ! \.. 8 ~ o 10 100 Frequency (Hz) ~ •• f& .0 ~ I. V l!! I 10 I V± = ±15V 100 / l 60 U 60 I "--r-- i / 5 100 II Input Bias Current 120 ,.---- V±=±15V 1M Frequency (Hz) Output Voltage Swing 30 .......... 100 k 10 k 1k i ~ 1k 40 20 ~ o 10k .0 -20 40 60 Ambient Temperature (OC) Load Resistance (0) Common Mode Input Voltage Range Supply Current 20 ~ j r 10 & V l!! ~ 1 i::Ii ~ o o . ~ E 1 ±10 Supply Voltage (V) ~ ±.o r...... """- -10 u -20 ,-....- o ........V ~ V --- ......... r......... """-r......... 10 Supply Voltage (V) 3-95 t-IEC J.lPC4559 Operating Characteristics (Cont.) TA = 25°C Input Noise Voltage Density Voltage Follower Pulse Response 1000 10 Y±=±15V Ie j :!il 0 I -5 \ / / 20 3-96 ~ 100 z= '[ 15 30 30 .5 -10 Time""') 300 :si!. \ 10 ~ 40 I 10 ~ ~ "- ---- 10 Frequency (Hz) 100 ,..,EC J1PC4560 DUAL HIGH-PERFORMANCE OPERATIONAL AMPLIFIER NEe Electronics Inc. Description Pin Configuration The jiPC4560 is a dual operational amplifier with improved slew rate and gain-bandwidth product when compared to the jiPC4559 with unity gain frequency compensation. Low input noise and high output current drive capability makes this device ideal for audio applications and active filters. Features o o o o o Internal frequency compensation Large common mode and differential voltage range No latch-up Gain-bandwidth products: 10 MHz typical Low input noise voltage: 6 jiV p _p typical pPC4560C/G2 Ordering Information 83-002171A Pari Number Package Operating Temperature Range IlPC4560C Plastic DIP 0' to +70'C Plastic Minillat 0' to +70'C Electrical Characteristics TA = 25°C. V± = ±15 V Limit Parameter Absolute Maximum Ratings TA = 25°C Voltage Between V+ and V- 36 V Power Dissipation INote I). CPackage 700 mW Power Oissipation INote I). G2 Package 440 mW Dillerential Input Voltage ±30 V Input Voltage INote 2) OV Output Short Circuit Duration Os Operating Temperature Range oto +70'C Storage Temperature Range -55 to +125'C Note: 1. When the ambient temperature is more than 25'C. derate linearly at 7 mW/'C (TJMAX = 125'C). 2. For supply voltages less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Symbol Test Min. Typ. Max. Unit Conditions Input Offset Voltage Vio 0.5 6.0 mV Rs oS 10 kn Input Offset Current liD 5 200 nA Input Bias Current Ib 60 500 nA Large Signal Voltage Gain AVOL Power Consumption Po Common Mode Rejection Ratio CMRR Supply Voltage Rejection Ratio SVRR Output Voltage Swing Common Mode Voltage Range Yom Vicm 88 105 120 70 dB 170 100 89 RL 2: 2 kn. Vo=±IOV mW 80th channels dB Rs oS 10 kn 103 d8 RsoS 10 kn ±12 ±14 V Rs 2: 2 kn ±IO ±13 V 10 = ±25 rnA ±12 ±14 V Slew Rate SR 2.8 Input Noise Voltage en 6 IlVp.p Rs = I kn. I = I Hz to 1 i I'v--I-----I----40---o Output Rs +Input 0-----+---------1----' +--lI----I--'--_1--+--r Q12 c, c, R, R, R. D V-o---~--+--~---~--_'--------~----~--4--~ 83"'()()2170B Noise Measurement Circuit Channel Separation Measurement Circuit 50 k 100 k >---oV02 son +15V 1k CRT Channel Separation > .....--OVo 1/2pPC4560C/G2 son 10 k V02) 1 = 20 log ( 1000· V01 1k Noise _ Vo Voltage - 2000 -15V 63-002172A 3-98 aa-002173A ~EC pPC4560 Operating Characteristics TA = 25°C Large Signal Frequency Response Open Loop Frequency Response 120 V±= ±15Y V± = ±15V 100 '"'" 80 it ~ .. 60 ~ 40 ~ J!! 20 o 1 10 100 "i: 28 t ·r '"'\ \ \ 24 , .. 20 '" 10k 1k 32 ~, , "- 100k Frequency (Hz) I" ;; ~ " I " 1M 12 o 10M i\. "" < .......... 100 10k 1k 100k Frequency (Hz) Output Voltage Swing ! 1M II Input Bias Current 20 V± = ±15V V±=±15V -a 15 /I+vol -t f f • --....... l-voll 10 100 1 j -............. 60 r--- j J J 80 40 20 20 40 60 o 80 -20 40 20 80 80 Ambient Temperature (DC) Load R.alstance (kO) Common Mode Input Voltage Range Supply Current 20 1 4 1! i u i JI 3 ",.... f i --- ....- r--. ........... .......... i 2 V -10 u -20 ±10 Supply Voltage M ±20 o ......... V ,-V r-.... ........... r-..... 10 Supply Voltage M 3-99 fttIEC pPC4560 Operetlng Characteristics (Cont.) TA = 25°C Pulse Response Input Noise Voltage Density 10 V± = ±15V Av=1 / ~> .!;. \ \ II -5 100 f I 30 10 .!l z° < ~ . ! .5 ij \ Rs=1oon '"'" 61=1 Hz ..... lil -10 10 20 30 40 10 nme~) 100 1k Frequency (Hz) Application Circuit Head Phone Amp +20 V 51 k c. + 10k 10p V,N o---tr--1~-r---i d 8 n Head Phone 2.5 mW typical maximum power Nole: NEe cannot ...ume any responllbility 'or any clrcults'hown or representtha' Input they are free from patenllnfrlngement. dBm Output VRMS mW +8 1.55 0 -8 0.77. 0.5 0.388 0.125 2.0 83-00230lB 3-100 ~EC pPC4560 Application Circuit (Cont.) C3 0.0022 pF C4 0.01 pF +15 V Cs 100,uF Input 0--'Mr--f:::r"'---+---i >---......--~-~Output 2.2 k R' R6 '0 k 83-0021818 II Distortion Characteristics O.OO~.L.,:--------::lO.:-'-------:':':.0:-------7.,. Output Voltage (VRMS) 3-101 pPC4560 3-102 NEe NEe NEe Electronics Inc. jJPC4570 DUAL ULTRA LOW-NOISE, WIDEBAND, OPERATIONAL AMPLIFIER Description Pin Configurations The tJPC4570 is an ultralow-noise, wideband, high slew-rate, dual operatio. ,al amplifier. Input equivalent noise is three times better than the conventional 4558 type op-amp. The gain bandwidth product and the slew-rate are seven times better than 4558. In spite of fast ac performance, the tJPC4570 is extremely stable under voltage-follower circuit conditions. Supply current is also im~. oved compared with conventional wideband op-amps. ThetJPC4570 is an excellent choice for pre-amplifiers and active filters in audio, instrumentation, and communication circuits. Features o o o o o Ultralow noise: en = 4.5 nV/y'Hz High slew-rate: 7 V/tJs Wide bandwidth: GBW = 15 MHz at 100 kHz Internal full-frequency compensation NE5532 equivalent pPC4570C/G2 83-002275A Ordering Information Part Number pPC4570C pPC4570G2 pPC4570HA Package Operating Temperature Range Plastic DIP Plastic Minillal Plastic SIP -2010 +70'C -2010 +70'C -2010 +70'C 83-002B22A 3-103 IJ fttIEC pPC4570 Equivalent Circuit 112 Circuit 1 9 I v+ I I I I v "-« '" ".... v ~ ~ h 3,7 Input 4,6 +1 nput ~ ::} L.M' "- I I I I I I - I I I I I I 2,8 I II ::-l , ...... V V V- ....... - '" I ....... ,....., I I I I :: 5 I V- ....... O~ ut I ~ I I I ~ v83-002821B 3-104 fttIEC pPC4570 Absolute Maximum Ratings Electrical Characteristics TA TA = 25°C Voltage Between V+ and VDifferential Input Voltage = 25°C, V± = ±15 V Limits 36 V ±30 V Parameter Symbol Min. Typ. Max. Unit Power Dissipation. Cand HA Packages (Note I) 350 mW Input offset voltage Vlo 0.3 5 mV Power Dissipation. G2 Package (Note 2) 440mW Input offset current lio 10 200 nA Input bias current Ib 500 1000 nA liD dB Input Voltage (Note 3) ±15 V Output Short Circuit Duration 10 s Operating Temperature Range -20 to +70°C Test Conditions Rs = 50 Q Large signal voltage gain AVOL Supply current Icc Notes: 1. Thermal derating factor is 5 mW/oC when ambient temperature is higher than 55°C. Common mode rejection ratio CMRR 00 100 dB 2. Thermal derating factor is 4.4 mW/oC when ambient temperature is higher than 25°C. Supply voltage rejection ratio SVRR 80 100 dB 3. Forsupplyvoltages less than ±15 V, the absolute maximum Output voltage swing Vom ±12 ±13.5 V RL::' 10 kQ Output voltage swing Vom ±12 ±12.0 V Rl::' 2 kQ Common mode voltage Vicm ±IO ±14 V Storage Temperature Range -55 to +125°C input voltage is equal to supply voltages. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Slew rate SR 90 8 57 rnA V/i/sRL=2kQ Gain bandwidth GBW 10 15 MHz Power bandwidth PBW 50 70 kHz Unity gain Irequency lunity Phase margin RL = 2 kQ Vo = ±IO V Vo = 27 Vp.p• THO:sI% MHz 60 Total harmonic distortion THO 0.002 % Vo = 3 VRMS, 2 to 20 kHz Channel separation CS 120 dB 1= 20 Hz to 20 kHz Input RMS noise voltage 1.2 0.5 0.65 i/VRMS RIAA i/VRMS Flat + JISA Input noise voltage en 4.5 nV/JljZ I = I kHz Input noise current in 0.7 pA/JljZ I = I kHz 3-105 II ~EC JlPC4570 Operating Characteristics TA = 25°C Input Noise vs Frequency Characteristics Phase Gain vs Frequency 1o,---------,----------,----------,----------, 50 -- RL = 10kO: CL::: opF ~VOL ~.~----~------~-------4------~ ¢ ~61---------+---------j---------+---------j f-- r- 90 -... r-... -180 .... t-- ~ 4 ~ , 0. £ 21----------+------1-------+------1 I 01LO--------~lO~0--------~lk----------,JO-k--------~100k 50 _ AVOL ¢ r-- Frequency (Hz) Gain, Phase vs Frequency Voltage Follower Pulse Response V, --: ±15 V RL = 2 kO RL:-;- 10 kO CL = 220 pF - CL --=47pF Slew Rate - 7 Vips 90 ............. ....... r- 1-_ r-- r-- I I -180 1M Frequency (Hz) 3-106 1\ 1\ II I / 1/ 10 lOOk 10M 1M lOOk Frequency (Hz) I I tJ I 10M GND \ 1\ 10 Time (/Jsj 12 NEe NEe Electronics Inc. pPC324 QUAD LOW-POWER OPERATIONAL AMPLIFIER Pin Configuration Description The tlPC324 is a quad operational amplifier designed to operate from either single or split power supplies, with very low current drain. The input common mode voltage of these amplifiers includes ground and they are internally frequency compensated for unity gain stability. Features D Internal frequency compensation D Large output voltage swing: 0 V to V+ - 1.5 V DC D Input common mode voltage range includes ground D Wide power supply range: Single supply 3 V to 30 V DC Dual supplies ±1.5 V to ±15 V DC D LM324 direct replacement 83-002213A Ordering Information Part Number Operating Temperature Range Package pPC324C pPC324G2 Plastic DIP 0° 10 HO°C 0° 10 HO°C Plastic Mlnlflal Equivalent Circuit 114 Circuit v+ 6.A 6.A 100pA Cc 0, >---+ RSC 1,7,8.14 Output 3,5, 10, 12 0" +Input ~------+--r 010 ~--!---c- 0" 0" SOpA 11 GND (V-) 83-0022128 3-107 !\fEe pPC324 Absolute Maximum Ratings Operating Characteristics TA = 25°e, V± = ±5 V TA = 25°e Voltage Between V+ and V- 32 V Differential Input Voltage 32 V Input Voltage Supply Current -0.3 to +32 V Power Dissipation, C Package 570 mW Power Dissipation, GPackage 550 mW Operating Temperature Range. Cor GPackage o to +70°C Storage Temperature Range, Cor GPackage -55 to +125°C f-----j----,----,---+--+__ Electrical Characteristics TA = 0 to 70°C TA = 25°C, V± = ±5 V Parameter S,mbol Limit Test Min. Typ. Max. Unit Conditions Input Offset Voltage Vio 2 Input Bias Current Ib 45 Input Offset Current lio 5 Common Mode Input Voltage Range Vicm Supply Current ICC Large Signal Voltage Gain AVOL Output Voltage Swing YOM 88 250 nA 50 nA V+ -1.5 V Input Bias Current mA RL = = on all op·amps 100 dB RL 2': 2 kn 100 75 V+ -1.5 V CMRR 55 85 dB Supply Voltage Rejection Ratio SVRR 55 10 dB Output Current (Source) 0 Supply Voltage (V) 0.8 Common Mode Rejection Ratio Channel Separation ,. 0 mV Rs=on CS IOSOURCE 20 RL = 2 kn ~ i(I ---- 50 ~ i '5 f = 1 kHz to 20 kHz 120 dB 40 rnA + Input = 1 V. -Input = 0 V Output Current (Sink) IOSINK 10 20 rnA -Input = 1 V. + Input = 0 V Output Current (Sink) IOSINK 12 50 rnA -Input = 1 V. + Input = 0 V 00 10 ... r- ............. i-""" TA = +25°C '0 30 40 Supply Voltage (V) Voltage Gain 160 RL=20kO 120 ....- ~ m ~ r-- ~ RL=2kO c ·iii "~ 80 J! ~ ~ 40 00 10 '0 Supply Voltage (V) 3-108 30 40 NEe pPC324 Operating Characteristics (Cont.) TA = 25°C Current Limiting Common Mode Rejection Ratio 120r----------,----------r---------,----------, 70 ~ 60 C .§. ~ 8 m ~ ~ i.. 50 , ~ 0 40 " I--- r---.... 30 -20 20 a: ----I----40 60 ~g ~ ~g • <3• a0r---------+---------+---------~--------__l 60r----------+----------r----------r--------~ 40r----------+----------r----------r--------~ 20r----------t----------r----------r--------~; ij O~________J __ _ _ _ _ _ _ _~_ _ _ _ _ _ _ _~~------~g ao 100 1k 10 k 100 k 1M Frequency (Hz) Ambient Temperature (OC) Open Loop Frequency Response E1 Large Signal Frequency Response 20 ,40r-----,-----.-----,-------------,0-M-n---------. I a: 15 .. ~ Vo 1\ .j C/I f :!l 10 \ ~ r-o.. ;f .,. · ," ""-i" i 1k Frequency (Hz) lOOk +15V ~ 10 k '" 100 k Frequency (Hz) 1M Voltage Follower Large Signal Pulse Response RL:::::2 kO V+ -15 V - / I \ \ fU I I 1 1 1 I ~ o 10 20 30 40 Tim&(pS) 3-109 pPC324 3-110 NEe NEe NEe Electronics Inc. Description pPC3403 QUAD HIGH· PERFORMANCE OPERATIONAL AMPLIFIER Pin Configuration The IlPC3403 quad operational amplifier is designed with four independent high gain frequency compensated operational amplifiers. Featuring operations from either single or split power supplies from 3 V to ±18 V. The common mode input range includes the negative supply which eliminates the need for external biasing circuitry in most applications. Features o o o o o o Input common mode voltage range includes ground or negative supply Output voltage can swing to ground or negative supply Wide power supply range: Single supply of 3.0 to 36 V Split supplies of ±1.5 to 18 V Class AB output stage for minimal crossover distortion Short-circuit protected outputs MC3403 direct replacement 63-002223A Equivalent Circuit 114 Circuit V+ 14 + Input Output 1.1'.6,'\" AS 2.4 kG GND(V-) 11 83-0022228 3-111 II NEe IlPC3403 Absolute Maximum Ratings Ordering Information TA = 25°C Voltage Between V+ and V- Part Number 36 V Package Operating Temperature Range Dilferentiallnput Voltage ±36 V pPC3403C Plastic DIP DOC to +lO°C Input Voltage INote I) ±18 V pPC3403G2 Plastic Minillat O°C to +lO°C Power Dissipation, CPackage 570 mW Power Dissipation, G2 Package ° Operating Temperature Range 550 mW to +70°C Storage Temperature Range -55 to +125°C Note: 1. The absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA = 25°C, V± = ±15 V Limits Parameter Symbol Min, Input Offset Voltage Input Offset Current liO Input Bias Current Large Signal Voltage Gain AVOl Input Voltage Range Vicm Common Mode Rejection Ratio CMRR Supply Voltage Rejection Ratio Supply Current Output Short Circuit Current Isee Note) 10SHORT Unit 2,0 7,0 mV V+ = +5 V, V- = GND 5 50 nA V+ = +5 V, V- = GND 45 250 nA V+ = +5 V, V- = GND 86 ........................... . 98 +13 to +13.5 to -15 -15 70 89 V+ = +5 V, V- = GND, RL = 2 kn V 90 dB 103 dB 103 d8 V+ = +5 V, V- = GND ,.........~.~ ...... ?,~...... ~~ ....~O. ~~: ~~.=:.":': ~I! ~~a.n~!I~ ........................ . 2.5 7.0 mA ±10 ±20 ±45 mA ±12 ±13.5 V+ = +5 V, V- = GNU, all channels .................................... . CS 120 Note: Do not exceed the maximum power dissipation rating. 3-112 dB RL = 10 kQ .............................................................................. . . =!=.I.O .••• :±:I.~ •...••....••..~ ..•. ~~ ~ ~:O. ~c: V+ - 1.7 V+ - 1.5 V Rl = 10 kn, 5 V:5 V+:5 30 V, v- = GNU Output Voltage Swing Channel Separation Max, ... ~6...••. ~~ .•.........••. ~~ ..••~O. ~ :±:I.~ ~'. ~~.=: .2. ~C: SVRR ICC Test Conditions Typ, dB , = I kHz to 20 kHz NEe JlPC3403 Operating Characteristics TA = 25°C Open Loop Frequency Response Power Bandwidth 120 30 100 ,.iii "'S~. " 80 < 60 ;g 40 '"I'" 20 o 1 10 100 a: ~ l o '" .,·i'" 10 I'" i 100 k 1M \ i\. o 10 M ~ 10 k 1k I r-- 1M 100 k Frequency (Hz) Frequency (Hz) Output Swing Input Bias Current 30 ~ \ r 10 k 1k 20 ~ II 60 / !'E ./ 20 i 10 , t--- ~ / 0 - - 40 S / ! 20 / ±5 ±10 o ±15 -40 -20 20 40 60 80 Temperature (Oe) Supply Voltage (V) Input Bias Current 60 ~ 40 ~ u Iii ~ -- 20 ±5 ±10 ±15 Supply Voltage (V) 3-113 pPC3403 3-114 t-IEC fttlEC NEe Electronics Inc. pPC4064 QUAD J-FET INPUT LOW-POWER OPERATIONAL AMPLIFIER Description Pin Configuration The pPC4064 is a low power J-FET input quad operational amplifier that will operate at voltage levels as low as ±2.0 V. Input current is typically less than 1 rnA. With input bias and offset currents as low as a few pA. the pPC4064 is an excellent choice for hand-held measurement equipment. Features D D D D D D D Low supply current Very low input bias and offset currents High slew rate High input impedance Output short circuit protection Internal frequency compensation TL064 direct replacement 11 Ordering Information Operating Temperature Range Part Number Package IIPC4D64C 14·pln plastic DIP -20 10 +70·C IIPC4D64G2 14-pln Mlnlflal -20 10 +70·C B3-003133A Equivalent Circuit 114 Circuit r-------------~r_------------~--------_r--------------~v+ R. R. Q5~----------~~Q~·~------------t_----~~~------~r_----, IMo---l---+--' L-----~__~------~__________~------------~~~_+------~v- 83--0031348 3-115 !\fEe pPC4084 Absolute Maximum Ratings Recommended Operating Conditions TA = 25°C Supply Voltage Differential 36 V Power Dissipation. CPackage (Note I) 570mW Power Dissipation. G2 Package (Note 2) 550mW Differential Input Voltage (Note 3) ±30V Output Short Circuit Duration Indefinite Operating Temperature Range -20 to 70°C Parameler Limits Min Typ Max Symbol Supply Voltage Vsupp Output Current Load Capacitance ±2 V 10 5 rnA CL 220 pF Nole: 1. Derate at 8 mW/oC when TA > 25°C. 2. Derate at 5.5 mW/oC when TA> 25°C. 3. For supply voltage less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Electrical Characteristics TA = +25°C. Vsupp = ±15 V Parameter Symbol Min limits Typ Input Offset Voltage Vlo Input Offset Voltage Vlo aViol a T 10 Input Offset Current 110 Input Offset Current 110 Input Bias Current Ib Input Offset Voltage Drift Input Bias Current Large Signal Voltage Gain Common Mode Rejection Ratio Power Supply Rejection Ratio Output Voltage Swing ±Vo Common Mode Input Voltage Supply Current 70 70 Tesl Conditions 10 mV mV pV/oC 5 50 1.5 pA 100 nA pA TA = Topt 10 3 nA TA = Topt Rl = 10k. Vo = 10 V Ib 70 Unll 15 2 AVOL Isupp CMRR PSRR Max 76 BOO 95 dB 1000 Rs = 50n Rs=50n. TA=Topt Rs=50n.TA=Topt pA dB 95 dB ±12 ±14 V Vcm ±12 +15 -13 V Output Current 10 -3.5 Slew Rate SR 3 VIpS Rl = 10k Input NOise Voltage en 30 nV/y'iiZ 1= 1 kHz Gain Bandwidth Product Channel Separation rnA GBW Rl = 10k ±Vo = ±10 V MHz CS 120 dB I = Ito 20 kHz Electrical Characteristics TA = +25°C. Vsupp = ±5 V Parameler Limits Typ Symbol Min AVOL CMRR 20 Common Mode Rejection Rallo 70 90 dB Power Supply Rejection Ratio PSRR 70 90 dB Output Voltage Swing ±Vo ±3.8 ±4.1 V Vcm +4.7 -2.8 +5.2 -3.5 V Large Signal Voltage Gain Common Mode Input Voltage 3-116 Max Unll Unil ±16 Tesl Condilions dB Rl = 10k NEe NEe Electronics Inc. pPC4074 QUAD J-FET INPUT LOW-NOISE OPERATIONAL AMPLIFIER Description Pin Configuration The J-FET input operational amplifiers of thepPC4074 are designed as low-noise versions of the pPC4084. Features of the pPC4074 include improved input equivalent noise voltage, input offset voltage, and input bias current compared to the pPC4084. The pPC4074 is an excellent choice for a wide variety of applications, including audio preamplifier and active filter circuits. Features o o o o o o o o Low-noise en = 18 nV/y'Hz Low-input bias and offset currents Output short-circuit protection High-input impedance: J-FET input stage Internal frequency compensation High slew-rate: 13 Vips typical Latch-free operation TL074 direct replacement 83·0D2213A Equivalent Circuit 114 Circuit r---------~----------~----~------~----~------~v+ R, 3,5.10,12 + Input o - - - - - j - - - - - - - - - - - j - - - - - ' 1,7,8,14 t--¥./V--+------+--------Q Output a, Q" a, D, R, R, R, R, 11 L -__~----.+_____.+___________+ _ - - - - + _ - - - - . _ .______+_--___+--_o GND (V-) 83-0022786 3-117 II ,..,EC pPC4074 Ordering Information Part Number Package pPC4074C Plastic DIP pPC4074G2 Plastic Mlniflat Recommended Operating Conditions Limits Operating Temperature Range Parameter Supply Voltage Absolute Maximum Ratings (AV=+11 Output Current Differential tnput Voltage tnput Voltage (Note I) Power Dissipation (C Package) Power Dissipation (G2 Package) Output Short Circuit Duration 36 V ±3D V ±15 V 350 mW 440mW Indefinite Operating Temperature Range Storage Temperature Range Note: I. For suppty voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 3-118 v± Capacitive Load TA = 25°C Voltage Between V+ and V- Symbol Min. Typ. 10 ±5 Max. Unit ±16 V 100 pF 10 rnA Test Conditions t'tIEC J1PC4074 Electrical Characteristics TA = 25°C, V± = ±15 V Limits Parameter Symbol Min. Typ. Max. Unit Test Conditions Input Offset Voltage Vlo 3 10.0 mV RSoS50n Input Offset Current 110 5 50 pA TA = 25'C [Note I) 30 200 pA TA = 25'C (Note I) Input Bias Current Ib Large Signal Voltage Gain AVOL Supply Current Common Mode Rejection Ratio Icc CMRR 70 86 dB Supply Voltage Rejection Ratio SVRR 70 86 dB Output Voltage Swing VOM ±12 ±13.5 V RL:o:l0kn Output Voltage Swing YOM ±IO ±12 V RL:O: 2 kn Common Mode Input Voltage Range Vicm SR ±10 Slew Rate Input Equivalent Noise Voltage 106 8 10 dB RL :0: 2 kn. Vo = ± 10 V rnA Four amplifiers V 13 V//1s 18 nV/JHz 4 IlVRMS 3 MHz CS 120 dB ViD aViD/aT 10 en Unity Gain Bandwidth Channel Separation 88 Av= 1 Rs = 100 n. f = 1 kHz Rs = 100 n. f = 10 Hz to 10 kHz II Over Operating Temperature Range Input Offset Voltage Input Offset Vollage Drill 13 mV Rs oS 50 n. TA = TOPT IlV/'C TA=TOPT Input Bias Current Ib nA TA=TOPT Input Offset Current liD nA TA=TOPT Nole: 1. Input bias currents are temperature sensitive. Short time measuring method is recommended to maintain the junction temperature close to the ambient temperature. 3-119 fttfEC pPC4074 Operating Characteristics TA = 25°C Power Dissipation Open Loop Frequency Response 1000 120 c ° ~ :;0 G2 Package ~ 400 ~ --..... 0- "~ ~c ~_CPackage 600 ! "",""r, 100 800 ;;.§. ~ ............ ........ 80 [ 60 ll, I .!! g ............ 200 40 40 60 80 o 100 "" "........ f------ - i 20 20 V± =±15 V RL=2kO """- I ........ 1 10 100 Ambient Temperature (0C) 1k 10k lOOk 1M Output Voltage Swing Large Signal Frequency Response 30,-------r-------~------,--------,------, 40 V±=±15V RL = 10 kO RL = 10 kO ; • I ~ 1: 30 -----+--- 20 "'" ·i r-------,I~v~±-~--±~,0~V+--------+-l VI • I ~ Ii' 20 'ii> 10 o ~ J-----~~~~----~--~ " 10 OL--------L------~--------L--------L~~--~I 100 1k 2k 10k 1M ./ /' 10' / '"" Output Voltage Swing Voltage Follower Pulse Response . € 5 B g io . ·i VI -5 RL =2kO: / V Output 1\ \ I > ;; 10 ~ 0 Load Resistance (kO) 3-120 ±20 Supply Voltage (V) 20 ./ ±10 10M Frequency (Hz) 30 1'" 10M Frequency (Hz) Time(jJs) CL = 100pF V± = ±15 V I "' fttIEC JlPC4084 QUAD J·FET INPUT OPERATIONAL AMPLIFIER NEe Electronics Inc. Description Pin Configuration The tlPC4084 offers four operational amplifiers with matched ion implanted P-channel J-FET inputs with standard bipolar technology in a single 14 pin DIP. With low input bias current and slew rates ten times that of general purpose amplifiers, this device is ideally suited for pulse amplifiers, active filters and integrator designs. r------1'4J Output 0 -Input D + Input 0 Features D Wide common-mode and differential input voltage range D Low input bias and offset currents D Output short-circuit protection D High input impedance: J-FET input stage D Internal frequency compensation D High slew-rate: 11 V/tls typical D Latch-free operation D TL084 direct replacement 83-OO2279A Equivalent Circuit 114 Circuit r-----~-----~--~--_4r_--1_----Ov+ 3,5,10,12 1,7,8,14 Output + Input o - - - t - - - - - + - - - - - . J t---'V'V"v--t----t----oQ 03 R, 02 R, ~-~--~--+------~ ___ ~--~ __ " ~~-4_-0V- 83-002278B 3-121 II t\'EC pPC4084 Electrical Characteristics Ordering Information TA = 25°C, V± = ±15 V Limits Parameter Symbol Min. Typ. Input Offset Voltage Vio Input Offset Current lio Input 8ias Current Ib Large Signal Voltage Gain 5.0 30 Max. Unit 15.0 mV 200 pA 400 pA Test Conditions DoC to +70°C Voltage Between V+ and VPower Dissipation (Note I) AVOL 88 dB 106 RL 2: 2 kO. Vo = ±IO V CMRR Supply Voltage Rejection Ratio SVRR Output Voltage Swing VOM ±12 ±13.5 V RL2:IOkO Output Voltage Swing VOM ±IO ±12 V RL 2: 2 kO Common Mode Input Voltage Range Vicm ±IO V Slew Rate SR II Input Equivalent NOise Voltage en 25 Unity Gain Bandwidth GBW Channel Separation CS B.O 11.2 mA All amplifiers Differential Input Voltage Input Voltage (Note I) Output Short Circuit Duration Operating Temperature Range 70 70 76 dB 76 Storage Temperature Range dB Vips Av= I v'iil r = I kHz. nV/ Hz RS = 100 0 MHz 120 dB Over Operating Temperature Range 3-122 Plastic DIP Absolute Maximum Ratings Common Mode Rejection Ratio Input Offset Current pPC4084C TA = 25°C ICC Input Offset Voltage Drift Input Bias Current Package Operating Temperature Range RS:S 500 Supply Current Input Offset Voltage Part Number 20 Vio t.Viol t. T Ib lio 10 10 mV RS:S 50 0, TA = TOPT /lV/oC TA = TOPT nA TA = TOPT nA TA = TDPT 36 V 570 mW ±30 V ±15 V Indefinite 010 HO°C -55 to +125°C Note: 1. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ttiEC /lPC4084 Operating Characteristics TA = 25°C Large Signal Frequency Response Open Loop Frequency Response 120 RL 100 iii "- ~ 80 ~ c ~ 60 f 40 30 v± = ±15 V "- ~ 1 10 ~ 20 "- "" 10. ~ ~ r--... 10 0 "- lOOk "I 1M Frequency (Hz) o 10M 1• 100 10 k ~g> j 20 .'" 30 v± = ±15 V /' ~ ! 0 10 ,/ o V / / J'" '" /" 20 .j '" & l! ~ 1 10 8 I 2 o II Output Voltage Swing = 10 kO V '" 10 M 1M 100 k Frequency (Hz) 40 RL \. "\ V± = ±5 V Output Voltage Swing 30 \ V±=±10V '" 1;; = 10 kO .\ . c 1k 100 RL V±=±15V OJ'" 20 o = 2 kO ±10 o ±20 / 100 V--- V / 1• 300 Supply Voltage (V) 3. 10 Load Resistance (kO) Input Equivalent Noise Voltage Voltage Follower Pulse Response 10' -5 I /' ... Output '" '\ RL=2kO CL. = 100 pF V± = ±15 V v± = ±15V R6=1000 ~ . 103 % ~ ~ 102 -5Z ~ 10 1 Time (uS) ----10 r---- 100 ,. 10. 100 Frequency (Hz) 3-123 !ft{EC pPC4084 Operating Characteristics (Cont.) TA = 25°C Input Bias Current Supply Current 100 2.S V±= ±15 V .. 10 ~ !! ! / 1.• '3 0.1 0.01 - -20 V V 1 3 . : ~ ./ I ~ 20 /' 1.5 1.0 O.S 40 Ambient Temperature (OC) 3-124 S 2.0 60 80 ~ ~ ~ 0 0 ±S ±10 Supply Voltage (V) ±15 ±20 NEe NEe Electronics Inc. J.lPC4574 QUAD ULTRA LOW-NOISE, WIDEBAND, OPERATIONAL AMPLIFIER Description Pin Configuration The pPC4574 is an ultra low noise, high slew rate quad operational amplifier specifically designed for audio, instrumentation, and communication circuits. The low noise and high frequency capabilities make it ideal for preamps and audio filters for instrumentation and professional audio. Features o o o o o Ultra low noise High slew rate Wide bandwidth Internal full frequency compensation Quad equivalent to NE5532 II Ordering Information Part Number /lPC4574C /lPC4574G2 Operating Temperature Range Package 14·pin plastic DIP 14·pin plastic minillal J,lPC4574C/G2 -2010 +80'C 83-003135A -2010 +80'C Equivalent Circuit 114 Circuit v-o-----~r-------~--~--------------~----~--_. Q. ::r------+-E:......::.'--------------+~C Q,. -Input +Input 0---+-------+--....1 R. +-----t: R3 v-o---+_~~-+-- Q,. "------+----+---+---0 Output R. o __~--------4__ _~~--------+___~~ 83-{)o31368 3-125 ft¥EC J.lPC4574 Absolute Maximum Ratings TA = 25'C Voltage Belween V+ and V- 36V Power Dissipalion. CPackage 570mW Power Dlssipalion. 82 Package (Nole I) 550mW Dillerenliallnpul Voltage (NOIe 2) ±30V Oulpul Shorl CirculI Duration lOs Operating Temperalure Range -2010 BO'C Slorage Temperalure Range -5510+125'C Note: 1. Derate at 5.5 mW/'C when TA > 25'C. 2. Forsupply voltages less than ±15 V. the absolute maximum Input voltage is equal to supply voltage. Electrical Characteristics TA +25'C. v± = 15 V Parameter Symbol Min LlmHs Typ Max Unit Inpul Ollsel Voltage Vlo 0.3 5 mV Inpul Dllsel Currenl 110 10 200 nA 430 1000 nA 12 mA Inpul Bias Currenl Large Signal Voltage Gain Supply Currenl Ib 00 110 dB Test ConditIons Rs=50Cl Rl =2k.Vo=±10V Common Mode Relection Ratio AVOL Isupp CMRR BO 100 dB Power Supply Rejection Ratio PSRR 80 100 dB OulpUI Vollage SwIng ±Vo ±12 ±13.5 V Rl 2: 10k Oulpul Voltage SwIng ±Vo ±10 V Rl 2: 2k Common Mode Voltage Vcm ±10 ±12.B ±14 8.5 V AC and Noise Characteristics Limits SR 4 6 Unit VIps GBW 10 14 MHz Power Bandwidlh PBW 50 70 Unity Gain Frequency lunity Parameter Slew Rale Gain Bandwidth Product Symbol Phase MargIn TOial Harmonic Dislortion Channel Separation THO CS Min Typ Max kHz Test Conditions Rl =2k Vo = 27 V pop. THO os; 1% MHz 50 degrees 0.002 120 % Vo = 3 V rms. 210 20 kHz dB 1=20t020kHz 1.2 pV rms RIAA + 30 kHz LPF pV rms Flat + JISA Rs = 100 Inpul Noise Voltage en Inpul Noise Vollage Densily en 5.0 nV/v'Hi 1= 1 Hz Inpul Noise Current Density in 0.7 pA/v'Hi 1= 1 Hz 3-126 0.53 0.65 NEe NEe Electronics Inc. Description IlPC4741 QUAD HIGH-PERFORMANCE OPERATIONAL AMPLIFIER Pin Configuration The tlPC4741 is a quad operational amplifier designed using four independent internally compensated highperformance 741-type operational amplifiers. The superior AC and DC characteristics of bandwidth, slew-rate, and noise make this device ideal for active filter and audio amplifier applications. Features D Internal frequency compensation D Output short-circuit protection D Large common mode and differential input voltage range D No latch-up D No crossover distortion D Wide power supply range: ±2 V to ±20 V D HA4741 direct replacement 83-002236A Equivalent Circuit 1/4 Circuit v+o-------4r----------------~------~--------~----~--_. as~----------------~--_4~~------~~--r 2,6,9,13 - Input o-----r 3,5,10,12 + Input o---------t-----------t-----' Rs 1,7,8,14 +-..JV\,........+--+--+-o Output R, 11 V-o-------~--_4--__~~--___4--------_~----+_----_4___4--~ 83-0022358 3-127 II NEe tJPC4741 Ordering Information Absolute Maximum Ratings TA = 25°C Voltage between V+ and V- 40 V Power Dissipation C Package 570 mW Power Dissipation 62 Package 550 mW Differential tnput Voltage ±30 V Input Voltage (Note I) Part Number Package Operating Temperature Range ttPC4741C Plastic DIP 0' to 70°C ttPC474162 Plastic Minillat 0' to 70'C ±15 V Indelinite Output Short Circuit Duration (Note 2) oto +70'C Operating Temperature Range ~55to Storage Temperature Range +125'C Notes: 1. Forsupply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. 2. Short-circuit to ground on one amplifier only. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics = 25°, V± = ±15 V TA Limits Parameter Symbot Min. Typ. Max. Unit Input Offsel Voltage ViD 1.0 5.0 mV Input Offsel Current liD 30 50 nA 100 300 nA 210 mW 100 dB Input Bias Current Large Signal Voltage Gain Power Consumption Ib AVOl 88 150 Po Common Mode Rejection Ratio eMRR Supply Voltage Rejection Ratio SVRR Output Voltage Swing 80 dB 94 90 94 Test Conditions RS:Sl000 RL2':2kO,VO=±10V dB YOM ±12 ±13.7 V RL2': 10 kO Output Voltage Swing YOM ±10 ±12.5 V RL 2': 2 kO Common Mode Input Voltage Vicm ±12 ±14 V Slew Rate 8R 1.6 Input Noise Voltage en 9 Channel Separation CS 108 3-128 Vips Av = 1 nV/v'liZ 1=1 kHz dB 1= 10 kHz ttiEC JlPC4741 Operating Characteristics TA = 25°C Large Signal Frequency Response Open Loop Frequency Response 120 30 v-+: "'- .......... 80 ..~ e "~ 60 ~ "" 40 20 o , 10 V± = ±15 V ±15 V RL::O 2 kO CL=50pF '00 '" ....... '" . , '00 10. '~ "\ ,M 100 k ,. o 100 10 M !l'" 20 ] ::; 10 · E E ,/ ...... V / V / / ~ / 20 ·i'" -~......;J ..... 0, 5.0 k 0, 0" L--- R" '--- v~ll ~ + ..... 100 R" 4 R,. 5.4 k 0 .. 1 GNO y- • 83-00231BA 4-1 ttiEC pPC311 Absolute Maximum Ratings Ordering Information TA = 25° C Voltage Between V+ and V- 36 V Part Number Package Operating Temperature Range Output to Negative Supply Voltage 40 V pPC3ll C Plastic DIP DoC to +70° C Ground to Negative Supply Voltage 30 V pPC3ll G2 Plastic Minillat DoC to +10° C Oillerentiallnput Voltage ±30 V Input Voltage (Note 1J ±15V Power Dissipation. C Package 350mW Power Dissipation. G2 Package 440mW lOs Output Short Circuit Duration Operating Temperature Range. C or G2 Package Storage Temperature Range. Cor 62 Package Oto+10°C -55 to +125° C Note: 1. For supply voltages less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA = 25° C. V± = ±15 V limits Parameter Symbol Min. Test Conditions Typ. Max. Unit 2.0 7.5 mV V+ - V- = 5 V to 30 V. Rs:s 50 kn Input Ollset Voltage ViO Input Ollset Current liD 6.0 50 nA V+ - V- = 5 V to 30 V. Rs:s 50 kn Input Bias Current Ib 100 250 nA V+ - V- = 5 Vto 30 V. Rs:S 50 kn AVOL 106 Voltage Gain Response Time tRSP 200 Saturation Voltage VSAT 0.75 Strobe ON Current ISTB ON 3.0 50 nA Output leakage Current 1.5 ns Input step 100 mY. overdrive 5 mV V Y,N 2" 10 mY. 10 = 50 rnA rnA 10LEAK 0.2 Positive Supply Current Icc+ 5.1 7.5 rnA Negative Supply Current 5.0 rnA Icc- 4.1 Input Voltage Range Viem ±14 Saturation Voltage VSAT 0.23 Y,N 2" 10 mY. 10 = 35 rnA V 0.4 V V+ 2" 4.5 V. V- = 0 V. V,N:S -10 mV.lo = B rnA Over Operating Temperature Range Input Ollset Voltage Vio 10 mV V+ - V- = 5 V to 30 V. Rs:S 50 kn. TA = 0 to 70°C Input Ollset Current 110 70 nA V+-V-=5Vt030V.Rs:S50kn. TA=Ot070°C 300 nA V+ - V- = 5 Vto 30 V. Rs:S 50 kn. TA = 0 to 70°C Input Bias Current 4-2 t-t{EC IlPC311 Typical Applications Offset Null Open Collector Output V+ V+ 3k 8 >--+---oVo 7 83-002320A 83-002323A Strobing Emitter Follower Output .. V+ 8 ......---oVo 83-002321 A Increasing Input Stage Current .-_-.-----0 V+ 83-OO2324A 83-002322A 4-3 NEe pPC311 Operating Characteristics TA = 25°C Input OHset Current Input Bias Current 500 t--- 400 1 300 ~ a ! ~o V" ~ f15V- - -- - ......... Pins 5, 6 and 8 Shorted Pins 5, 6 and 8 Shorted 1 t--- r- 1. 0 10 j!! 200 --- 0 ! ! Normal 100 o o o 20 40 --- - r----...... V±=±15V 60 80 - Normal o 20 60 40 80 Ambient Temperature (0C) Ambient Temperature (0 C) OHset Error Input Characteristics 100 V±=±15V ~ s 8, Maximum ~ g ~ V 10 0 , ! / - ,/ 1 1S0~+--i--t-4--4--+--+--~4--+-4~+--+--t-4--i 1/ J~ 125j-~~--t-i'~::+==+~j-i'-t~~~-t--r-i'~ 100~+--i--t-4--i--+--+--~4--+-4~+--+--t-4--i I Typical i .~ oli 50r-+--+-1--+--r-i--+-+--+-4--+-~-+--r-+-~ voy Vii tRt It'e 1 10k 75r-~-i--t--r-i--t--t--~~-+~~~-t--t--r-i lOOk 1M 25~+--i--+--r-i--+--+--~-r-+--r-;r-+--+--r-i 10M -12 -8 Input Resistance (kO) -4 12 Transfer Function Common Mode Limits 60 -0. 5 ~ ~ V±~~30V 50 Reterenced to Supply Voltages 'E -1. 0 r 40 8, ;:; I 16 Differential Input Voltage (V) ~ -1. 5 . ~ ~ c ~ ~ ~ ~ E +0. 4 30 I 20 0 +0. 2 Follower Output RL=600n 10 10 20 30 0 40 50 Ambient Temperature (OC) 4-4 " Emitter 60 70 80 1.0 0.5 I'... Normal Output RL = 1 kO v- == 40 V II "} i'--. '"" Diffe,enliallnput Voltage (mV) 0.5 1.0 ,..,EC pPC311 Operating Characteristics (Cont.) TA = 25°C rvt. Response Time lor Various Input Overdrives I 5 20 mV 4 IJ V I ~y ,-.. j---"" 5mV 3 V/ I'--- 2mV 2 I 500 VIN _ - - - '/./ -L. '" '" 0.4 0.6 \ \ ~ .1 ../ \ j---,2.mV'-- Vo - //' V 1 I Response Time lor Various Input Overdrives 5mV'-- 1- il - VIN + , \ 2mV'-- - 5.. _ Vo I J J :J., :J., :J., _ - I I I I I I·j.. II i,:[ I I I I I IJJ o 0.2 0 0.2 Time (us) Response Time lor Various Input Overdrives & 5 5 • 5mV 2mV 5 -1 • r • 1 • / 711 11 r1- V j : ~ / : t - 'i'V+ i ~+ - _ III v '6/ • -1 5 > E-o I 20mV , , V- Vo b 2. , ~ 'j:: _ 15 > .! f \ ,---, .. -15 , \, \ - - ~ V- , :j:: Vo- 2.0 , - :j:: :\: 5. V± = ±5 V t Time {tIs) Output Limiting Characteristics Output Saturation Voltage •. 7 14 • • ,8 •. 7 •. 6 ~ 0.4 ./ 3 ,,/ /' ..... l,...""'" V v ,..- 2. 3. Output Current (rnA) .. {\ , ! /I '\.2 ~ ~ -........ ~ .~, •. 2 1. .......- 12. :c l/ .., / •• :l 11 - + r-----20mv~ IL\ ~ Time (.us) I. V'N I'. S V± = =5 V ~ 0.5 .. ~- ,1\ "- -1. !--2Imv~ - ~ -10 ,. I -5 !--5 mv/ -5 ~ 0.6 Response Time for Various Input Overdrives ~ • 0.4 Time (us) 4• 5. ~a,;on- •. 6 •. 5 8. ..4 6. •. 3 V & I // •V r- Short Circuit Current 4. •. 2 2. •. 1 • ,. 15 • Output Voltage (V) 4-5 !c ~ :ic ! t-fEC pPC311 Operating Characteristics (Cont.) TA = 25°C Supply Currenl Supply C!.!!'!'ent -------- Positive Supply -OutPul~ / 10 v±=1±15V ---- ~ /' ~nd Negalive Supply OUIPUIHir o o 10 15 20 I 25 30 Leakage Currenl. 10-8 OU'~' 10-' I f 10-10 ...I Vo=40V -- ~ ,~ 10-1 25 35 --- 15 V -- I V±=±15V 45 55 Ambient Temperature (OC) 4-6 - Input V,N Posillve Supply Output Low I Positive and Negative Supply OU'PU'119 h o o 10 20 30 40 SO Ambient Temperature (OC) Supply Voltage (V) g r-- 65 75 60 t-----70 I 80 NEe NEe Electronics Inc. jlPC319 DUAL HIGH·SPEED VOLTAGE COMPARATOR Pin Configuration Description The tlPC319 is a precIsion high-speed comparator designed to operate from single or split power supplies from +5 V to ±15 V. It features excellent input characteristics and drive compatibilities to all popular logic families. The tlPC319 is designed for commercial temperature ranges. Features D D D D D D Operates from single 5 V supply Typically 80 ns response time at ±15 V Open collector output Minimum fan-out of two each side (TTL) High common mode slew rate LM319 direct replacement 83-002341A Equivalent Circuit 112 Circuit II 11 ., R, ., R, R, V V "- va, ,...,. r-... a, Va, Va, 5,10 V ""- -I nput ,9 a, "'" ""- =:= c, "r-..' a R, a, a, R, R" ~ R" R" +1 nput 42 R, Va" ""- a, R, R" Note: Pins 1,2,13,14 No Connection ,.. a,,"'- ....... R25 R" R" R23 - a" ......... R20 a20 >-0,,>- ~ R" ~a" R" 0" R" 7,1 o,',/' 42 a,,)1-- 11"" O"r a" ~,' R" a"r R" Quip ut R" 8 GN o 6 v83-0Q2340A 4-7 ttlEC pPC319 Absolute Maximum Ratings Ordering Information TA = 25°C Temperature Range Voltage Between V+ and V- 36 V Part Number Output in Negative Supply Voltage 36'1 JlPC319C Plastic DIP 25 V JlPC319G2 Plastic Minillat Ground to Negative Supply Voltage Ground to Positive Supply Voltage 18 V Oifferentiallnput Voltage ±5 V Input Voltage [Note 1) Package O'C to +70'C ±15 V Power Dissipation. C Package 500mW Power Dissipation. G2 Package 550 mW 10 s Output Short Circuit Duration oto +70'C Operating Temperature Range. Cor G2 Package Storage Temperature Range. Cor G2 Package -55 to +125'C Nole: 1. For supply voltages less than ±15 V. the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA =25°C. V± = ±15 V Limits Parameter Input Offset Voltage Symbol Min. Typ. Max. Unit Test Conditions Vio 2.0 8.0 mV Input Offset Current liD BO 200 nA Input Bias Current Ib 400 1000 nA Voltage Gain AVOL Response Time tRSP 80 ns Input 100 mV. overdrive 5 mV Saturation Voltage VSAT 0.75 1.5 V VI :S -10 mV.lo = 25 rnA Output Leakage Current 10LEAK 0.2 10 JlA VI?10mV.lo=35mA Positive Supply Current Icc+ 4.3 rnA V+ = +5 V. V- = 0 V Positive Supply Current Icc+ 8.0 12.5 rnA V±=±15V Positive Supply Current Icc+ 3.0 5.0 rnA V±=±5V Vlcm ±13 V V±=±15V 0.4 V V+? 4.5 V. V- = O.V. VI:S -10 mV. 10 = 3.2 rnA Input Voltage Range Saturation Voltage VSAT Over Operating Temperature Range 78 92 0.23 V± = ±5 Vto ± 15 V. Rs :S 500 dB Input Offset Voltage Vio 10 mV Input Offset Current liD 300 nA V± = ±5 Vto ±15 V. Rs:S 5 kO. TA = 0 to +70'C Input Bias Current Ib 1200 nA V± = ±5 V to ±15 V. Rs:S 5 kO. TA = 0 to +70'C 4-8 V± = ±5 V to ±15 V. Rs:S 5 kO. TA = 0 to +70'C t\'EC pPC319 Typical Applications Split Supplies Single Supply V+ (<; 18 V) V+ (<; 18 V) VRL (<; 36 V + V-) VRL (<; 36 V) Vo Vo V- (:0- -25 V) V- (:0--25 V) 83-002343A 83-002342A Operating Characteristics TA = 25°C I nput Currents Input Characteristics 1000 500 400 ;;£ i ------- 800 Ib .. Ib_ Ibl V±=±15V r--.... \/ C 600 £ ~ 300 a ! } . 0 iii 200 ~ 400 200 J~ 100 -200 ',0 -400 --20 20 40 60 80 DIHerentiallnpul Voltage (V) Ambient Temperature (0C) Transfer Function Common Mode Limits 20 a ~ :::; i:. ,,:,-"~1 5v E E <3 1=""1 '1 VT - 2 -20 20 40 Ambient Temperature (OC) I 60 Vi"=±15V RL=1.4kO 15 a / 8. ::g ~ 10 II l ;3 J! 80 v.:.=15V -1.0 -0.6 -0.2 // Vv:L=5V +0.2 +0.6 -t1.0 Difte,entiallnput Voltage (V) 4-9 tttfEC pPC319 Operating Characteristics (Cont.) TA = 25°C Response Time lor Various Input Overdrives 61 . 5 \ \ I'\. 2+~ \ "- 2 V\ 1 0 ~ " 5mV :!- - = .. ~ 5 1 0 200 i 300 . € // 100 V± - ±15 V VRL_=+SV_ ,L- 5007 ~ ~ I 100 Response Time lor Various Input Overdrives :~:::~::~:;:===~===~====~==~'J-±~--±1-5T!V'---' ____ f---+-'+1~'\.--"H--+---+--~~~~~:ri_ 6 5 3 3 \ 1 t--201~ 0l, ~ 01 f'"f 2 mV--+--+---+--j IY- \ ·1" 1/7 ~5~V 'If-- ~ 2 \-~ /) / 1 o I'. 100 200 'P 20 / V 0.2 100 300 Output Limiting Characteristics / / J / " / j "E- 80 u 60 ~ c:; V±=±15V Input OVerjrlVe 0.6 1.2 100 J Output Voltage (V) 4-10 300 200 120 = 5 mY 40 20 0.4 P 0 Output Saturation Voltage ....... P Time (ns) 25 / , P V+=±15V VR1.=+SVRL=500n Time (ns) / V 2Lv D- J- I I I I I I I II o 20m:t.../j" V 4 4 \ 300 200 Time (ns) Response Time lor Various Input Overdrives \ \ I I / V/T 1/ 1/-----12 mV / !/7 r--- 5~V II / Time (ns) 2 i i 1 ----- "- 100 I _20~V 2mV I I I J I I I II o I I VRL +5 V RL=5000 '\ I\"\. 3 - Response Time lor Various Input Overdrives - 0.8 1.0 1/ '"....--- - -- i 1.0 _ ~hort Circuit Current ~ ........... 0.8 ~ ./ - 0.6 0.4 Power Dissipation 0.2 j/ 5.0 10 Output Voltage (V) 15 ~ o ..~° ttiEC J.lPC319 Operating Characteristics (Cont.) TA = 25°C Supply Current Supply Current 0 /~ 8. 0 0 2.0 10 .,/' /" V - V ±5 I V ....... lcC+ I Icc- - ~ V±=±15V ICC+ l- ICC- I~ ±10 ~ _I- 20 ±20 ±15 Supply Voltage (V) 40 60 80 Ambient Temperature (ee) Supply Voltage Range 4or------------,,------------.--=---------, ~ VRlRange ~ V+Range II ~ L--------------~,-0--------------~20-------------3~0 g Negative Supply Voltage (V) 4-11 pPC319 4-12 t-IEC NEe NEe Electronics Inc. jJPC339 QUAD LOW-POWER VOLTAGE COMPARATOR Pin Configuration Description The tJPC339 is a quad comparator designed to operate from a single or split powersupply over a wide range of voltages, with very low current consumption. Even when operating from a single power supply the input common mode voltage includes ground. 1----,r - - - - ; t 4 t OutputC Features D Input common-mode voltage range includes ground D Wide power supply range: Single supply 2 V to 36 V DC Duai supplies ±1 V to ±18 V DC D Low power consumption D Compatible with all forms of logic D Open collector output D LM339 direct replacement 83-002310A Ordering Information Part Number Package Operating Temperature Range IlPC339C IlPC339G2 Plastic DIP Plastic Mlnlflal DOC to +70°C DoC 10 +70°C II Equivalent Circuit 114 Circuit + Input - Input Output 0------+----+-------' 83-0023098 4-13 NEe IlPC339 Absolute Maximum Ratings TA = 25°.c Voltage Belween V+ and V- 36 V 3lP! Differentialtnput Voltage -0.3 to +36 V Common Mode Input Voltage Power Oissipation. CPackage 570 mW Power Dissipation. G2 Package 550 mW Output Short Clrcuilto Ground Indefinile Operating Temperature Range. Cor G2 Package Storage Temperature Range. Cor G2 Package -55 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA = 25°.c. V+ = 5 V limits Parameter Symbol Min. Typ. Max. Test Conditions Unit Input Offset Voltage Vio mV Vo = 1.4 V. VREF = 1.4 V. RS = 0 0 Input Bias Current Ib 25 250 nA Vo = 1.4 V Input Offset Current liD 5 50 nA Vo = 1.4 V V+ -1.5 V 2 mA Rl = dB Rl = 15 kO o Common Mode Input Voltage Range Vicm Supply Currenl Icc Voltage Gain AVOl large Signal Response Time tRSP Output Sink Current IOSINK 0.8 106 6 00 1.3 I'S Rl 5.1 kO. VRl = 5 V 16 mA VIN(-) = 1 v. VINI+) = 0 V. VO:O; 1.5 V Saturation Voltage VSAT 0.2 Output leakage Current IUlEAK 0.1 0.4 V VINI-) = 1 v. VINI+) = 0 V. IOSINK = 3 mA nA VINI+) = 1 v. VINI-) = 0 V. Vo = 5 V Typical Applications V+ V+ Output VIN 1.2 13.14 0------1 Output 1.2 13.14 R, VHYS VREF = 0 to V+ -l.SV VREF 83-002311A 4-14 =( _R_1_) V+ R1 + R2 = 0 to V+ - 1.SV 83-002312A t\'EC pPC339 Operating Characteristics TA = 25°C Supply Current Input Bias Current 50 RL=OC 1.2 1 1,0 ~ /' .?~ 0.8 '" 0.6 ------- ---~ C o ~ -- /" ./ 'D 'T.:'"~ooc 1 ~ ~25°C .. 0 3D ID !,!;;.l0oe ! f.,---- 20 II-_~______~--~T~A~7~0~OC~~::::::::~::=-~--~ ~ lD 10 20 30 L -_ _ _ _ _ _ ~ ______ 10 0 ~ _ _ _ _ _ _ _ _L -_ _ _ _ _ _ 20 Supply Voltage (V) 30 . .". Response Time for Various Input Overdrives ~ ,... 20mV f ~ -~¥ vo- 11 , s c5 j 0.1 I '0 Supply Voltage (V) Output Saturation Voltage 11 ~~ .s> j ~ 0.01 ~ g 100 Output Sink Current (rnA) I 100mV - \. TA = 25°C -50 11 ! r-- __ -100 I I 0.5 1.0 1.5 2.0 Time(ps) Response Time for Various Input Overdrives 100 mV Input Overdrive [ 'I 1 > / I I 20mv/ '/ I i/ J / 5mv/ I~-= !J .s 100 VIN 11 ! 5.1 k Vo + & ~ _ - 50 TA = 25°C 0.5 1.0 1.5 2.0 Time (.us) 4-15 II J,lPC339 4-16 fttfEC NEe NEe Electronics Inc. pPC393 DUAL LOW-POWER VOLTAGE COMPARATOR Pin Configuration Description The pPC393 is a dual comparator designed to operate from either single or split power supplies from + 2 V to ±18 V. It features low power supply current drain and input common mode voltage which includes ground, even when operated from a single supply. ThepPC393 is designed for Commercial temperature ranges. Features o o o o o o Input common-mode voltage range includes ground Wide power supply range: Single supply 2 V to 36 V DC Dual supplies ±1 V to ±18 V DC Low power consumption Compatible with all forms of logic Open collector output LM393 direct replacement J,lPC393CI pPC393G2 S3-002359A .. Equivalent Circuit 112 Circuit v+ Output Input 0::------+----+------' 83-0023588 4-17 NEe JiPC393 Ordering Information Absolute Maximum Ratings TA = 25°C Voltage Belween V+ and V- 36 V DiHerenlial Input Voltage 36 V -0.3 to +36 V Common Mode Input Voltage Power Dissipation. C Package Part Number Package pPC393C Plastic DIP pPC393G2 Plastic Miniflat Operating Temperature Range DOC to HO°C 350 mW Power Dissipation. G2 Package 440 mW Output Short Circuit to Ground Indefinite oto +70°C Operating Temperature Range. Cor G2 Package Storage Temperature Range. Cor G2 Package -55 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA=25°C.V+=5V Limits Parameter Symbol Min. Typ. Max. Unit Test Conditions Input Offset Voltage Vi. 2 5 mV Vo = 1.4 V. VREF = 1.4 V. Rs = Input Bias Current Ib 25 250 nA Vo = 1.4 V 50 nA Vo = 1.4 V Input Offset Current Ii. Common Mode Input Voltage Range Vlcm Supply Current Icc on 0 0.6 mA RL=oo Voltage Gain AVOL 106 dB RL = 15 kn Large Signal Response Time tRLS 1.3 mA -INPUT = 1 V. + INPUT = 0 V. Vo ~ 1.5 V Output Sink Current IOSINK 16 Saturation Voltage VSAT 0.2 Output Leakage Current IOLEAK 0.1 0.4 V nA - INPUT = 1 V. + INPUT = 0 V. IOSINK = 3 mA + INPUT = 1 V. - INPUT = 0 V. Vo ~ 5 V Typical Applications v+ V+ Output 1.7 t---t-'V\f'y-.......--Q Outpul 1.7 VREF = 0 to V+ - 1.5 V 83-002360A VREF = 0 10 V+ -1.5 V 83-002361 A 4-18 NEe pPC393 Operating Characteristics TA = 25°C Supply Current Input Bias Current 50 RL=OO 1.0 "oS 0.8 I () ~ ~ 0.6 ~ 0.4 /./ ---- .......-............ .,.., /' ~ ~ 40 _~TA~25oe ~ ~TA=70°C iii ~ ~ () 30 TA = 25°C '5 r 30 40 TA ~ - 2. ~ 20 10 TA = O°C TA = Dec 10 Supply Voltage (V) Output Saturation Voltage we ~ ~ ~ • 10 20 40 30 Supply Voltage (V) Response Time lor Various Input Overdrives 10 ~ ~ & f ~ 0 ~ 20mV 100mV ~ I & ~ § ~ ! VIN _ 5.1k - + r- - - \. ,.oS ~ ;~'"~~~ Vo '5 l!! f-h. TA = 25°C -50 -100 ~ 100 Output Sink Current (rnA) 0.5 1.0 1.5 2.0 Time{tls) Response Time lor Various Input Overdrives 100 mV Input Overdrive y I I I 20mv/ 1 ,.g f ~ I I I '7~ I J II J VIN _ 5.1 k Vo 100 + - 50 TA= 25°C .E 0.5 1.0 1.5 2.0 Time cps) 4-19 pPC393 4-20 r-rEC NEe DEFINITION OF TERMS Input Offset Voltage: The voltage between the input terminals when the output is within a specified voltage range. Input Voltage Range: The range of common mode voltage at the input terminals within which operating specifications are assured. Input Bias Current: The bias current of the input transistors. Output Leakage Current: The current into the output terminal, at a given output voltage and input drive, equal to or greater than a specified value. Input Offset Current: The difference in current in the two input terminals when the output is at a specified voltage. Output Sink Current: The maximun negative current that can be output by the comparator. Voltage Gain: The ratio of the change in output voltage to the change in input voltage. Saturation Voltage: The low output voltage level at a specified current "sink" level. Common Mode Rejection Ratio [CMRR]: The ratio of the input voltage range to the maximum change in input voltage over this range. Overdrive: The input step voltage required, at some predetermined input level, to change the output state to high or low from its initial state. Supply Voltage Rejection Ratio [SVRR]: The ratio of change in input offset voltage to the change in supply voltage. .. 4-21 DEFINITION OF TERMS 4-22 t-IEC ftlEC VOLTAGE REGULATORS 5-A II VOLTAGE REGULATORS ttiEC Section 5 - Voltage Regulators tJPC305 Precision Positive Voltage Regulator ........................................ 5-1 tJPC317 Three-Terminal Adjustable Positive Voltage Regulator ........................ 5-5 tJPC337 Three-Terminal Adjustable Negative Voltage Regulator ....................... 5-9 tJPC2600 Series Three-Terminal Positive Voltage Regulator ......................... 5-13 tJPC78LOOH Series Three-Terminal 0.1 A Positive Voltage Regulators ................ 5-17 tJPC78LOOJ Series Three-Terminal 0.1 A Positive Voltage Regulators. .... . . . .. ... . . .. 5-23 tJPC78MOO Series Three-Terminal 0.5 A Positive Voltage Regulators ................. 5-29 tJPC7800 Series Three-Terminal 1.0 A Positive Voltage Regulators ................... 5-35 tJPC79LOO Series Three-Terminal 0.1 A Negative Voltage Regulators ................. 5-41 tJPC79MOO Series Three-Terminal 0.5 A Negative Voltage Regulators ................ 5-45 tJPC7900 Series Three-Terminal 1.0A Negative Voltage Regulators .................. 5-51 5-8 t-iEC jlPC305 PRECISION POSITIVE VOLTAGE REGULATOR NEe Electronics Inc. Description Pin Configuration ThejlPC305 is a precision adjustable voltage regulator designed for a wide range of applications including digital and analog circuits. This device features fast response to both line and load transients, low standby power dissipation, and freedom from oscillation with variation in resistive or inductive loading. This device is ideal for use in general purpose power supply circuits. Current Limit [ 1 Booster Output [ 2 Unregulated Input C 3 GND [ \..J jJPC305C B 7 6 4 5 P P P Regulated Output COMP/S.D. Feedback P Reference Bypass 83-002478A Features o o o o o Output voltage adjustable from 4.5 V to 30 V Output currents in excess of 10 A possible by adding external transistors Load regulation better than 0.1%full load with current limiting DC line regulation guaranteed at 0.03%1V LM305 direct replacement Equivalent Circuit Unregulated Input 2.8 k 600 R, ,----1-------t"' 012 '----+----+---------.,---1;:..0,. >---1: 013 !----1. 1.86 k 0" a" Booster Output R8 1.32 k t-----+--[, +----1:: 05 R, 0, 0, Current Limit Regulated Output 4.4 R6 D, Compensation! Shut Down 6.8 k R3 Feedback Reference Bypass 2.2 k Rs Ground 83-002477A 5-1 t-IEC pPC305 Absolute Maximum Ratings Ordering Information TA = 25°C Input Voltage 40 V 40 V Peak Output Current Part Number Package Operating Temperature Range pPC305C Plasllc DIP oto +70°C 50 mA Power Dissipation 350 mW oto +70°C Opanting Tempentun Ranga . Stonge Temperature Ranga -55 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics LimHs Parameter Symbol Min. Typ. Max. Input Voilige Ranga VIN 8.0 40 v Output Voltage Range Vo 4.5 30 v Inpul Output Voltage DIHanntial load Regulation Lln~ Regulation 3.0 v = 18 n ......................................................................................... 0.02 0.05 % REGIN 0.025 0.06 %/V VIN - Vo ,,; 5 V 0.015 0.03 %/V VIN - Vo > 5 V 0.003 Temperature Stability Feedback sense voltage 1.65 %/V 0.3 1.0 % 1.8 1.90 V CHEF = 10 pF. f = 120 Hz DOC :5 TA :5 70°C ....................O:~~~ ............. ~.....1.0. ~~ ~! ~ .I~.~~z: ~~W~.~ ...................... . 0.002 % long Term Slibility 0.1 % Standby Current Drain 1.0 CREF: Bypass capaCitor of pin 5. RSC: Output current sense resistor. 5-2 0 :510:5 12 mAo RSC REGl Ripple Rejection Standby Current Drain 30 Test Conditions Unit 2.0 CHEF = 0.1 pF t-iEC pPC305 Operating Characteristics TA = 25°C Load Regulation - r"""'IIIIo ~ g I. i -0.01 Load Regulation ~ t"- o"d -20°C - -r-- ................. -0.02 "" ;; % 0 TA -0.03 ~ -0.02 '\ c 0 :; ~ \ -0.04 11, f! ~ -0.06 0 -0.08 - Rse = 130 - I I----O~C/ 201oC~ ~ '" lL\\ V\ / ~ /" , I ~ \ \ \ \ \ 20 10 15 10 ....... / TA=2SloC/ -0.1 o \ 80"C./ ~ Rsc=O -0.04 - r-- r-- ....... 80°C V ~ ~ KA Load Current (rnA) 3.2 1.0 . . / T~=25"C/ ' VI ,.- ./°tC-r-- ~ /·20"C g 2.6 J 2.4 '\ 8b"c.t ./ ~ ;; 0.6 % 0 . ~ 0.4 ~ R1/R2 \. 3.0 j 2.8 "\ ....... Rl = 1.11 X Vo (0) 2.2 r-Rsc 113 n o 10 20 30 40 2.0 50 - "\ ............ 0.2 ~ 2 kO 1\ a: o 40 Optimum Divider Resistance Values Current Limiting Characteristic ~ 0.8 I \ 30 Load Current (rnA) 10 5 Output Current (mA) ~ - 20 50 Output Voltage (V) Supply Voltage Rejection Current Limit, Sense Voltage 0.6 0.1 Vo 10 V TA - 25°C . ~ 0.5 <> f! ,g i '"'§ 0.4 F- :J C ~ 0.3 (J -- ----- ,. £g ~ l r-- 11, f! ~ 0.05 . t"-... 0.02 .=- 0.01 - 0.005 0.002 0.2 0 20 40 60 Junction Temperature (0C) 80 ........ CREF CREF == 0 10~F f::::: 120 Hz --, 0.001 1 10 20 50 Input/Output Voltage Differential (V) 5-3 NEe pPC305 Operating Characteristics (Cont) TA = 25°C Transient Response 4or------,------,------,r------r---.R~s~CC7.,0~0~--' ~----_+------1_----_1~----_+--~VIN~SV---- --~+---_ 1\ line 1 Vo 10 V ~.:C -40~----_t------1_----~------_+------+_----_; Rsc="100 .t ~ I----f-CL = 0 --f------+---Full Lc ld Current - 20 rnA - No Load Current =- 1.0 rnA 400 ~ _____ CL = 111F 1_--------jr-----'----'-;'---'-'---''--_t'_' 1.-"""---_1 ~ ~----_+------1_----_1~----_+--- Vo = 10 V - o 1\, __ _ Load ~--~~--·----~-I------~---+--~--~I -400~O------~----~,0------J-------2~O------~-----J30 TimeC/ls) Applications 5 V -- 15 mA Regulator 10 V -- 200 mA Regulator 130 1.3 n 0.5 W T 288505 T R13.,. C VIN 2':: 13 V ' C'3.3 PF o-4.....,--{!1 Rl2.4S • 83-002486A 83-002487A 1 A Regulator 15 V -- 1 A Foldback Current Limit r--------------------r------.....,.-o VIN 1.302W VIN 2:: 19 V O--4-......--+--~Hl.I R, 1.S02W L---------------------~ 83-002488A NEG cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement. 5-4 ____-o J, L~d 83..()(l2489A t-IEC pPC317 THREE-TERMINAL ADJUSTABLE POSITIVE VOLTAGE REGULATOR NEe Electronics Inc. Pin Configuration Description The IlPC317 is an adjustable three-terminal positive voltage regulator capable of supplying in excess of 1.5 A over a 1.3 V to 30 V output voltage range. Output voltage can be fixed by two external resistors. Features D Output current up to 1.5 A D Current limit constant with temperature 1 3 2 It\ Adj. Output Input D Internal thermal overload protection D Equivalent to LM317 83-002523A Ordering Information Part Number Package Operating Temperature Range pPC317H 3 pin SIP -20°C 10 +80°C Equivalent Circuit Input R27 R1 R2 R3 R. -K ::J 02..... RS 01O ~ ~ Q18 ~ Q13>- Q18;:t--- R18 R2 -K OS-K 07 C1 R1. C2 R10 R11 R12 R13 ,. 01. .r ~ Q11 Q12;:t- R21 R20 017' 08 R1' L.t::;:02S f-- 021 R8 03)t--K0 ' R8 ...... R17 SpF r""'I 01 ~~D V 023 Q20 01S...... '* II C3=~ R6 R7 bn; &' ,,01' &,0.&'08 k f- l~D H:::026 ~ '-- ~ R22 RM R2. R2S Output Adj 83·0019548 5-5 ~EC pPC317 Recommended Operating Conditions Absolute Maximum Ratings TA=+25°C ' Input-Output Voltagl Ollfarentlal hitiiiii;1 PaWBi DiHip.UGn (NGte 1) Oplrallng Templrature Range Storagl Tamparlture Ranga leld Temperature (Soldering. IDs) Tharmal Reslstlnciliunclion to c..e) Tbarmal ReslSllncl (juncllon to Imbllnt) 40 V 2DW -20°C tD +150°C -65°C tD +150°C 300°C 4°C/W B3°C/W Note: 1. Internally limited. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage tothe device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Limits Symbol Min. Typ. Max. Parameter input-Oulput Voltaga Dllllrintial Output Voltage VIN - Vo 3 38.7 V Vo 1.3 3D V Input Voltlge VIN 4.3 40 V Output Current Operallng Temperature Range 10 0.01 1.5 A TJ -20 +125 °C Unit Test Conditions Electrical Characteristics (VIN - Vo == 5 V, 10 = 0.5 A, O°C ~ TJ ~ +125°C) Parameter Symbot Min. Limits Typ. Max. TBst Conditions Unit Line Regulallon (NOla I) REGIN ...•..•.. ~:O........O:~~ .... ~~~ •••~A. ':". ~~~~'. ~.~ ~ !~I~. -:-. ~~). ~ ~~.~ ..............••• 0.02 0.07 %/V O°C:5 TJ:5 +125°C. 3 V:5 (VIN - VO):5 40 V load Regulation (NOlI I) REGl ..........~.~ .••.•. ~ •.5••..• ~. ~9 ...~~:=: ~.~ ~J. ~.~~o.C: .. ~.~~ ~ ~0.:S. ~.~ .A..•.•.••.•••••• 20 70 mV V0:55V. 0°C,,;TJ,,;+125°C.10mA,,;lo,,;1.5A .••••••••. ~•.•..•• Thermal RagullllDn Adluatmant Pin Currlnt Adjustment Pin Current Chlnge Relarenea Voltagl VREF Drill lDI~ Current Peak Output Currant REGTH IAOJ bolAOJ VREF boVREFI boT 1.20 4.7 VN Rlppla RllactlDn Rilio RR 1.5 0.07 100 5 1.30 10 %VO %/W pA VO~5V. 0°C,,;TJ,,;+125°C.IOmA,,;lo,,;1.5A TJ = 25°C. 0.2 ma:5t :5 20 ma V 10 mA,,; 10 ,,; 1.5 A. 3 V,,; (VIN-Vol ,,; 40 V. Po ,,; 20 W % DO C:5 TJ:5 +125°C mA (VIN - Vol = 40 V _... :~ •••••~.~ •••••• ~.~•••••••A•••••~ ~.~.(~!~.-:- .V.O) .~. ~~ ~ ••••••••...•.....••..•..•.. 0.15 Output Nol.. Voltage .. 0.7 10 10PEAK 0.3 0.02 50 0.4 1.25 ~~ ...... ~~ ....~~ ~ ~.~ .• ~J. ~.~~0.c: .l~.~~ ~ ~o. ~.l:~ .A.............. . O.B 0.001 (VIN - VO):5 40 V (~~2) TJ = 25°C. 10 Hz:51 :510 kHz .......... ~~ .............. ~~ .... ~~~J. ~ ~: Y~.=: !~.v:! ~ !~~ ~~'. ~~I~.=: .l.~ ~~.s 56 65 dB CAOJ = 10 pF. 10 V. f = 120 Hz. llVIN = 1 VRMS Not.: 1. Measured at constant junction temperature. using pulse testing with a low duty cycle. PW = 10 ms. duty cycle"; 2%. 5-6 ........ . ttlEC pPC317 Typical Applications Output Input R, C'N O.1,uF + Co 1pF R, Vo = [1 R, JXVREF R, +- 83-00195SA 5-7 pPC317 5-8 t-IEC NEe NEe Electronics Inc. JlPC337 THREE-TERMINAL ADJUSTABLE NEGATIVE VOLTAGE REGULATOR PRELIMINARY INFORMATION Description Pin Configuration The tlPC337 is an adjustable three terminal negative voltage regulator capable of supplying up to 1.5A over a voltage range of -1.3 to -30 V. Output voltage is set by only two external resistors. r--------------------------------, ___ 0 ) NEe Features D D D D pPC337 Output current up to 1.5A Current limit constant with temperature Internal thermal overload protection Output transistor safe area protection Ordering Information ,nput J /1'" ADJ Input Output 83-003110A Part Number Package Operating Temperature Range I'PC337H TO-220 -20°C to +85°C Block Diagram r - - - - -.........------------~-------.........-~ Input '--------t---+.---------------------.+---<> Output '-------------------------------<> Ad) 83-o03111A 5-9 t-IEC pPC337 Absolute Maximum Ratings (TA Recommended Operating Conditions = 25°e) Limits Input Output Voltage Diflerential -40 V Total Power DissIpation 25 W (Note 1) Operating Temperature Range Parameter S,mbol Input Output Voltage Differential Min. Typ. Max. VIN'VO -3 -5 -38.7 Uni. V -20 to +85°C Input Voltage VIN -4.3 -40 V Operating Junction Temperature -20 to +150°C Output Voltage Vo -1.3 -30 V Storage Temperature -65 to +150°C Output Current 10 0.01 1.5 A Operating Junction Temperature TJ -20 125 °C Junction to Case Thermal Resistance 4°C/W Junction to Ambient Thermal Resistance 83°CIW Note: (1) Thermal overload protection circuit shuts off the output whenever TJ ?: 150°C. Comment: Stresses above those listed under "'Absolute Maximum Rati ngs"' may cause permanent damage to the device. Th is is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics V,WVO = -5 V, 10 = 0.5 A, ooe::; T j ::; + 125°e Limits Parameter Symbol Min. Max. Unit 0.01 0.04 %/V TJ = 25°C. 3 V;;; IVIN·VOI ;;; 40 V (Note I) 0.02 0.07 %/V O°C;;; TJ oS 125°C. 3 V oS IV,N' Vol oS 40 V 15 50 mV TJ = 25°C. (Note 1) 0.3 1.0 % 10mAoSIOoSI.5A IVOI ?:5V 20 70 mV ooS TJ oS 125°C (Note 1) IVO'oS5V 0.3 1.5 % 10mAoS1OoS1.5A IVOI ?:5V line Regulation load Regulation Thermal Regulation Adjustment Pin Current REGL REGTH 'AOJ Adjustment Pin Current Change l!.IAOJ Reference Voltage VREF -1.20 Test Conditions Typ. 0.003 0.04 %/W 65 100 /lA 5 /lA -1.30 V -1.25 IVOI oS5 V TJ = 25°C.IVIN·VIi = 40 V, Vo = -10 V. oS 10 oS 0.25A. t = 10 ns o TJ = 25°C. 3 V oSIV,N'VO' oS 40 V. lOrnA oS 10 oS 1.5A (Note 2) 3 V oS IVIN'Vo' oS 40 V. 10 rnA oS 10 oS 1.5A (Note 2) l!.VREF/l!. T 0.6 % O°C oS TJ oS 125°C. 10 = 5 rnA Minimum load Current 10 Min 2.5 10 rnA IVIN'Vo' = 40 V Peak Output Current 1.5 2.2 2.9 A 3 V oSIV,N'Vol oS 15 V 'OPEAK 0.15 0.4 A IVIN'Vo' = 40 V 0.003 % TJ = 25°C. 10 Hz oS f oS 10 kHz 60 dB TJ = 25°C.l!.Vo = 1 Vrms 70 dB f = 120 Hz. Vo = 10 V VREF Drift Output Noise Voltage Ripple Rejection en RR 66 Note: 1. Pulse Measurement Pw = 10 ms. duty cycle;;; 2%. 2. Internal Power Dissipation;;; 20 W. 5-10 CAOJ = 0 CAOJ = 10 /IF NEe pPC337 Typical Connection f-o--..,....-..,....-o + Vo C'N O.1pF VO=[1+~].Vref R1 83-003112A Typical Applications 1. Variable Output Regulator Va = -1.3 V to -30 V Input (-4.3 V to -40.0 V) Output R2 Value -1.25 0 120 360 1032 2184 2760 -2.5 -5.0 -12 -24 -30 I I pPC337H ADJ : I Output I Vo R1 120n C'N 0.1 p,F : ; Co _ 1pf '" ~R2 II I 83-00311SA 2. Ripple ReJection Improvement Input f-o--""--""--"""1""--o Vo - Co 111f + 83-003114A 3. Current Regulator 10 Operating Range R1S12S0 IO~10mA 83-003115A 5-11 pPC337 5-12 t-{EC t-IEC JlPC2600 SERIES THREE-TERMINAL POSITIVE VOLTAGE REGULATORS NEe Electronics Inc. PRELIMINARY INFORMATION Pin Configuration Description The pPC2600 series are monolithic three terminal positive regulators which employ protection circuits against the dangerous overvoltages always present on the battery rail of the car. They are intended as fixedvoltage regulators for car instrumentation in vehicles with 12 V battery and can supply an output current up to 500 mA. Features D D D D D D D D 1 3 2 I t\ Input Gnd Output Output voltages of 5 V and 10 V Output current up to 500 mA No external components Low dropout voltage Load dump voltage surge protection Reverse voltage protection Internal thermal overload protection Internal short circuit current limiting B3-<102523A Absolute Maximum Ratings TA = 25°C Ordering Information Number Package Operating Temperature Range IlPC2600H Plastic SIP -30to+85°C Part Recommended Operating Conditions TA = 25°C Hem Input voltage Output Current Opereting Junction Temperature Range Symbol Limit Test Min. Typ. Max. Unit Condlltons 12 VIN 10 TI 50 -12 28 DC Input Voltage. VIN 10C) DC Input Reverse Voltage -VIN 10C) Positive Transient Voltage. VI, It = 40 ms. duty cycle = 1%) lurge) Negative Trlnslent Voltage. -VIN It = 30 mI. duty cycle = 1%)llurga) Internal Power Olilipation. Pr ITe = 25°C) Operating Junction Temperature Range. Tapt III Operating Temperature Range. Top. Storage Temperature Range. Tstg Thermal Rellstancellunctlon to caBal. Rlh U-ol Thermal Rellatsnce IIunctlon to ambient). Rut 11.1) -35 V -28 V 120V -90 V 20 WINotel) -30 to +150°C -30 to +85°C -65 to +150°C 83°C/W Note: 1. Internally limited. V 500 mA +125 °C 5-13 fttIEC pPC2600 SERIES Block Diagram 2 OUTPUT 3GND 83-0018898 Electrical Characteristics TA = 25°C Hem Output Voltaga Symbol Min. Limit Typ. Max. Unit Test Conditions pPC2605 Vo 4.8 5.0 5.2 V 12 V:5 VIN :5 16 V. 10 = 500 mA pPC2610 Vo 9.55 10.0 10.45 V 12 V:5 VIN :516 V.lo = 500 mA Line Ragulation REGIN 7 20 mV 12 V:5 VIN :516 V.lo = 50 mA Load Regulation REGL 0.3 1.0 'IoVo VIN = 14 V. 50 mA :510:5 500 mA Qulascant Curranl pPC2605 IBIAS 37 mA VIN = 14 V.lo = 500 mA pPC2610 IBIAS 150 mA VIN = 14 V. 10 = 500 mA d8 15 V:5 VIN:517 V.lo = 500 mA f = 100 Hz Ripple Rejection RR 56 pPC2605 VN 27 pVRMS VIN = 14 V.lo = 500 mA pPC2610 VI 53 pVRMS VIN = 14 V.lo = 500 mA Dropout Vollage VOIF 1.3 Short Circuit Currant 10ahori Paak OUlput Current 10peak Output Resistance Ro Lockoullnput Voltage VIN (cutl Output Voltage Drift LWo/L\.T OUlpul Noise Voltage 5-14 650 28 V 10 = 500 mA 900 mA VIN = 14 V 1.000 mA VIN=14V 0.07 Q VIN = 14 V. 400 mA :510 :5 500 mA f= 1 kHz V Vo = 0 32 0.4 1.7 35 mV/oC VIN = 14 V. 10 = 50 mAo -12°C:5 TA:5 +80°C t-IEC pPC2600 SERIES Timing Waveform '1 :5 40 ml, duty cycle:5 1% . -_ _ _ 12:5 30 ms, duty cycle:5 1% Input Vol"ge 0 _---'L-_ _ _ _ _+...L.-_-L_...L.-.....,I-h,.--__ Outpul Current 0 -------1-f-f-"'--+-...... OutputVoltago 0 _ _ _ _ _.............. ---I--II......J"-'----- C ___ _-'-_--IO_I......J"-OL-........ 63-0018918 Typical Application Input 0-....,...-<>--\ C'N O.1pF 1--o----1r--o Oulput Co O.1pF 83-00189OA 5-15 pPC2600 SERIES 5-16 ~EC NEe NEe Electronics Inc. /lPC78LOOH SERIES THREE· TERMINAL 0.1 A POSITIVE VOLTAGE REGULATORS Pin Configuration Description TheJlPC78LOOH series of three terminal regulators are monolithic positive voltage regulators which feature internal current limiting and thermal shutdown. They are intended for use as fixed voltage regulators in a wide range of applications, including local on-card regulators where distribution with single pOint regulation is a problem. NEe JAPAN 78LXXH This device is not recommended for new designs. Use JlPC78LOOJ instead. 3 o 1 It\ Features o o o 2 Output Output current in excess of 100 mA No external component required Internal thermal overload protection Internal short circuit current limiting Gnd Input 83-002510A Equivalent Circuit l 0 ........ R13 20. r--K J. Inp " a, I Va" ...... Va 01O ...... " RI1 4. R14 0 ........ 13,...... R12 200 R. 100 ~, R10 2 700 ~~D' 0, R16 300 u. /. R11 100 ~R' 500-7k ,. R, R2 10. R, 2. Quip ,t?- 8~ u. ~R, / 1.3k-14k 0 ........ '( ~o, "---- f-----K o,;J -Ko, ,. R, Q, 4. R, R, 1.3 k 3 GND 83-0025098 5-17 t-IEC pPC78LOOH SERIES Ordering Information Typical Application Part Number Package Operating Temperature Range pPC78L05H Plastic SIP -20·C to +SO·C pPC78L08H Plastic SIP -20·C to +SO·C pPC78L1oH Plaslic SIP -20·C to +SO·C pPC78L12H Plastic SIP -20·C to +SO·C pPC78L15H Plaslic SIP -2o·C to +8O·C pPC78LIoH Plaslic SIP -2o·C 10 +8o·C In pul 0.33 pF [Note 2] Internal Power Dissipation r : =C2 INaIe 1] Notes: [1] Although no output capaCitor Is needed for stability, it does Improve transient response. [2] Required it regulator is located an appreciable distance from power supply filter. 30V 35V Input Voltage fpPC78LloHI78L12HI78L15H) Outp ul 2 pPC78LOOH : =c, Absolute Maximum Ratings Input Vollage fpPC78L05H178L08H) 1 83-002511A 800mW Operating Temperature Range -20 to +SO·C Siorage Temperatura -5510 +150·C Operating Junellon Temperature Range -20 \0 + 150·C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics - pPC78L05H VIN = 10 V, 10 = 40 rnA, O°C:5 TJ :5125°C, CI = 0.33pF, Co = 0.1 pF Limits Parameter Output Voltage Symbol Min. Typ. Max. Vo 4.6 5.0 5.4 Line Regulallon REGIN Load Regulation REGl oulpul Voltage Vo Quiescent Current IBIAS Quiescent Current Change .t:.ISIAS Output Noise Voltage VN Ripple Re)eclion RR Temperature Coefliclent 01 Output Voltage Dropout Voltage Short Circuit Current 5-18 Vo/.t:.J Test Conditions Unit 55 200 mV TJ = 25·C. 7 V:s VIN:S 20 V ...............................__ .........................................................................................................................._. __ ._-_ .. 45 150 mV TJ=25·C.8V,;:;VIN:s2oV 11 60 mV TJ = 25·C. 1 mA,;:; to';:; 100 mA 5.0 30 mV TJ = 25·C. I mA:s 10:S 40 mA ------------------._ ... _---------------- 5.5 V 7 V:S VIN :S 20 V. I mA:s 10 :S 40 mA -------_ ...4.5 -_._.- ... -.- .............. _--._ .... -.. _----.-._----_ .. - .-.- .... --._-----_ .. -_. -._.-.-----_._._._-_ ........ _............................................ 4.5 5.5 V VIN = 10 V. 1 mA:s 10 :S 70 mA ~ ~ ~ ~=~~ ....................................... _.................................................................................................................. 5.5 mA TJ = 125·C 1.5 mA 0.2 mA VIN = 10 V. I mA:s 10 :S 40 mA 30 pV TA = 25·C. 10 Hz:s I:s 100 kHz 50 dB 1= 120 Hz. 8 V:s VIN:S lB V. TJ = 25·C -0.65 mV/·C 10=5mA .............. 40 8 V:s VIN';:; 20 V.lo = 40 mA ....•.•.•...................... _................................. Voo 1.7 V TJ = ~·C IOSHOR1 150 mA TJ = 25·C fttfEC pPC78LOOH SERIES Electrical Characteristics -IIPC78L08H VIN = 14 V, 10 = 40 rnA, O°C:5 TJ :5125°C, CI = 0.33pF, Co = 0.11lF Limits Parameter Oulput Vollage Line Reguillion LOld Regulation Teet S,mbol Min. T,p. Max. Vo 7.36 8.0 B.64 V 80 200 mV 70 150 REGIN REGL Quiescenl Curren! Change 40 mV .. .1:~ ............. ~.~.......~ ......O:~ ~.:;; .V.I~ ~ ~~ .V: !.~~ ~ ~~:s. ~~ ~~................ . IBIAS .......... ~.~ ...... ~.~...... ~~ ....~J. ~. ~~:~ ..................................... . AIBIAS 8.8 V 5.5 mA 1.5 mA VIN = 14 V, I mA 05 10 05 70 mA TJ = 25°C 12 V 05 VIN 05 23 V, 1005 40 mA .............................................................................. mA VIN = 14 V, I rnA 05 10 05 40 mA 60 0.2 pV TA = 25°C. 10 Hz:5 1:5 100 kHz 45 d8 1= 120Hz. 12V05VIN0522V.TJ = 25°C VO/AT -0.8 mVI"C 1.7 V TJ = 25°C 10SHORT 150 mA TJ VN Ripple Rejeellon RR 38 Dropoul Vollage Shan Circuli Curren! TJ = 25°C, I mA :510 :5 40 mA Vo Oulpul Noise VollIge Temperature Coallicleni 01 OutpUI Vollage TJ = 25°C .......... !~ ...... ~~ ...... ~~ ....~J.~. ~~:~'.! .II!~ ~ ~~ ~ .I~~.~~ .................... . 7.2 Quiescenl Curren! Conditions TJ = 25°C, 10.5 V 05 VIN 05 23 V .............................................................................. 8.0 Outpul Vollage Unit 10 = 5 mA = 25°C Electrical Characteristics -IIPC7 8L 1 OH VIN = 17 v, 10 = 40 rnA, O°C:5 TJ :5125°C, CI = 0.33pF, Co = 0.1 pF Limits Parameter Output Vollage Line Regulation Load Regulation Output Vollage Quiescent Current Quiescent Current Change S,mbol Min. Vo 9.2 Max. Unit 10 10.8 100 230 mV 80 170 mV 18 90 mV 9 mV 9.0 45 11.0 9.0 11.0 V 6.0 rnA 5.5 mA 1.5 rnA REGIN REGl Vo Test T,p. 4.0 IBIAS L;IBIAS V Conditions TJ = 25°C. 12.5 V 05 VIN 05 25 V ___ . o __ • • • • • • • • • • • • ___________________ • ___ • _______ • __ • __ _ TJ=25°C.I mA05 100540 mA 12.5 V 05 VIN 0525 V. I rnA 05 10 0540 rnA ------ ............ _---------- .. _-------_ ...... -.. -_ .... ---------------------------------------------- --------------------- VIN=17V.I mA 05 10 0570 rnA TJ = 25°C 13 V05 VIN 05 25 V. 1005 40 mA 0.2 Output Noise Vollage VN Ripple Rejection RR Temperature Coefficient 01 Output Vollage TA = 25°C. 10 Hz 05 105 100 kHz dB VohT -0.9 mV/OC 10SHORT 150 Dropout Vollage Short Circuli Current 70 44 37 10 = 5 rnA 1.7 5-19 t-IEC pPC78LOOH SERIES Electrical Characteristics -IlPC78L12H VIN = 19 V, 10 = 40 rnA, O·C::; TJ::; 125·C, CI = 0.33pF, Co = 0.1 pF Limits Paramaier Oulpul Voltage Line Regulallon Symboi Min. Vo 11.1 REGIN Test Typ. max. Conditions Unii 12 12.9 V TJ = 25°C 120 250 mV TJ = 25°C. 14.5 V:s VIN:S 27 V 100 200 mV TJ=25°C.16V:SVIN:s27V Load Regulallon REGL .......... ~~ ...... I.~O...... ~~ ....~J.~. ~~~~'. ~ .~A. ~ ~~ ~ .I~~.~~ ......... " ......... . 10 mV TJ = 25°C. I mA::; 10 ::; 40 mA 50 OUlpUI Voltage Vo 10.8 13.2 V 14.5V:SVIN:S27V.I mA:S10:S40mA .............................................................................. 10.8 Qulescenl Currenl Quiescenl Currenl Change V VIN=19V.I mA:S10:S70mA 6.5 mA TJ = 25°C 6.0 mA TJ = 125°C .............................................................................. .o.IBIAS •.•••••.•.....•.•• ~.~ •.•••. ~~ •••• 1.6.~;: ~!N. ;S.~~~: 1.0.~.4!I. '!I~ ....................... . 0.2 mA VIN = 19 V. I rnA:S 10 :s 40 rnA 80 pV TA = 25°C. 10 Hz::; I::; 100 kHz 42 dB 1= 120 Hz. 15 V:s VIN:S 25 V. TJ = 25°C VO/.o.T -1.0 mvrc 1.1 V TJ = 25°C 10SHORT 150 mA TJ = 25°C VN Ripple Relectlon RR 36 Dropout Vollage Short Circuli Currenl 13.2 IBIAS Outpul Noise Voltage Tempel'llure CoeHicienl 01 Outpul Vonage 4.2 10 = 5 mA Electrical Characteristics -IlPC78L 15H VIN = 23 V, 10 = 40 rnA, O·C::; TJ::; 125·C, CI = 0.33 pF, Co = 0.1 pF limits Parameter Output Voltage Line Regulilion Load Regulation Symbol Min. Vo 13.8 REGIN REGL Max. Quiescenl Curninl Qulncenl Currenl Chlnge Vo IBIAS .o.IBIAS 15 16.2 V 300 mV liD 250 .......... ~~ ...... I.~~ ..... ~~ ....~J. ~ ~~~~'. ~ .~A. ~ ~~ ~ .I~~.~~ .................... . 75 mV 13.5 16.5 V 13.5 16.5 V TJ = 25°C. I mA::; 10 ::; 40 mA 17.5V:SVIN:S30V.I rnA:S10:S4OrnA .............................................................................. VIN=23V.I rnA:s 10:S70 rnA ..........~.~ ...... ~.~...... ~~ ....~J.~. ~~~~ ..................................... . 6.0 mA TJ = 125°C 1.5 mA 20 V:s VIN :s 30 V. 10 :s 40 rnA .............................................................................. rnA VIN = 23 V. I rnA:S 10 540 rnA pV TA = 25°C. 10 Hz::; I::; 100 kHz 39 dB 1= 120 Hz, 18.5 V:s VIN:S 28.5 V. TJ = 25 C VO/.o.T -1.3 mvrc 10 = 5 rnA 1.7 V TJ = 25°C 10SHORT 150 mA TJ = 25°C Ripple Rejection RR Dropout Vollage 5-20 TJ = 25°C TJ = 25°C. 17.5 V:s VIN:S 30 V .............................................................................. 0.2 VN Short Circuli Currenl Conditions 90 Oulpul Noise Vollage Ternparalure CoeHicieni 01 OUlput Voltage Unit 130 12 OUlpUI Voltage Test Typ. 33 Q NEe pPC78LOOH SERIES Operating Characteristics TA = +25°C Current Limiting Characteristics Worst Case Power Dissipation ys. Ambient Temperature 1.0 tJPC78L05 VIN = 10V 100'b,W 0.8 I" ~ i5 a 0.6 .~ TJ~7yC_ i5 ~ r--. d.• & TJ 0.2 TJ = 25°C /' < .0 20 ~ 1 ~ ~ @ 60 Ambient Temperature 80 @ ~ rC) -- ----tJPC78L05 pPC78L05 = 25°C V I-- r-- c ~ u / 3.5 1 VIN = 10V o Vo= 5V 10 = 40 rnA 3.0 ~ 10 20 ~ 25 50 pPC78L05 VO=5V TJ = 25°C 2 = "lUO rnA 1C'=0i'A~ 50 rnA 'f~40iA"'-.. 10 10mA lo=100mA, ~ Dropout Conditions t:. Vo=5% ofVo ~ J. f 1 o'L-------~2~5------~50~------7~5~----~,Loo~-----,~25 r Junction Temperature (Oe) ~~ ~b 100 125 tJPC78L05 10 10 75 Dropout Characteristics Dropout Voltage as a Function of Junction Temperature r ~b Ambient Temperature (Oe) Input Voltage (V) I-- 200 Quiescent Current as a Function of Temperature '.0 5.0V I 150 Output Current (rnA) lo=40mA TJ 100 50 100 Quiescent Current as a Function of Input Voltage Vo 1 ~ 1~5'C r 1'.... ~~ ~~ W' ~ 1 ! J 10 Input Voltage (V) 5-21 NEe pPC7 SLOOH SERIES Operating Characteristics (Cont.) TA = ±25°C LC3d Transient Respciise 20 ~ 17.5 i!l 5 1 t Ii :ll 0 IlPC78LOS rPC78L05 c Input Voltage II 12. 5 ~ \ Load Current 10 0 u "0 10 0 0 ~ 1 ~ 7.5 100 14 I\, c Output Voltage 0 t 0 I 1 Output Voltage IV c ~100 i ~ 10 = 100 rnA ~(Retstive ILOad) o -200 0 10 12 ~ < VIN= 10 V ;; ~ 2 V0.15 V % 0 10 20 Ripple Rejection as a Function Frequency 100 90 30 40 50 Output Impedance as a Function 01 Frequency 10 .u PC78LOS tlPC78L05 1--+-+-+t-+-+-H+----1---+-+-++---1 VIN '--' 8 V to 18 V 10 =-c VIN = 10 V 40 rnA lo=40mA Co = 0.1 J.iF 80 iO 70 i.. 60 lO a: i;;; 60 Time (t.ts) Time (ps) S 2 50 ]. 1 40 i ~ E 30 O. 7 '5 o. 5 o o. 4 20 o. 3 10 0 J..-"'": ~~~~-+-_+_+~-+--~-H-_+-~~~__11 o. 2 ~~~-ll50--,OLO-~~5~00~~,~k-~~5~k--,0~k-L-L-5UO-k-,~O;k o. 1 10 Frequency (Hz) 5-22 V ~ ./ 10 50 100 500 1k Frequency (Hz) 5k 10 k 50 k 100 ttiEC pPC78LOOJ SERIES THREE-TERMINAL 0.1 A POSITIVE VOLTAGE REGULATORS NEe Electronics Inc. Description Pin Configuration The pPC78LOOJ series of three terminal regulators are monolithic positive voltage regulators which feature internal current limiting and thermal shutdown. They are intended for use as fixed voltage regulators in a wide range of applications, including local on-card regulators where distribution with single point regulation is a problem. ~,....-] NEe 78LOO Features D D D D Output current in excess of 100 mA No external component required Internal thermal overload protection Internal short circuit current limiting 3 2 1 /1'" Output GND Input 83-003097A Equivalent Circuit r-_--------.----~--_--~--~---() Input R17 R9 R11 R,O 1 .........-~----<>---.........-- IBIAS Output Noise Voltage VN Ripple Rejection RR 120 50 Dropout Voltage Short Circuit Current 10SHORT Peak Output Current 10PEAK Mo/L'>T Output Voltage Drift s: 38 V TA = 25·C. 10 Hz s: f s: 100 kHz 54 dB f = 120 Hz, 28 V s: VIN oS 38 V 2.0 V 10= 1.0A.TJ = 25°C A TJ = 25·C. VIN = 38 V 0.4 1.7 Test Conditions 2.4 2.8 1.4 A mV/·C TJ = 25·C. VIN = 33 V 10 = 5 mAo O·C s: TJ s: 125·C Operating Characteristics TA = +25°C Worst Case Power Dissipation vs. Ambient Temperature IJ Output Voltage vs. Ambient Temperature lol5mA In'lnl'e 20 ~ 5 c ; ! 15 I 10 so Hea,l Sink -- I QJ ~ With 10° C/W Heat Sink ~ No Heat sinl 25 ,g ;; r--.... ~ ,uPC780~H ./ '/' - .......... ""'- ~~~~1-so ~ "PC7812:;- / -100 ~ . -150 IJPC7824r -200 -250 so -300 75 100 Ambient Temperature (Oe) 125 25 25 so 75 100 125 150 Ambient Temperature rC) 5-39 NEe pPC7800 SERIES Operating Characteristics (Cont.) TA = +25°C Peak Output Current as a Function of Input/Output Differential Voltage Dropout Voltage as a Function of Junction Temperature 2. s 2.0 ~ 3.0 ------..::::::::::::-- :::::::--- ..... ~ r--- 1. 5 f f '· O 2.5 10 1A 0 '5 1.5 200mA I""-- c 0.5 ~ 2.0 ! 500mA g 20 rnA i 0 1.0 75 "C 0.5 ~ 9 -25 25 50 100 15 ~----~----~'0~--~'5~--~2~0----~2~5~---3f.0~--~35· 125 Junction Temperature (OC) Inpul to Output Voltage Differential (V) Load Transient Response (pPC7805H) Line Transient Response ~ t ~ I ~ 1.0 ~ 0.5 j i !c 10 10 Output Voltage t V -0.5 t I'A - V- ~ -1.0 I Input Vollage J Jf'... & = !l JiPC7805H 15 10 -10 = 500 rnA -Vo~5V o 10 20 30 40 50 10 60 Time (PS) 12 Time (.us) Dropout Characteristics (pPC7805H) Quiescent Current 10 - jlPC780SH 1 A ""- ~ ~OO mA pPC7824H O.SA ""- ~~""- ~ ~ OA "~ >Q ~ ( 0.1 A I '0 ~ ~ "P' 1 V~ ~ J Iff j /1 / /'" ~ IL 10 Input Voltage (V) 5-40 / If 1 ,uPC781 2H 15 20 Input Voltage (V) 25 30 35 40 ttfEC NEe Electronics Inc. pPC79LOO SERIES THREE-TERMINAL 0.1 A NEGATIVE VOLTAGE REGULATORS PRELIMINARY INFORMATION Pin Configuration Description The pPC79LOO series is composed of four monolithic three terminal negative voltage regulators that employ current limiting, thermal shutdown, and output transistor safe area protection. They are intended as fixed voltage regulators in a wide range of applications, including local or on-card regulation forelimination of noise and distribution problems associated with singlepoint regulation. The four devices in the pPC79LOO series (pPC79L05, 08, 12, and 15) have output voltage ratings of -5, -8, -12, and -15 volts, respectively. F] U79LOO , 3 2 /t~ Features GND D D D D Input Output Output current up to 100 mA Internal thermal overload protection Internal short circuit current limiting Low noise 83-D03116A Equivalent Circuit ~--~--~--~--~--------------------------------------~--~~ GNO A9 R. II A, A10 A6 '--------------------------'i---+----,~-----------'~--_+_<> Output D3 R11 R'3 t-----+---i------i:... 021 A,. R'9 -+-__-+____+-____________________-+-__---+-__________--'-______---+--<> L...-_ _ Input 83-0031178 5-41 ttiEC pPC79LOO SERIES Absolute Maximum Ratings Ordering Information Part Number Package /lPC79L05J (TA = 25°C) Operating Temperature Range T092 -30 or -35 V (Note I) Input Voltage -20°C to +05°C /lPC79LOOJ T092 -20°C to +05°C /lPC79L12J T092 -20°C to +05°C /lPC79L10J T092 -20°C to +05°C 700mW Internal Power Dissipation Operating Ambient Temperature -20 to +05°C Storage Temperature -55 to +150°C Operating Junction Temperature Range -20 to + 150°C Thermal Resistance Recommended Operating Conditions Parameter Symbol Input Voltage VIN (1) -30 V for /lPC79L05. 08 -35 V for /lPC79L 12. 15 Limits Type Number Min. Typ. Max. /lPC79L05 -7 -10 -20 /lPC79LOO -10.5 -14 -23 Comment: Stresses above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Unit V /lPC79L12 -14.5 -19 -27 /lPC79L15 -17.5 -23 -30 Output Current Operating Junction Temperature 10 All TJ All -20 100°C/W Note: 40 70 rnA 75 125 °C Electrical Characteristics - J,lPC79L05 V IN = -10 V, 10 = 40 mA, O°C:c::: TJ:c::: 125°C Limits Parameter Symbol Min. Typ. -4.0 -5.0 Test Conditions Unit -5.2 V TJ = 25°C -5.25 V -7 V oS VIN oS -20 V. 1 rnA oS 10 oS 40 rnA 5 60 mV TJ = 25°C. -7 V oS VIN oS -20 V 10 50 mV TJ = 25°C. 1 mAoSIOoSl00mA 6.0 rnA TJ = 25°C 0.5 rnA -7 V oS VIN oS -20 V. 10 oS 40 rnA 0.1 rnA V'N=-10V.l rnA oS 10 oS 40 rnA 100 /lVrms TJ = 25°C. 10 Hz oS f oS 100 kHz 70 dB f = 120 Hz. -8 VoS VIN oS -10 V. TJ = 25°C Output Voltage Vo Line Regulation REGIN Load Regulation REGL Quiescent Current 10lAS 4.2 Quiescent Current Change Max. -4.75 L::.IBIAS Output Noise Voltage VN Ripple Rejection RR Dropout Voltage VOIF 1.1 V TJ = 25°C 10SHORT 120 rnA TJ = 25°C. VIN = -20 V Peak Output Current 10PEAK 180 rnA TJ = 25°C Output Voltage Drill LWo/L::.T 0.4 mV/oC 10=5mA Short Circuit Current 5-42 50 t\'EC pPC79LOO SERIES Electrical Characteristics - JlPC79L08 VIN = -14 V, 10 = 40 mA, OOG:S TJ:S 125°G Limits Parameter Symbol Min. Typ. -7.7 -8.0 V TJ = 25°C V -10.5 V oS VIN oS -23 V 60 mV TJ = 25°C, -10.5 V oS VIN oS -23 V 80 mV TJ=25°C.l mAoS 10 oS 100 mA 6.0 mA TJ = 25°C 0.5 mA -10.5 V oS VIN oS -23 V.lo oS 40 mA 0.1 mA VIN=-14V,1 mAoSIooS40mA 110 /lV rms TJ = 25°C. 10 Hz oS f oS 100 kHz 70 dB f = 120 Hz, -12 V oS VIN oS -22 V, TJ = 25°C TJ = 25°C Line Regulation REGIN Load Regulation REGL 12 Quiescent Current IBIAS 4.2 Ripple Rejection RR Dropout Voltage -7.6 t;IBIAS VN Test Conditions -8.3 Vo Output NOise Voltage Unit -8.4 Output Voltage Quiescent Current Change Max. 50 VOIF 1.1 V Short Circuit Current 10SHORT 85 mA TJ = 25°C. VIN = -23 V Peak Output Current 10PEAK 180 mA TJ = 25°C Output Voltage Drift t;Vo/ t; T 0.6 mV/oC 10 = 5 mA Electrical Characteristics - JlPC79L 12 VIN = -19 V, 10 = 40 mA, OOG :S TJ:S 125°G Limits Parameter Output Voltage Symbot Vo Test Conditions Min. Typ. Max. Unit -11.5 -12.0 -12.5 V TJ = 25°C -12.6 V -14VoSVINoS-27V.l mAoSIooS40mA -11.4 Line Regulation REGIN 45 mV TJ = 25°C. -14.5 V oS VIN oS -27 V Load Regulation REGL 14 100 mV TJ = 25°C, 1 mAoS 10 oS 100 mA Quiescent Current IBIAS 4.2 6.0 mA TJ = 25°C 0.5 mA -14.5 V oS VIN oS -30 V, 10 oS 40 mA Quiescent Current Change t;ISIAS Output Noise Voltage VN Ripple Rejection RR Dropout Voltage 0.1 52 mA VIN = -19 V. 1 mA oS 10 oS 40 mA 140 /lV rms TJ = 25°C. 10 Hz oS f oS 100 kHz 70 dB f = 120 Hz. -15 V oS VIN oS -25 V, TJ = 25°C TJ = 25°C VOIF 1.1 V Short Circuit Current 10SHORT 40 mA TJ = 25°C. VIN = -27 V Peak Output Current 10PEAK 180 mA TJ = 25°C Output Voltage Drift t;vo/ t; T 0.8 mV/oC 10 = 5 mA 5-43 II ~EC pPC79LOO SERIES Electrical Characteristics - pPC79L 15 VIN = -23 V, 10 = 40 rnA, O°C:S TJ:S 125°C Limits 3Jmboi rOranlGIUr Output Voltage Vo Test Conditions Min. Typ. Max. Unit -14.4 -15.0 -15.6 V TJ = 25°C -15.75 V -17.5 V ~ VIN ~ -30 V. 1 rnA ~ 10 ~ 40 rnA -14.25 Line Regulation REGIN 10 45 rnV TJ = 25°C. -17.5 V ~ VIN Load Regulation REGl 15 125 rnV TJ=25°C.1 Quiescent Current ISlAS 4.2 Quiescent Current Change L>IBIAS Output Noise Voltage 180 VN Ripple Rejection RR Dropout Voltage VOIF Short Circuit Current 50 67 1.1 10SHORT Peak Output Current 10PEAK 180 Output Voltage Drllt L>Vo/L>T 1.0 Typical Connection Input 0--..,....--1: CON pPC79LOO ~t--~--<>OUIPut ::= COUT CIN: 0.1 100.47 pF; required If regulator Is located an appreciable distance from power supply tIIter. COUT: 2: D.22pF [recommended mylar capacitor]. 83·Q03118A 5-44 ~ -30 V rnA~10~100rnA 6.0 rnA TJ = 25°C 0.5 rnA -17.5 V ~ VIN 0.1 rnA VIN = -23 V. 1 rnA ~ 10 ~ 40 rnA jJV rrns ~ -30 V.lo ~40 rnA TI = 25°C. 10 Hz ~ f ~ 100 kHz d8 f = 120 Hz. -18.5 V ~ VIN TJ = 25°C V TJ = 25°C rnA TJ = 25°C. VIN = -30 V rnA TJ = 25°C rnV/oC 10 = 5 rnA ~ -28.5 V. t-IEC NEe Electronics Inc. pPC79MOO SERIES THREE·TERMINAL 0.5 A NEGATIVE VOLTAGE REGULATORS PRELIMINARY INFORMATION Description Pin Configuration The tlPC79MOO series is comprised of five monolithic three terminal negative voltage regulators that employ current limiting, thermal shutdown, and output transistor safe area protection. They are intended as fixed voltage regulators in a wide range of applications, including local or on-card regulation forelimination of noise and distribution problems associated with singlepoint regulation. Five output voltages are available: -5, -8, -12, -15, and -24 volts. NEe 79MOO Features D D D D ~Input o 1 3 2 /t"'- Output current up to 500 mA Internal thermal overload protection Internal short circuit current limiting Low noise GND Input Output 83-003119A Equivalent Circuit ~--~--~--~--~--------------------------------------~--~-oGND RS Ag '------+---__+----+-____________________ ~ ___ + - - - - - - - - - - _ + _______ __+~ Inpu' 83·0031208 5-45 ttlEC JlPC79MOO SERIES Ordering Information Part Number Absolute Maximum Ratings (TA = 25°C) Operating Temperature Range Package -35 V Input Voltage pPC79M05H SIP -20°C to +85°C Internal Power Oissipation pPC79M08H SIP -20°C to +85°C Operating Ambient Temperature 20 W (Note I) -20 to +85°C pPC79MI2H SIP -20°C to +85°C Storage Temperature pPC79MI5H SIP -20°C to +85 °C Junction to Case Thermal Resistance 4.0°C/W -20°C to +85 °C Junction to Air Thermal Resistance 83°C/W pPC79MI8H SIP Note: (1) Output automatically turns off if TJ > 150°C. Comment: Stresses above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress Recommended Operating Conditions Parameter Symbol Type Number rating only and functional operation of the device at these or any Limits Min. Typ. Max. Unit --------'-----:c:==-~--'':':_-::::_--pPC79M05 -7 -10 -25 Input Voltage Output Current Operating Junction Temperature VIN pPC79M08 -10.5 -14 -25 pPC79MI2 -14.5 -19 -30 pPC79MI5 -17.5 -23 -30 pPC79M24 -27 -38 -33 -55 to +150°C other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. v 10 All 5 350 mA TJ All -20 125 °C Electrical Characteristics - JlPC79M05 VIN = -10 V, 10 = 350 mA, ooe s TJ s 125°e Limits Parameter Output Voltage Symbol Vo Min. Typ. Unit -5.2 V TJ = 25°C -5.25 V -7 V 0; VIN 0; -25 V. 5 mA 0; 10 0; 350 mA 7.0 50 mV TJ = 25°C. -7 V 0; VIN 0; -25 V 3.0 30 mV TJ = 25°C, -8 V 0; VIN 0; -18 V 30 100 mV TJ = 25°C, 5 mA 0; 10 0; 500 mA mV TJ = 25°C, 5 mA 0; 10 0; 350 mA -4.8 -4.75 Line Regulation REGIN load Regulation REGL Quiescent Current IBIAS Quiescent Current Change Output Noise Voltage 20 4.2 t:dBIAS 100 VN 54 Ripple Rejection 6.0 mA TJ = 25°C 0.5 mA -8 V 0; VIN 0.4 mA 5 mA 0; 10 0; 350 mA 200 pV rms 60 d8 0; -25 mA TJ = 25°C, f = 10 Hz to 100 kHz d8 TJ = 25°C -8 V 0; VIN f=120Hz TJ=25°C RR 50 Oropout Voltage Test Conditions Max. 10 = 300 mA 0; -18 V, VOIF 1.1 V Short Circuit Current 10SHORT 400 mA TJ = 25°C. VIN = -25 V Peak Output Current 10PEAK mA TJ = 25°C Output Voltage Drift MoiL':. T mV/oC 10 = 5 mA 5-46 620 800 0.4 1020 10=100mA ftt{EC JlPC79MOO SERIES Electrical Characteristics - pPC79M08 VIN = -14 V, 10 = 350 mA, OOG:O; TJ:O; 125°G Limits Parameter Outpul Voltage line Regulation load Regulation Quiescent Current Quiescenl Current Change OutpUI Noise Voltage Symbol Vo Typ. Max. Unit -7.7 -8.0 -8.3 V TJ=25'C -8.4 V -10.5 V::; VIN::; -25 V. 5 rnA ::; 10 ::; 350 rnA 8.0 80 rnV TJ = 25'C. -10.5 V::; VIN::; -25 V 4.0 50 rnV TJ = 25'C, -II V::; VIN ::; -21 V 30 160 rnV TJ = 25'C. 5 rnA::; 10::; 500 rnA rnV TJ = 25'C, 5 rnA::; 10::; 350 rnA -7.6 REGIN REGL 20 4.2 IBIAS L':.IBIA8 110 VN 54 Ripple Rejection RR Dropout Voltage VOIF 6.0 rnA TJ = 25'C 0.5 rnA -10.5 V::; VIN ::; -25 rnA 0.4 rnA 5 rnA::; 10::;350 rnA 220 pV rrns dB 60 50 Short Circuit Current 108HORT Peak Output Current 10PEAK Output Voltage Drift L':.Vo/L':.J Test Conditions Min. 1.1 400 620 800 1020 0.6 TJ = 25'C, 1= 10 Hz to 100 kHz dB TJ = 25'C -11 V::; VIN ::; -21.5 V. 1=120Hz V TJ=25'C rnA TJ = 25'C. VIN = -25 V rnA TJ = 25'C rnV/'C 10 = 5 rnA 10 = 300 rnA 10= 100 rnA IJ Electrical Characteristics - pPC79M12 VIN = -19 V, 10 = 350 mA, OOG:O; TJ:O; 125°G Limits Parameter Output Voltage line Regulation load Regulation Quiescent Current Quiescent Current Change Output Noise Voltage Symbol Vo Test Conditions Min. Typ. Max. Unit -11.5 -12.0 -12.5 V TJ = 25'C -12.6 V -14 V::;VIN::;-30 V, 5 rnA::;10::;350 rnA -11.4 REGIN REGL 9.0 80 rnV TJ = 25'C. -14.5 V::; VIN::; -30 V 5.0 50 rnV TJ = 25'C, -15 V::; VIN::; -25 V 30 240 rnV TJ = 25'C. 5 rnA::; 10::; 500 rnA rnV TJ = 25'C, 5 rnA::; 10::; 350 rnA 6.0 rnA TJ = 25'C 0.5 rnA -14.5 V::; VIN::; -30 rnA 0.4 rnA 5 rnA ::; 10 ::; 350 rnA 280 pV rrns 20 4.2 IBIAS L':.IBIA8 140 UN 54 60 dB TJ = 25'C. 1= 10 Hz to 100 kHz Ripple Rejection RR dB TJ = 25'C -15V::;VIN::;-25V. 1=120Hz Dropout Voltage VDlF 1.1 V TJ = 25'C Short Circuit Current 108HORT 200 rnA TJ = 25'C, VIN = -30 V Peak Output Current 10PEAK rnA TJ = 25'C Output Voltage Drift L':.Vo/L':.T rnV/'C 10 = 5 rnA 50 620 800 0.8 1020 10 = 300 rnA 10= 100 rnA 5-47 t-{EC pPC79MOO SERIES Electrical Characteristics - pPC79M15 VIN = -23 V, 10 = 350 mA, O·C:::; TJ:::; 125·C Limits Parameter Output Voltage line Regulation Load Regulation Quiescent Current Quiescent Current Change Output Noise Voltage Symbol Vo Typ. Max. Unit -14.4 -15.0 -15.6 V TJ = 25°C -15.75 V -17.5 V 5 VIN 5 -30 V. 5 mA 5 10 5 350 mA -14.25 REGIN REGL 9.0 80 mV TJ = 25°C. -17.5 V5 VIN 5 -30 V 50 mV TJ = 25°C. -18 V 5 VIN 5 -28 V 30 240 mV TJ = 25°C, 5 mA 510 5 500 mA mV TJ = 25°C, 5 mA 510 5 350 mA 4.2 IBIAS L>IBIA8 180 VN 6.0 mA TJ = 25°C 0.5 mA -17.5 V5 VIN 5 -30 mA 0.4 mA 5mA5105350mA 360 pVrms d8 60 VOIF 1.1 Short Circuit Current 108HORT 200 Peak Output Current 10PEAK Output Voltage Drift Mo/M 620 800 1020 1.0 TJ = 25°C, f = 10 Hz to 100 kHz d8 TJ = 25°C 10 = 300 mA -18.5 V5 VIN 5 -28.5 V. 10=100mA f= 120Hz V TJ = 25°C mA TJ = 25°C, VIN = -30 V mA TJ = 25°C mV/oC 10 = 5 mA RR 50 Dropout Voltage Conditions 7.0 20 54 Ripple Rejection T~~t Min. Electrical Characteristics - pPC79M24 VIN = -33 V, 10 = 350 mA, O·C:::; T J :::; 125°C Limits Parameter Output Voltage Line Regulation Symbol Vo REGL Quiescent Current 181AS Quiescent Current Change Output Noise Voltage Typ. Max. Unit -23.0 -24.0 -25.0 V TJ = 25°C V -27 V5 VIN 5 -38 V. 5mA5105350mA -22.8 REGIN Load Regulation -25.2 9.0 80 mV TJ = 25°C. -27 V5 VIN 5 -38 V 5.0 50 mV TJ = 25°C. -30 V5 VIN 5 -36 V 30 360 mV TJ = 25°C. 5 mA 510 5 500 mA mV TJ = 25°C. 5 mA 510 5 350 mA 20 4.2 L>IBIA8 300 VN 54 Ripple Rejection RR Dropout Voltage VOIF 6.0 mA TJ = 25°C 0.5 mA -27 V 5 VIN 5 -38 mA 0.4 mA 5mA5105350mA 600 pVrms dB 59 50 Short Circuit Current 108HORT Peak Output Current 10PEAK Output Voltage Drift L>VoI L> T 5-48 Test Conditions Min. 1.1 10 620 800 1.4 1020 TJ = 25°C. f = 10 Hz to 100 kHz dB TJ = 25°C -28 V 5 VIN 5 -38 V. f = 120 Hz V TJ = 25°C mA TJ = 25°C. VIN = -38 V mA TJ = 25°C mV/oC 10 = 5 mA 10 = 300 mA 10=100mA NEe pPC79MOO SERIES Typical Connection Input O--~r---l 1---..---0 Output COUT CIN: 0.1 to 0.47 ,uF; required if regulator is located an appreciable distance from power supply filter. COUT: 20.22 tJF [recommended mylar capacitor]. 83·003121A 5-49 pPC79MOO SERIES 5-50 t-IEC ttiEC JlPC7900 SERIES THREE-TERMINAL 1.0 A NEGATIVE VOLTAGE REGULATORS NEe Electronics Inc. Description Pin Configuration The tlPC7900 series of three terminal regulators are monolithic negative voltage regulators which feature internal current limiting and thermal shutdown. They are intended for use as fixed voltage regulators in a wide range of applications, including local on-card regulators where distribution with single point regulation is a problem. 1 3 2 Features o o o o It\ Gnd Input Output Output current in excess of 1.0 A No external components required Internal thermal overload protection Internal short circuit current limiting 83-002523A Equivalent Circuit Gnd R, R23 ~o, ~/' ~ ~ .. 0, ~ R20,/. V R24,J. ~ 0, 011 '-t rK" R, jFJ ~ Va" "'"I I R20 ~-K I I I 0, 0, VI'., ;k 11 I I I R, Va" 012 1 -~ Yo" ....... R12 h< _ ..J '® R, ----K R, 0,,>- L- ....... 016 019~ - ~ O. 0, ....... ,¥1 Ivo ........ ~' L- ....... 015 R, R, 0" rK" R" C, T Note· A B - 5 V to -8 V Options -2Vto-24VOptiOns R19 ~j I- 014rK" R, R, ul ....... 020 ~ R11 - ~ ~ 0, R18 C, :3- 0 18 R16 R" Ru R" 3 Input (fin) 83-002537C 5-51 fttIEC J.IPC7900 SERIES Typical Application Ordering Information Part Number Package Operating Temperature Range /JPC7905H Plastic SIP -20°C to +80°C /JPC7908H Plastic SIP -20°C to +80°C /JPC7912H Plastic SIP -20°C to +80°C /JPC7915H Plastic SIP -20°C to +80°C /JPC7918H Plastic SIP -20°C to +80°C /JPC7924H Plastic SIP -20°C to +80°C tJ PC79XX Input Output c, c, (1) 0.33"F (2) more than O.3311F Notes: (1) Mylar film type capacitors are Absolute Maximum Ratings Input Voltage (pPC7905/08/12115/1 8) -35 V Input Voltage (pPC7924) -40 V Intarnal Power Dissipation Inlernally Limited recommended. (2) Required If regulator Is located an appreciable distance from power supply filter. 83-002539A Operating Temperature Range Storage Temperature Range -55 to +150°C Operating Junction Temperature Range -20 to 125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics - tJPC7905 = -10 V, 10 = -SOD mA, DOG::; TJ::; 12soG VIN Limits Parameter Output Voltage Symbol Vo Min. Typ. load Regulation OU188G8nt Current Ouleacent Current Change -5.25 V -7 V:s VIN:S -20 V. -5 mA:s 10:S -1.0 A. PT:S 15 W 100 mV TJ = 25'C. -7 V:s VIN:S -25 V 50 mV TJ = 25'C. -8 V:s VIN:S -12 V REGIN .............................................................................. REGl ..••....•. ~~ ...... I.~O.....• ~~ •.•. ~J.':". ~~~~ . -:-.5.~~.~.19.~.-:-.1:~~ •.•..•.•••.•..•••••• 20 80 mV TJ 25°C. -250 mA:S 10 :S -750 mA IBIAS t.IBIAS = = 25°C 1.3 mA -7 V:s VIN :s -25 V .............................................................................. 1.0 2.0 0.5 Output Noise Voltage Ripple Re)ectlon VN RR Dropout Voltage 54 mA mA 100 pVRMS TJ -5 mA :S 10 :S -1.0 A TA = 25°C. 10 Hz:S f:S 100 kHz 62 dB f = 120 Hz. -8 V:s VIN:S -18 V.lo = -500 mA 1.1 V 10 = -1.0 A. TJ = 25°C TJ Peak Output Current IOPEAK -2.1 A Output Voltage Drift t.VOI t.T -0.4 mVrC S-S2 Test Conditions Unit .. -:-~:8.... -:-.5:~ .... :-:~.~ ......V .....~J. ':". ~~~~ ..................................... . -4.75 line Regulation Max. = 25°C 10 = -5 mAo O°C:S TJ:S 125°C NEe pPC7900 SERIES Electrical Characteristics - tlPC7908 = -14 V, 10 = -500 rnA, O°C ~ TJ ~ 125°C VIN Limits Parameter OUlpul VOllage Symbol Vo Min. Typ. Max. Test Conditions Unit · .-:-!:7.... -:-.8:~ .... :-:~.~ ......V .....~J.~. ~~:~ ..................................... . -7.6 -8.4 V -10.5 V,,; VIN oS -23 V. -5 mA oS 10 oS -1.0 A, PT oS 15 W 6.0 160 mV TJ = 25°C, -10.5 V oS VIN oS -25 V 2.0 80 Line Regulalion REGIN .............................................................................. Load Regulallon REGL · ......... ~~ ...... ~~~ ..... ~~ .... ~J.~. ~~:~'. Oulescenl Currenl Oulescent Current Change IBIAS 100 mV TJ = 25°C, -250 mA,s; 10,s; -750 mA 1.0 2.0 mA TJ = 25°C AIBIAS 0.5 Output Noise Voltage VN Ripple Rejection RR 54 Dropout Voltage -:-.5. ~~.:;;.I~.:;;. -:-.1:~ ~................... . 30 mA 200 /lVRMS 62 dB 1.1 V Peak Output Current 10PEAK -2.1 A Output VOllage Drift AVO/AT -0.6 mY/DC -5 mA ,s; 10 ,s; -1.0 A TA = 25°C, 10 Hz,s; f ,s; 100 kHz f = 120 Hz, -11.5 VoS VIN oS -21.5 V.IO = -500 mA = -1.0 A. TJ = 25°C = 25°C 10 = -5 mAo o°c,s; TJ,s; 125°C to TJ Electrical Characteristics - tlPC7912 ~ 125°C VIN = -19 V, 10 = -500 rnA, O°C ~ TJ limits Parameter Output Voltage Symbol Vo Min. Typ. Max. Test Conditions Unit · :-:1.1:~ .••-:-~~.~ .•.• -:-.1~:5•.... -11.4 -12.6 V Y.... .~J.~. ~~:~ •..•....••........••.••...••...••..•.. 10 240 mV -14 V oS VIN oS -27 V. -5 mA oS 10 oS -1.0 A. PT oS 15 W TJ = 25°C. -14.5 V oS VIN oS -30 V Line Regulation REGIN .............................................................................. Load Regulallon REGL · ......... ~~ ...... ~~~ ..... ~~ .... ~J.~. ~~:~,. ~~.:;;.I~.:;;. -:-.1:~~ 30 120 mV TJ = 25°C. -250 mA,s; 10,s; -750 mA Oulescenl Current IBIAS Oulescenl Current Changa AIBIAS Output Noise Voltage VN Ripple Rejecllon RR Dropout Voltage Peek Output Current 10PEAK Output Vollag8 Drill t..VO/t..T -:-.5. 1.5 3.0 mA ................... . TJ = 25°C 1.0 mA -14.5 V oS VIN oS -30 V .............................................................................. 0.5 54 mA 300 /lVRMS -5 mA ,s; 10 ,s; -1.0 A TA = 25°C, 10 Hz,s; f,s; 100 kHz 62 dB 1.1 V f = 120 Hz, -15 V oS VIN oS -25 V, 10 = -500 mA 10 = -1.0 A. TJ -2.1 A TJ = 25°C = 25°C o.e 5-53 fttIEC pPC7900 SERIES Electrical Characteristics - pPC7915 VIN = -23 V, 10 = -500 mA, OOG:S; TJ:S; 125°G Limits i'arameter Oulpul Vollage Symbol Vo Min. Typ. REGL Quiescenl Currenl Change V -17.5 V:s VIN:S -30 V. -5 rnA:s 10:S -1.0 A. PT:S 15 W 150 rnV TJ = 25'C. -20 V:S VIN:S -26 V .......... ~~ ...... ~~O...... ~~ ....~J. ':". ~~~~'. -:-.5. ~~.~.Ip.~. -:-.1:~~................... . 30 Quiescenl Currenl -15.75 REGIN 3.0 Load Regulalion Tost Conditions Unit -14.4 -15.0 -15.6 V TJ = 25°C .............................................................................. -14.25 line Regulation Max. 150 mV TJ = 25°C. -250 rnA :s; 10 :S -750 rnA 1.5 IBIAS AIBIAS 0.5 Oulpul Noise Vollage VN Ripple Rejection RR 54 Dropoul Vollage rnA 375 IlVRMS 60 dB -5 rnA :S 10 :S -1.0 A TA = 25°C. 10 Hz:S f:S 100 kHz , = 120 Hz. -18.5 V:s VIN :s -28.5 V. 10 = -500 rnA = -1.0 A. TJ = 25°C = 25°C 10 = -5 rnA. O°C:S TJ:S 125°C 1.1 V 10 Peak OUlpul Currenl 10PEAK -2.1 A TJ Outpul Vollage Drift AVO/AT -1.0 rnVI'C Electrical Characteristics - pPC7918 VIN = -27 V, 10 = -500 mA, OOG:S; TJ :::; 125°G Limits Paramoto, Symbol Min. Typ. Max. Tost Conditions Unit OUlpul Vollage Vo . :-:1.~.~ ...-:-~~.~ .... -:-.1~:7.....•V.....~J. ':". ~~~~ ........•........•......•.•........... -17.1 -18.9 V -21 V:SVIN:s-33V.-5rnA:Slo:S-1.0A.PT:S15W line Regulalion REGIN 15 360 rnV TJ = 25'C. -21 V:S VIN:S -33 V .............................................................................. Load Regulalion REGL Quiescenl Currenl IBIAS Quiescenl Currenl Change AIBIAS 5.0 180 rnV TJ = 25'C. -24 v:s VIN:S -30 V 90 360 rnV TJ = 25°C. -5 rnA:S 10:S -1.5 A 30 180 rnV TJ = 25°C. -250 rnA:S 10:S -750 rnA 1.5 3.0 rnA TJ = 25°C 1.0 rnA .............................................................................. -21 V:s VIN :s -33 V .............................................................................. 0.5 Oulpul Noise Voltage VN Ripple Rejeclion RR 54 rnA 450 Il VRMS 60 dB Peak OUlpul Current 10PEAK -2.1 A OUlput Vollage Drift AVO/AT -1.0 rnV/oC 5-54 TA = 25°C. 10 Hz:S f:S 100 kHz f = 120 Hz. -22 V:s VIN:S -32 V.lo 10 = -1.0 A. TJ 1.1 Dropoul Voltage -5 rnA :S 10 :S -1.0 A = 25°C = 25°C 10 = -5 rnA. O°C:S TJ:S 125°C TJ = -500 rnA t-IEC pPC7900 SERIES Electrical Characteristics - pPC7924 = -33 V, 10 = -500 rnA, O°C:S TJ:S 125°C VIN Limita Symbol Parameter OuipUi Voll_gl Typ. Min. Max. Test Conditions Unit . :-:~~.~ ...~~~.~....-:-~~:O......~ ....~J.~. ~~:~ ..................................... . Vo -22.8 -25.2 V 18 480 rnV 6 240 rnV -27 V:s VIN :s -38 V, -5 rnA :s 10 :s -1.0 A REGIN TJ = 25°C. -27 V:s VIN:S -38 V .............................................................................. lOld Ragulilion REGl ••.••••••• ~~ •••••• ~~O•.•••• ~~ ..••~e ~~:~ -:-.5. ~~.:;;.I~.:;;.-:-.I:~~ ••••••.•••••••.••••• 240 rnV TJ = 25°C. -250 rnA:5 10:5 -750 rnA 30 QuilSC8tll Currenl IBIAS lina Rlgul8110n Qull.CaoI Currenl Chlngl . = 25°C .............................................................................. 1.5 AIBIAS OuljlUl Nolsa VOItlgI VN Ripple RajeClion RR TJ = 25°C. -30 V:s VIN:S -36 V 3.0 rnA TJ 1.0 rnA -27 V:s VIN :s -38 V 0.5 51 Dropoul Vollag. rnA 600 pVRMS -5 rnA:510:5-1.0A TA = 25°C. 10 Hz:5 1:5 100 kHz 1= 120 Hz. -28 V:s VIN:S -38 V.lo = -500 rnA 59 dB 1.1 V 10 = -1.0 A. TJ TJ Palk OuipUi Curranl 10PEAK -2.1 A Output Voltage Orift AVO/AT -1.0 rnVrC = 25°C = 25°C 10 = -5 rnA. O°C:5 TJ:5 125°C Operating Characteristics TA = 25°C II Current Limiting Characteristics Power Dissipation vs. Ambient Temperature -6 100 50 ---_/ /8HS 10 5.0 2.0 ;:>< X ~ - --- ~ 0.5 0.2 ....... 50 75 -4 .......... -2 "\., .......... 100 Ambient Temperature (Oe ) I -3 ,-' 0.1 25 10°C/W No Heat Sink '\ // 1.0 -5 'HS~O / 20 / 10 V V, tlPC790SH TJ = 25°C ./1 1 " ~ 125 0.4 0.8 1.2 I--"'" 1.• 2.0 Output Current (A) 5-55 t-IEC pPC7900 SERIES Operating Characteristics (Cont.) TA = 25°C Peak Output Current as a Function of Input/Output Differential Voltage Load Transient Response -2.5 ::11 I flll111 -2.0 .......... .......... -1.5 TJ = 25"C 0.5 ........ TJ -1.0 125°C ........... ....... "- I~ -0.5 . . . . r-..... o o 10 15 Input~Output Differential {V} 20 -0.5 "-....I" r-. 25 t--- VI = -10 V < }JPC7905H ~ 2 r---rO~1 30 20 40 10 pPC7905H V, 10 V '0 100mA TJ 25"C CI Co = 0 1.0 V 0.1 ~ TJ = 25°C o 20 IlPC7905 60 40 Time (psI 5-56 100 Output Impedance as a Function of Frequency ::jj ~ 11111 ~ I ! =1-- 200 TmA 80 60 Time (tis) Line Transient Response 1--10 j 80 ~ 100 0.01 10 100 1k Frequency (Hz) 10 k 100 t\fEC DIA AND AID CONVERTERS 6-A II CONVERTERS t\fEC Section 6 - DI A and AID Converters Digital-to-Analog pPC603 6-Bit High-Performance D/A Converter ...................................... 6-1 pPC610 10-Bit Polarized 01 A Converter ............................... . . . . . . . . . . . . .. 6-9 pPC624 8-Bit High-Speed Multiplying D/A Converter ............................... 6-17 pPC601212-Bit High-Speed Multiplying DIA Converter............................. 6-27 pPD6900 8-Bit CMOS Video DIA Converter ........................................ 6-35 pPD7011 8-Bit NMOS 01 A Converter .............................................. 6-39 Analog-to- Digital pPD6950 pPD7001 pPD7002 pPD7003 pPD7004 6-B 8-Bit CMOS Video AID Converter ........................................ 8-Bit CMOS Serial Output AID Converter ................................. 10-Bit CMOS Integrating AID Converter .................................. 8-Bit CMOS High-Speed AID Converter .................................. 10-Bit CMOS Successive Approximation AID Converter ................... 6-45 6-51 6-59 6-69 6-75 t-IEC pPC603 6·BIT HIGH· PERFORMANCE NEe Electronics Inc. D/A CONVERTER Description Pin Configuration The tlPC603 is a monolithic digital-to-analog converter designed to convert 6-bit binary coded decimal signals to an analog output voltage signal. The reference voltage, weighted current source, current switch, and output op-amp, are all integrated on board the device. MSB Features Ordering Information Part Number Package pPC603D Ceramic DIP Operating Temperature Range = 25°C Voltage Between V+ and VPower Dissipation Input Voltage Output Short Circuit Duration Operating Temperature Range Storage Temperalure Range 3rd Bipolar/Unipolar 4th Current Adder lSB v+ F.S. Range Setting GND Analog Output 83-002364A Pin Identification Pin Name Function MSB Oala Bit I 2 2nd Oala Bit 2 3 3rd Data Bit 3 4 41h Dala Bit 4 5 51h Oala 8it 5 LSB Oala Bit 6 V+ Power Supply Positive Analog Output Absolute Maximum Ratings TA V~ 5th D Linearity error: 0.4% (1 14 LSB of 6-bit) max D Response speed: 3 tls max D Temperature coefficient at full speed: 160 ppm/oC max D Input level TTL, OTL level, active low D The output voltage range can be applied to any of the 3 following ranges: 0 to 10 V, -5 to +5 V, -10 to +10 V D Built-in output short-circuit protection D Possesses a linearity equivalent to that of a 7 -bit converter, and can be used as a 7-bit O/A converter by the addition of external circuits D Pin-for-pin compatible with PMI's "OAC-01 Coo F.S. Adjust 2nd ±18 V 500 mW -0.7 to +6 V Indefinite -20 to +80°C 9 Ground Power Supply Ground 10 F.S. Range Full Scale Range Selling II Currenl Adder BipolarIUnipolar Control 12 BipolarIUnipolar 13 V- Power Supply Negative 14 F.S. Adj. Full Scale Adjusl -55 to +150°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device atthese or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 6-1 ttiEC tJPC603 Equivalent Circuit MSB 2nd 3rd 4th 5th LSB v+ Current Scale Adder Setting t6k 16k 14 F.S. Adjust 13 v- 12 Bipolar/Unipolar GND 63-0023'638 6-2 NEe pPC803 Electrical Characteristics TA = +25°C, V± = ±15 V Limits Parameter Llnaarlty Error Symbol Min. Typ. Max. Tlst Co.dltlon. Unit NL 0.4 %FSR Fig. 1. 2, 3 ......................................................................................... 0.45 Full Scala Tamperature Coefflclant (Nota 21 80 160 %FSR Fig. I. 2, 3; TA = -20 to +80°C ppm/DC Fig. I aach bit "ON" altar FS adlust TA = -20 to +80°C FSR Analog Output Ollsat Voltlga; ~~I~!I~~ ••••••.•••••••••••••••.••••••••••••.•••••.•••••••~5•••••• ~~ ••••F!~ .• I. ~~c.h. ~I! :'~~~". ~~t~~~t.~S. ~~I~~I.~~ :=.:-~"~ ~~O:.C•••• Bipolar (Nota 31 50 mV Fig. 2; ±5 Voutput without FS adlust ......................................................................................... 100 Low Laval Input Voltaga (Notl 41 VIL High Laval Input Voltaga (Notl 41 VIN Input Tarminal Currant liN 0.5 mV Fig. 3; ± 10 V output wlt~oul FS adlust V Bit "ON" V 2.1 5.0 pA Bit "OFF" oV:5 VIN :5 5 V Analog Output FS Voltage; ~~I~~I~~ ••••••••••••••••••••.•.••••••• ::~ ~.~~•••••••••••:-!! :7.~ ....V•••••~L. ~ ~ .~'? .~I~ .. ~;. ~~t~~U! .F~. ~d!~~ .••••••••••••••••••• Bipolar V ........... '+4.93 :'5:94 ........... +5.94 ':':4'.93 •••• it· .. Fig. 2; ±5 V rlnga; RL = 2 kO without oHsatldlusllnd FS adjust ......................................................................................... +9.86 +11.89 V ........... :.: i i.iil" ......... ':"·9·.86 .... II'" Supply Voltage Ralaction Ratio SVRR 0.15 Fig. 3; ±IO V rangl; RL =2 kO wilhout ollsatad/ustlnd FS adlust %FSR/V ±12 V:5 V±:5 ±18 V Settling Tima (Nota 51 TS 3 /IS Powar Consumption Po 250 mW Error $ ';' LSB. RL = 5 kn. CL = 30 pF Notes; 1. %FSR and ppm FSR are the percentage and parts per million against full scale. respectively. 2. The average value of the differential coefficient at TC = -20 to +80°C. 3. Care should be taken, since the temperature drift after bipolar offset adjustment has been made will become larger for ICs in which the offset voltage of the bipolar analog output is larger than the LSB value. 4. The input is active "Low." 5. When the load capacitance exceeds 30 pF there is a possibility of oscillation. 6-3 II t-IEC jlPC603 Typical Applications Bipolar Operation (2), -10 V to + 10 V Output Unipolar Operation, Output 0 to 10 V Range Bipolar Offset -15V o-~--T--' 0.01 1 -15V 500 o---..----..-t---¥IAr-----Q +15V 0.01 Analog Output 1 lOOk Analog Output 500 1M Va F.S. Adjust +15V +15V A 0 C (MSB) A (LSB) C 0 (MSB) Example Input 111111 100000 011111 000000 Digital Input 6 Bit Binary Code Active Low Input 6 Bit Offset Binary code Active Low Output 0.00 V 4.92 V 5.08 V 10.00V F (LSB) Example Output Input 111111 = -10.00 V -0.16V 100000 011111 ~ +0.16 V +10.00 V 000000 83-002367A 83-002365A Compensation against Capacitive Loads (1) Bipolar Operation (1), Output -5 V to +5 V Range Bipolar Offset -15V o-~--~~'---¥>h------Q +15V 0.01 T rh 500 Analog Output 1M Va 11 IlPC603D A (MSB) B C 0 o (LSB) o Digital Input 6 Bit Offset Binary code Active Low Example Input 111111 100000 "'i 011111 "'i 090000 Output -5.00 V -0.08 V +0.08 V +5.00 V 83-002366A 6-4 The Ie is stable against capacitive loads of less than 100 pF. Care should be taken, since the settling time will increase to about 5 fiS. 83-002368A NEe pPC603 Typical Applications (Cont.) Operating Characteristics Compensation against Capacitive Loads (2) Output Response (1) +15V 5k +LSB l ""\ 10 IS953 ,------+---+-0 Qulpul II u -L!!.S a -i. -2LSB - .A/ y / " « I IS953 10 Tlme(pS) ~PC603D 5k -15V o o Output Response (2) This method can be applied only to the 0 to 10 V and ±5 V output ranges. It Is possible to connect such operational amplifiers as pPC318 etc. to the 8 pin as a voltage follower. 83-002369A 10 1-BIt DIA Converter -15V / J \ j \ / 3M lOOk IS953 10 15953 IS953 IS953 Analog 0 utput Time (,us) ? ? ? ? ? r-<' I. 13 12 11 10 9 8 6 7 ,uPC603D 1 MSBA B I 2 I 3 • 5 Glitch Waveform at 1/2 Scale 6 c o 100000 E 4.92 LSB G 0- 'S & -2LSB !:I O~ o The linearity error can be reduced by adjusting the o ~ 3 MO resistor. The output voltage may be set to any of the 3 ranges, with the circuits of figure " 2 and 3. I I II , 011111 I 1/ Y -4LSB I I II 10 83-G02370A Time(JlS) 6-5 NEe pPC603 Application Circuit. Progressive comparison type AID converter Input utput : Oto 10V o : 6-blt straight binary -15Y~ J b (parallel, serial) 14 n 13 12 11 I 10 9 8 6 7 .PC603D 1 2 3 5 4 -- D-FF -- T -T ...Ee.!!... r-T -TA .A ....... D-FF ....... ! eli' .A ....... D-FF r-T eli I - .A ....... ~D D-FF D-FF -T f Sample/Hold A Lr:-:- L:-:~ L:-:r- Lr:-:~ L:-:rD-FF 0-IOY Hold -=t?~_r A -- Analog Input Sample and L....o+15V I A ... ---1 or- r-T T -T- ..A .A ....... -r-- ....... - -r- II 0, O2 Qa 0 4 Os Os 0 7 0- I a. J, ... Latch CI_ 8..Blt Ring Counter 0, ... J. J. J, 0, 0, II-BH Latch Enable Q. 0, 0, 666 6 6 6 Straight Binary Straight Binary Serl.. Output MSB Note: DaFF I, an Edge Trigger Type LSB Series Output 83-002375C 6-6 ttiEC JiPC603 Application Circuits (Cont.) Tracking type AID converter Input Output Oto 10V 6-bit straight binary -15V Analog Inpul J --:h [ 1°·01 I. n 13 12 11 I 10 9 8 5 6 7 L$" MPC6030 1 2 • 3 E,+15V l°.o1 >.~ ~~ >. ~ +-a, a, a. a, a, a, Up Down Counter Clock JlJ1....o-J II UP/DOWN I Clock LSB MSB Straight Binary Output 83-0016788 6-7 /lPC603 • 6-8 NEe t-IEC JlPC610 10·BIT POLARIZED D/A CONVERTER NEe Electronics Inc. Pin Configuration Description The tJPC610 is a high performance precision monolithic digital-to-analog converter which converts 10-bit binary coded digital signals to an analog DC output voltage. All of the necessary circuit blocks are incorporated on board the converter to make designing simple. With the built-in voltage reference and reference input, multiplier operation is also possible. MSB Sign Bit 2nd Reference Output 3,d v+ 4th Reference Input 5th Output 6th Analog GND Features 7th v- 6th Digital GND 9th ~ _ _ _---.r- LSB D Full Scale Temperature: 100 ppm/ °C max D Linearity error: 0.2% (1 /2 LSB of 8th bit) max 83-002377A D Settling Time: 1.5 tJs typ Pin Identification D Built-in band-gap reference voltage source D Multiplying type Pin D Sign-Magnitude binary code D Low noise D Low power dissipation Name Function MS8 Data Bit 1 2nd Data 8it 2 3rd Data 8it 3 4th Data Bit 4 5th 6th Data Bit 5 7th Data Bit 7 8th Data Bit B 9th Data Bit 9 10 LSB Data Bit 10 ±18 V 11 Digital Ground Power Dissipation 500 mW 12 V- Supply Analog Ground to Digital Ground ±0.5 V 13 Analog Ground -5to +15 V 14 VOUT - Output oto +7 V 15 Relerence Input Ordering Information Part Number Package pPC6100 Ceramic DIP 4 Operating Temperature Range Absolute Maximum Ratings TA = 25°C Voltage Between V+ and V- Logic Input Voltage Relerence Input Voltage Relerence Voltage Source Output Current Output Short Circuit Duration Operating Temperature Range Storage Temperature Range 1.0 mA 16 V+ Supply Indelinite 17 Reference Output -20 to +BO°C 18 Sign Bit Data Bit 6 II Power Supply Negative Voltage Output Power Supply Positive Sign + or- -55 to +150°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device atthese or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 6-9 NEe pPC610 Equivalent Circuit ~ + > :£ ~ l' ~I - ~ I~\ , + f---o f---o - ~~ ~ f---o - f---o~L -~ - ~~L f---o - --o~ - ~~ f---o - f---o~L - ~~1. ~ ~ >--0 w ~ - r=o ~ ~ M >--0 N ~ ---o~ I J I~ i.\ ~ ~ - ~b ~ ; 83-002376C 6-10 ttiEC IlPC61 0 Electrical Characteristics v± = TA = +25°C, +15 V Limits Symbol Parameter Min. Typ. Test Conditions Unit Max. II Bil Bipolar Operalion ......................................................................................... Resolulion (Nole I) 10 Bil linearlly Error (Nole I) NL 0.1 0.2 O/OFSR Unipolar Operalion Sellling Time TS 1.5 6.0 ps TA = -20 - +80°C Final Value ±20 mV 50 100 ppmfO C Using inlernal reference vollage source .............................................................................. Full Scale Temperalure Coefficienl (Nole 2) 30 60 Relerence Inpul Bias Currenl liS 100 500 Reference Inpul Slew Rale SR 1.5 nA Vips 2.4 2.6 V RL 2 20 kO Zero Scale Offsel Vollage ±5 ±IO mV Signbil "ON", olher bils "OFF" Zero Scale Offsel Symmelry ±I ±5 mV Full Scale OUlput Offset ±IO ±80 mV 0.015 0.15 Reference Vollage VREF Supply Voltage Rejeclion Ratio 2.2 ppmloC Using exlernal reference voltage source SVRR GfoFSR/V ±12 V:5 V±:5 ±18 V Power Dissipation Po 300 mW Logic Input Terminal Currenl liN 10 pA High Levelinpul Vollage (Nole 3) VIH 0.8 Low Levellnpul Vollage (Note 3) Full Scale OutpUI Voltage (Note 4) VtN = -5 V~ +15V V 2.0 11.0 -11.0 -10.0 V V All bils "ON". RL 2 2 kO .............................................................................. Vo 10.0 V Signbil "OFF", olher bils "ON". RL 2 2 kO Notes: 1. Though the IC possesses a resolution of 10 or 11 bits, the linearity error is equivalent to 9 bits. In applications where perfect monotonicity is expected, employ the IC as an a-bit D/A converter. 2. The average value of the differential coefficient at TA = -20'C to +80'C. 3. The digital input is active "High" binary code. 4. The value when the internal reference voltage is directly applied to the reference input terminals. Typical Characteristics (TA = 25°C) VREF - Vo+ Characteristic Digital Input Response Characteristics 15r------,------~-------.-------r------~ V± = ±15 v V±"" ±15V 10~------hr----~~~---4----~-+------~ :E ! a i 5~------~----~~~---4----~-+------~ 1~ o 5 II 10 Time (J-Is) t q 11 15 20 :E 10~----~------_+~~---+------~--~~~ I1 6 ~ 25 Reference Input Voltage (V) 6-11 II ~EC jlPC610 Typical Applications Typical Characteristics (Cont.) (TA = 25°C) Using internal reference voltage source VREF ~ Vo~ Characteristic Sign Bit LSB MSB . ~ -5 s'" g ,0- , 0 V+ Reference Input 10k -10 50k R, -150~------~------~--------~------~------~ Reference Inpul Voltage (VREF) Note: Use resistors with good stability for R1 and R2' o Reference Input Response Characteristic 0/ V 0 \ 5 / \. i1 I 1 I o m w • Time (>.(8) Sign Magnitude 1 1111111111 = = OV = OV 1111111111 = OV 0000000000 0000000000 / 83~OO2378A J u + 10-8it Binary code Sign ~ External reference and multiplier type Sign Bit MSB ~ LSB V+ Output Noise Voltage V± = :!:1S v 1Hz - 20Hz v- Digital GND Analog GND o Multiplying coefficient = = 4.4 V FS 4.4 X V REF • 2.2 X V REF . V MSB V LSa 2_2 X 2- 9 = = 2 sec 83-002379A 6-12 t-IEC J,lPC61 0 Application Circuits a-Bit + sign AID converter Successive approximation type (sheet 1 of 2) GND +15V -15V 10k 115V Input '-H- SDk ~r -f +5V V'N 0.01 ~ Sample Hold ht ~PC610D MSB Sign 5k ~ Vo Sample Command Bib LSB LSB -15V II r= '---- f-- ~2 0, 0, ~ ~ r ~ L~~ L~r- L~_ D-FF D-FF r-T "'-r- I I I 1 A "I ~ I r-T 1 A I I D-FF r-T D. T L -4 I I I I I I I I T D'T 1 I I I I I 0, I I I '1 I I I I I I I I I I I I I l Lrll r k'- I J D. s~7 ,- L:-:_ L~rD-FF D-FF -T r-T 1 T A A ~ ~ I "I A B C D E F G H 12-811 Ring Counter 6 CLOCK I I J I K L --0 I L Lat.h Enable B-BitRegister 666666666 Sign LSB MSB Output 83-OO2385C 6-13 NEe pPC610 Application Circuits (Cont.) + sign AID converter 8-bit Successive approximation type (sheet 2 of 2) CLOCK AII~ 8 C ______________________ ~~ ~~_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __ _ _ r_l~ __-,__________________________ __________~____________~r_l~______ ______________________________ _____ ~r_l~ ------------------------------------~~ v, c, c, c, -----~~======================~-> ~~================~=< c. c, SO ,W 1 1 V'IN FS V'N Vo V'IN FS/2 Note: D, VIN. V'IN and Vo show in case when an input equivalent to an output of "101110110". 6-14 W 1 1 1L..,:.0_ _ _ _ __ !\fEe J,lPC61 0 Application Circuits (Cont.) Peak detector (positive/negative) GND -15V Positive Input VIN +15V Negative CLOCK 0.01 10k f--H- 50k ~O1 '1 Comparator - pPC610 + OUT C.O. br>=D- LSB Sign MSB ~ t- UlO 0 1 0, ................... -e- +- ..... Q" 1O·Bit Up Down Binary Counter CLOCK CLEAR 6 Reset II LSB MSB Sign Digital Output Analog Output Va CLOCK C.O. V'N FS """"- Vo FS/2 --83-00238BC 6-15 pPC610 Precautions for Usage 1. To absorb surges and prevent oscillation, bypass the power supply terminals with a capacitor of 0.01 fJF. 2. To utilize the r.hl'lrar.leri<>lir.<> nf th'" "pr.~1nn in filII employ comp;n~nt~-~f g~~d-st~biiit/i~rth~ f~II~'~~;i~ adjustment resistor and the trimmer. 3. Since the settling time may increase or oscillation may occur in the case of capacitive loads, the fJPC610D should be used with load capacitance of 100 pF or less. 6-16 NEe 4. The output amplifier will saturate at: I VREFI 2: 3 V in the case of multiplier type operation. In this case the response time and power supply current will increase. 5. Since the reference potential inside the pPC610D is connected to the analog GND, common mode noise in regard to analog GND will present a direct error. Since analog GND and digital GND have independent circuits within the IC, these should be connected together outside the IC (if required). pPC624 a-BIT HIGH-SPEED MULTIPLYING D/A CONVERTER ttlEC NEe Electronics Inc. Pin Configuration Description ThepPC624 is a monolithic multiplying digital-to-analog converter designed for high speed performance and design/application flexibility. Advanced circuit design allows settling time of 85 ns. The outputs are high impedance dual complementary current types, which allow simple resistive loading, op-amp voltage conversion, and other configurations. The adjustable threshold logic input allows connection to all popular logic families. THRESHOLD CONTROL COMPo lOUT VR.' (-) v- VREF (+) lOUT v+ MSB LSB 2nd 7th 3rd 6th 4th 5th Features D D D D D D D 83-002390A Wide range multiplying capability Wide power supply range ±5 V to ±18 V High output impedance and compliance Variable logic threshold Direct interface to TTL, CMOS, PMOS Differential current outputs Pin to pin compatible with PMI'S DAC-08 Pin Identification Pin Name Function Threshold Control lOUT V- Current Output Current Output 5 lOUT MSa Data Bit 1 3 4 Ordering Information Power Supply Negative 6 2nd Data Bit 2 Package Operating Temperature Range 7 3rd Data Bit 3 pPC624C Plastic DIP -20°C 10 +70°C a 4th Data Bit 4 pPC6240 Ceramic DIP -20°C 10 +ao°c 9 5th Dati Bit 5 10 6th Data Bit 6 11 7th Data Bit 7 12 LSB Data Bit a 13 V+ Power Supply Positive 14 VREF+ Positive Reference Vollage 15 VREFCompensation Amp Compensetion Part Number Absolute Maximum Ratings TA = 25°C Supply Vollage Logic Inputs Logic Threshold Control Vollage Analog Currenl Outputs Relerence Inputs 36 V V- to (V- +36 VI V 10 V+ 4.2 mA V-IO V+ Relerence Inpul OIlierentlal Vollage ±18V Reference Input Currenl 5.0 mA Power Dissipation, 0 or C Package Operating Temperalure Range. 0 Package Operating Temperalure Range, C Package 16 II Negative Reference Voltage 500 mW -2010 +BO°C -2010 +70°C Storage Temperature Range, 0 Package -5510 +150°C Storage Temperature Range, C Package -5510 +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device atthese or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 6-17 t-IEC pPC624 Equivalent Circuit V+ VLC MSB 2nd 3rd 4th 5th 8th 7th LSB ,..----t-.,--+...,...---t-t--i-1r----t-.,--+...,...--t-.,.---F-OloUT ~~~~+_+_...,...~~--t_+_+~~~~~+_+-...,...4_4_--t-~F2~IOUT VRE' (+)Q:,14:+---t---+-----., VRE' (-)0;;15+---1 16 COMP V- 83-0023898 6-18 NEe JlPC624 Electrical Characteristics TA = +25°C, V± = ±15 V,IREF = 2.0 rnA Limlls Parameler S,mbol Rlsolution Monoloniclly Nonlinearity NL SeHling Tlma Full SClle Temperalurl Coeflicient TS Oulpul Volta.1 Compliance VOC IFS Full Scale Currlnl Full Scale Symmetry Zero Scale Onlll Currlnl IZS Oulpul Currenl Rlngl 10 Low Level Inpul Voltagl VIL Nigh Levellnpul Volta.1 Low Llvel Inpul Currenl VIN Nigh Levil Inpul Currlnl Logic Inpul Swing Logic Threshold Ringe IlL liN VIS Typ. Max. 8 8 8 BII 8 8 8 811 0.19 150 %FSR 85 10 50 ppmfOC +18 2.04 ±8.0 2.0 V mA pA pA ll.IFS::5'hLSB VREF = 10,000 V. R+REF = 5,000 kn 2.1 4.2 mA mA V = 5.0 V V- = 8.0 Via -18 V 0.8 V V VLC = 0 V. Bil "OFF" VLC = 0 V. Bil "ON" -2.0 -10 pA VLC = 0 V, VIN = -10 V10 +0.8 V 0.002 10 +18 pA V VLC = 0 V. VIN +13.5 -3 V pA VTH = VLC + 1.3 V -10 1.94 1.99 o o 0.2 2.0 2.0 Power Supply Curranl Unll ns 2.0 -10 -10 Relerence Bill Currenl Relerence Inpul Slew Rill Power Supply Voltagl Rejection Rilio TISI Mil. Condiliols ±v. LSB, RL ::5 50 n All blls ON/OFF = 2.0 V10 18 V ll.IREF/ll.T 4.0 8.0 mAlpi RREF ::5 200 n. Cc = 0 pF SVRR+ V 0.0003 0.01 %FSR/ ...•............•........•........... ~.....V:.=: .~.~!~ .1.8. ~ •. I.R.E.F. ':'.! .~~ ..................... . SVRR- V 0.002 0.01 %FSR/ % V- = -4.510 -18 V.IREF = I mA 1+ 2.5 3.8 mA -6.5 -7.8 mA .... j+.............. 2:4······ 3:8···· '~A'" •••. j-=-••.•••••••••• ·..:.6:4···· ''':'i:i''' '~A'" v+ ',;;5 it: it:..: v+ it: it:..: '~'5 ~ ~ :":'i5 v: 'IREF ~'z' ~A"""""""'" :":'i5 v: iREF ~ 2' ~A"""""""'" i .. ,...................... . .... j+' ............. 2:3 ...... 3:8 ... "~A' .. vi:'~ '±5'v"IREi;~' •••• j-=-••••••••.••.• ·..:.4:3···· ''':'ii:i''' '~A'" vi: ~A' '~'±5'V"IREF'~'i ~A""""""""""""'" 6-19 t-IEC pPC624 Typical Applications Basic Negative Reference Operation Basic Positive Reference Operation v+ v+ d.' d.' r---1 ~ MSB VLC r---1 2nd ~ ______~'3~---+~--~r_----~ R+REF~ VREF VlC MSB 2nd -r____~~____f7 --~____~'3~__ ,. 0-W..----,"".f--....--+------, -YREF '5 0--""'''r--+-----1 R-REF '5 D.' 0.' v- ~ Notes: 1. R+REF = R-REF 2. C = 0.Q1 pF (Standard Value) 3. Minimum capacitor value for stable operation is given by Cc = RREF (kO) X 15 (pF). 83-0023918 83-0023928 Basic Unipolar Negative Operation 5th 6th 7th LSB IREF = 2.000 rnA Input Vii IV) 101mA) iiilmA) Vo IV) 11 11 1.992 0.000 -9.96 0.00 11 1 0 1.984 0.008 -9.92 -0.04 0000001 1.008 0.984 -5.04 -4.92 0000000 1.000 0.992 -5.00 -4.96 1 1 1 1 1 1 0.992 1.000 -4.96 -5.00 00000001 0.008 1.984 -0.04 -9.92 00000000 0.000 1.992 0.00 -9.96 o1 83-0023938 6-20 NEe JlPC624 Typical Applications (Cont.) Basic Bipolar Output Operation +10.000V IREF = 2.000 mA .- 10.000k 10.000k Input 10lmAI iOlmA) Vo IV) VOIV) 11111111 1.992 0.000 -9.92 +10.00 10 Vo Yo 2_ 10 1 1 1 1 I 1 1 0 1.984 0.008 -9.84 +9.92 10000001 1.008 0.984 -0.08 +0.16 10000000 1.000 0.992 0.00 +0.08 o1 1 1 1 1 1 1 0.992 1.000 +0.08 0.00 00000001 0.008 1.984 +9.92 -9.84 00000000 0.000 1.992 +10.00 -9.92 83-0023948 Positive Low Impedance Output Operation Negative Low Impedance Output Operation +15V +15V 7th 0.1 LSB 200~ 7th LSB Vo 0.1 Vo 0.1 5k -15V l 5.000k -15V l 6-21 NEe pPC624 Typical Applications (Cont.) Comparator Connection Method for AID Conversion (Positive Analog Input) Comparator Connection Method for AID Conversion (Negative Analog Input) V,N V,N 7th +15V +5V +5V +15V LSB 7th 3k S.nOOk L$B 1k -15V -15V 83-002398A Low Impedance Output Operation (Both Outputs) t-15V 7th LSB Note: For buffer amplifier, high slew rate op-amp is recommended to obtain fast settling time. 83-002397A 6-22 83-002399A ttt{EC Interfacing with Various Logic Families The logic threshold is set about 1.4 V above VLC. This enables TTL level acceptance by simply grounding pin 1. By placing an appropriate voltage at the logic threshold control pin (pin 1), various threshold values are available for the other logic families. pPC624 Anti-temperature coefficient circuits CMOS, HNll; NMOS CMOS, HNll (1'V) ECl ±15V 200 9.10 130 TTL interface permission gives the interval logic threshold -4 mV/oC temperature coefficient. VTH = VLC + VlC 1.4 V - 0.004 V X (TA - 25°C). I 0.1 200 390 ••20 •. 20 -S.2V 83-002400A 6-23 t\'EC pPC624 Operating Characteristics (TA = 25°C) Fuii Scaie Current Fuii Scaie Current 5.0 V-~ TA = 2.5 -15V -20 to +80°C 4.0 ;c .5. ~ 3.0 i 2.0 / 0 1.0 / / / a V I 2.0 / / ;C .5. ~ a 1;; 1.5 1.0 'CM V-= -15V 0.5 < I ~ ~ 1.0 2.0 3.0 4.0 -15 5.0 ~ % -5 0 \ ~ ~ LSB Propagation Delay 400 I ic 300 i ..e 200 i!. 1\.\\ ,\ -10 o 0.2 0.3 0.5 1.0 2.0 3.0 5.0 10 " i 1.0 10 I i 6.0 2mA IREF ~ 1.5 ai IREF = 1mA 1.0 ~ D. 0.5 IREF O.2mA r ( 16 12 12 Reference Common Mode Voltage (V) 4.0 ci! r 0 6-24 0.1 6.0 LF~l r 0.01 Power Supply Current Relerence Amp Common Mode Range J-5V o ........... Output Full Scale Current (rnA) Frequency (MHz) LJ \ 100 -15 0.1 15 500 I\L~- 1'\ iii' 10 Common Mode Input Voltage Range (V) .,/h ! V+ = 15V -5 -10 Reference Input Frequency Response ;c .5. V+ICM ~ ALL BIT "ON" 2.0 / / / I h- 0 Reference Current (rnA) 2.5 V+ICM V-= -5V V-ICM , / y- =-5V 16 I 20 V+ 2.0 0 10 Positive Power Supply (V) 20 I NEe pPC624 Operating Characteristics (Cont.) (TA = 25°C) Power Supply Current Power Supply Current 6.0,---,----,----,----,-----, 6.0 I-(IREF - 2mA) <" .s 1- 6.0 6.0 ~:-::=t===+===+===:t=:~~ IREF = 2mA o ~ l-(IREF = 1mA) " >. 4.0 I. • &. I I (IREF 2.0 o 4.01----t----t-----t----1----I O.2~A) 1+ 2.0 1+ o -10 -20 F:':":"=::j:::=::=::F=:::::::F::::::::::=F=:::::::::::j 20 20 Negative Power Supply (V) 40 60 60 Ambient Temperature (0C) AID Conversion Program List 0000 MVI A.89H : CONTROL WORD FOR 8255 0002 OUT (8255) : PROGRAM TO 8255 0004 MVI B.80H : 81T POINTER INITIALIZE 0006 MOV A. B : BIT SET WORD OUT (PORT B) : BIT SET OUTPUT TO PB OF 8255 MOV C. A 0007 BIT TEST 0009 DOOA NOP OOOB IN 0000 RRC OOOE JC DEC POINTER 0011 MOV A. C 0012 SUB B 0013 MOV C. A MOV A. B 0014 DEC POINTER (PORT C) : AO - CARRY FLG 0015 RRC 0016 JC RETURN 0019 MOV B.A 001A ORA 001B JMP DOlE RETURN RET : READ COMPARATOR : COMPARATOR TEST : BIT RESET : DECREMENT BIT POINTER : LSB WAS TESTED? : NEW BIT SET WORD BIT TEST (MAIN PROGRAM) : CONVERSION END & RETURN TO MAIN PROGRAM PROGRAM MEMORY : 31 BYTE CONVERSION TIME : 371 /lS (741 STATE) MAX. 323 /lS (645 STATE) MIN (@ 2. Vo COMP 10 r, :~ 0.1 7.5 k 10 • 0 2. ..-; Parallel Mode Address lAW Setup Time Low-Leval WR Pulse Wldlh Pa!'lmeter Conditions ns Dala Selup Time Dala Hold Time ± 2°C; V+ = +5 V ~ J r; Notes: 1. Use resistors of 1% accuracy. 2. Capacitive load at VREF(F) pin should be less than 15 pF. 3. Adjustment Procedure a. Set VREF(F) = 2.7 V by VR1' b. After latching full-scale digital input. set Vo = 2.0V byVR2' 83-Q02474A 0111 Hold Time IWD Note: I r• If $ 50 ns. 6-42 NEe J.lPD7011 Timing Waveforms Parallel Mode Serial Mode WR DB, DB, 10 ::::+- ------------------~ 83-002475A Ir, tf· _ 50ns pk ,r V REF • 2. AID conversion is started with CS going high; at the final step of the first AID conversion, EOC is low. The conversion time is: 'CONV = 56/cK 3. For 'SCK<500 kHz, the load capacitor (stray capacitance included) and the pull-up resistor, which are connected to serial output, are required to be not more than 30 pF and 4 kn respectively. 4. V+ 5. V+ = 5.0 V, VREF = 2.5 ± 0.25 V. = 4.5 to 5.5 V. 6-53 II NEe pPD7001 AC Characteristics TA = +25°C Note 1 ± 2°C; fclk = Addressing the Inputs 400 kHz; V+ = 5 V, Limits Parametar Symbol Min. Typ. One of the four analog inputs is selected by toggling the chip select line at pin 6 "low" and presenting a 2-bit serial Tist Max. Unit Conditions EOC Hold Time IHECS 0 ps EOC 10 CS CS Selup Tima ISCSK 12.5 pS CS 10 SCK Nole 1 Address 0111 Sllup Tlma ISIK 150 os Address 0111 Hold Time IHKI 100 os High Level Sarlal Clock Pulsa Wldlh IWHK 400 os Low Lavel Sarlal Clock Pulse Widlh IWCK 4.00 os Oall Lalch Hold Time IHKOL 200 os Dala Lalch Pulse Wldlh 10KO 200 os Serial Oall Delay Time IDKU Oalay Time 10 FloatiDg SO IFCSO CS Hold Time IHKCS 500 250 200 os os code (from the host controller) to the Serial Input (S!) at pin 3. The "channel select" data is sent to the upper 2 bits of the 9-bit shift register on the rising edge of the Serial Clock (SCK) at pi n 4 and loaded into the Data Latch on the falling edge of the Data Latch signal at pin 2. Referring to figure 1 the analog input addressing sequence is: D Chip Select (CS pin 6) toggled "low" or 0 D 2-bit "channel select" data presented to SI and pin 3 D Data shifted in on SCK rising edge D Data Latch signal present at pin 2 (pulse is 200 ns min.) D Mux address data latched on falling edge of DL signal. SCK 10 OL SCK 10 SO. RL = 3 K (Nole 2). CL = 30 pF Ci 10 High Impedance SO Multiplexer Channel Selection Input DO 01 AD Low Low Al High Low A2 Low High A3 High High Figure 1. Analog Channel Selection ns Notes: 1. When Cs is high. the IlPD7001 performs AID conversion and does not accept any external digital signal. It remains at the previous state continuously. When Cs is low. the data is exchanged with the external digital circuits. However. 5 internal clock pulses are needed before digital data is output. The rating corresponds to the 5 clock signal pulses: tSCSK (min) = 5/fc lk 2. The serial data delay time depends on load capaCitance and pull-up resistance: tOKO = 2.3 X RL X CL + 100 ns. -I l-tHKI 91 _ _ _ _"" r"':"'-D"":,;:;;""-x::D
.....-=----l:::"'''''''-k==--+----==i='''''-I 0.05 ~--+---~:::--"""-kc:--+--=::::~=--I I :@ III ! ,,- 1.0 , - - - . , - - - - , - - - , - - - , - - - - - , - - - , ~ r---.J I 011 ~ ~ I r---..J 010 0 ! I J! a. .J C 001 O.01\-----+-----jc---+----+----j---j 000 0 2LSB Analog Input Voltage 6-56 3LSB (Vi! ! ,LO--~2LO---~5LO--~,0~0~--2~0~0----5~0~0--,=0~O; NEe pPD7001 Operating Characteristics (Cont.) Total Unadjusted Error vs. VREF Clock Oscillation Frequency vs. Current Characteristics ! 500 ~ iii ~ .. 31------1------+-- il; il; "c "'"c w ~ 2 f - - - - - + - - - - - I - - - ,g f--- ,gf--- . "~ .!:c 400 .2 ......... i""" ~ il J2 = 27k ceE = 47pF 0 0 ----RCE 'g 300 L o Reference Input Voltage (V) Output Sink Current vs. Saturation Voltage Characteristics o Supply Vollage V DO (V) Supply Voltage vs. Current Characteristics 1.0 , - - - - , - - - - , - - - - , - - - - - , - - - - , Voo = 5V . _ 0.81-----+----1----+----+-----1 ;::. F ~ 0.6 i ~ 0.4 ;; ~ o 0.2i-----+:7'SO"""=:..!-"'---t----+----I O~o--~r--~------~-----7------~----~ Sink Current (mA) Supply Voltage (V) 6-57 jiPD7001 6-58 NEe IlPD7002 10-BIT CMOS INTEGRATING AID CONVERTER ~EC NEe Electronics Inc. Description Pin Configuration The tlPD7002 is a high performance, low power, 10-bit CMOS analog-to-digital converter. Using the integrating technique the 7002 offers the designer full microprocessor interface, four multiplexed analog inputs, and low power CMOS construction. Xo x, GND Features C, D 8- or 10-bit resolution (selectable) D 4 channel multiplexed analog input D Auto zero and full scale correction without external components D High input impedance - 1000 MO D Internal status register can be accessed by host controller D Operates from single +5 V supply D Interfaces to most 8-bit microprocessors D Low power operation (CMOS) D 5 ms conversion speed (10 bits with fCK = 2 MHz) D Available in two performance ranges: Conversion accuracy (maximum with TA = 0 to +50°C): tlPD7002C-1 .......................... 0.1% FSR tlPD7002C ............................. 0.2% FSR Ordering Information Part Number Package J1P07oo2C Plastic DIP w- C, cs GO Do VREF GND CH3 CH, CH, cHo v+ 83-002445A Pin Identification Function Pin Name 1,2 XO, XI External clock input GNo TTL ground 4,6 CI Integrating capacitor 5,7 GO Guard 3 Operating Temperature Range GO 8 VREF Reference voltage input GNo Analog ground Analog channel 3 Absolute Maximum Ratings 10 CH3 TA = +25°C 11 CH2 Analog channel Z 12 CHI Analog channel I 13 CHO Analog channel 0 14 V+ Voltage (+5 VI Operating Temperature Storage Temperature Power Supply Voltage -0.3 V to +7.0 V All Input Voltages -0.3 V to V+ 0.3 V Power Dissipation 300 mW Analog GNo Voltage ± 0.3 V Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device atthese or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 15-22 07-00 23 CS Data bus Chip select 24,25 WR, RO Control bus 26,21 AO, Al Address bus 28 EOC 1.1 End of conversion interrupt 6-59 t-lEC pPD7002 Block Diagraln Data Bus Analog Input CH l I Control Word Latch CH ~ I I "< Status Latch t (12 an) AID Analog Block ,... I VAEF =:J --cAnalog GND AID ~ 10/8 y Digital Block ~ 6 6 6 Digital ItO Pin Function Pin Symbol Name 1.2 XO. XI Xtal 15-22 07-00 Data Bus 23 CS 24 25 26.27 AD. AI 28 EDC 6-60 110 Function Xtal OSC. XI can be used as the Input of external clock. Three-state (I TTlllIOl AID conversion dala (High and low Bylel and inlernal status output to 8-bit Data Bus. MPY Address.!{IO select and flag data input from bus. High Impedance when IIPD7D02 is not enabled (CS = Hlghl. Chip Select Input low level of CS makes other Input pins (WR. RD. AO. All enable and data transmission and receiving are possible through data bus pins. WR Write Input When WR RD Read Input When RD Input AO. AI deSignate the data In data bus (High. low. Status Bytel. Address End ot Conversion Output (I TTll = low. IIPD7002 rBCeim new data from data bus. = low. IIPD7002 transmits conversion data and Intenial stalus to data bus. EDC indicates the end of conversion to external chips. Read mode operation (high byte outputl resetable EOC. t-iEC JlPD7002 DC Characteristics TA = DOC to HODC; V+ = +5 V ± 0.25 v VREF = +2.50 V, felk = 1 MHz, CINT = 0.033 JlF, 10-Bit Mode Limils Min. Typ. Max. Unll Resolution.7002C-l 10 11 12 Bits Resolution. 7002C 9 11 12 Bils 0.05 0.1 %FSR Nonlinearity. 7002C 0.1 0.2 %FSR Full Scale Error. 7oo2C-l 0.05 0.1 %FSR Full Scale Error. 7002C 0.1 0.2 %FSR Zero Scale Error. 7002C-l 0.05 0.1 %FSR Zero Scale Error. 7002C 0.1 0.2 Full Scale Temperature Coefficient 10 ppm/o 10 ppm/oC Parameler Symbol Nonlinearity. 7002C-l Zero Scale Temperature Coellicient Tesl Condilions %FSR Analog Input Resistance RIH 1000 Total Unadjusted Error 1. 7002C-l TUEI 0.05 0.1 Total Unadjusted Error 1. 7002C TUEI 0.1 0.2 %FSR Total Unadjusted Error 2. 7002C-l TUE2 0.05 0.1 %FSR Total Unadjusted Error 2. 7002C TUE2 0.1 0.2 %FSR Clock Input Current Iclk 5 50 JlA High Level Output Voltage VOH V 10 = -1.6 mAo TA = -20 to +70°C Low Level Output Voltage VOL 0.45 V 10 = 1.6 mAo TA = -20 to +70°C Digital Input Leakage Current IILK 10 JlA Output Leakage Current 10LK Power Dissipation Po Mn V+-1.5 15 %FSR 10 JlA 25 mW XI pin can be used as an external CMOS level clock input. When external clock Is applied. Xo pin should be lell open. 6-61 ~EC jiPD7002 AC Characteristics T A = +25°C; V+ = +5 V ± 0.25 V, VREF = +2.5 V, fclk = 1 MHz, CINT = 0.033 JiF Limits Par!!!!ete!' Test ., .... M:}{. 8.5 10 15 2.4 4 Symbol ~~~. Conversion Speed [10 bit) tCONV Conversion Speed [8 bit) tCONV Address Set!!J!..Time CS, AO, Allto WR tAW 50 ns Address Set!!!!.. Time CS, AO, All to RO tAR 50 ns Address Hold Time WR to CS, AO, Al tWA 50 ns Address Hold Time RO to CS, AO, Al tRA 50 ns Low Level WR Pulse Width tww 400 ns Low Level RO Pulse Width tRR 400 ns Tun Ur.it ms ms Data Setup Time Input Data to WR tow 300 ns Oata Hold Time WR to Input Data two 50 ns Output Delay Time RO to Output Data tRO 300 ns Delay Time to High Z Output RO to Floating Output tOF 150 ns Nole 1 Note: 1 TTL load + 100 pF. Recommended Operating Conditions TA = +25°C Limits Parameter Supply Vollage Reference Vollage Symbol Min, Typ, Max, V+ 4.75 5.00 5,25 VREF 2.25 2.50 2.75 Analog Input Vollage Clock Frequency felk Integrating Capacitor CINT High Level tnpul VIH Low Level Input VIL High Level Clock Input VXHL Low Level Clock Input VXLL 0.5 Unit Test Conditions Notes [ContI: 2. Integrating capacitor: C1NT depends on clock frequency and can be obtained as follows C1NT(/lF) = 0.033/fclk (MHz). Note that conversion time is inversely proportional to the clock frequency. 3. TA = -20'C to +70'C, V+ = +5 V ± 0.25 V. Timing Waveforms Write Mode v V Nole I MHz Nole 2 pF 0.029 0.033 83-002600A 2.2 V Nole 3 V Nole 3 V Note 3 V Nole 3 Read Mode 0.8 V+ -1.4 1.4 Notes: 1. Negative voltage input « -0.2 V) decreases the input impedance. Furthermore, conversion error for the input through another MPX channel also increases. Input Conditions t r, II::::; 50 ns 24~ 0.4 V 83-002447A 6-62 !\fEe J1PD7002 Timing Waveforms (Coni.) AID Conver,lon Start - End Write Mode - EOC Output Do - 07 -+---'17----------'--------,\ Status EGC ~------~~------~/~=== Status BUSY Status MPX g:~ay~:~~; X L _ _ __ -lr-----------_'_---------, Previous co~verSion Data X'~----____ -+-------------------~ Conversion Data \~-- STOP ----- se~~~:~--~~~~------~~-------t~1 AID Conversion STOP End of Conversion START 83-0026018 Read Mode (Status, Low Byte) C$,AO,A, ifij----"'\ 00-0, ----++-0. Status latch ----H....,.'+------- Conversion Data Latch :===~~;t====== After AID Conversion END AID Conversion END and Low Byte Read Mode 83-0026028 Read Mode (High Byte) IX x EDC _ _ _....J After AID Conversion END '---AID Conversion END and High Byte Read Mode Read operation of High Byte resets the EOC (STATUS and EOC pin) 83-002451C 6-63 ~EC pPD7002 There is some uncertainty whether EOC is set or not, when data read operation is made simultaneously with the end of AID conversion. Furthermore, the reading error occurs at this time, so in this case a dual read operation is recornrnended. Operating Characteristics Full Scale vs .. 1111 11 .. 1110 11 .. .. 1101 i .----' I i a 11 Sequence I ~ ~ .---' I .----' 1100 One of the four analog inputs is selected by initiating a write mode from the external controller with the control signals as follows: CS (pin 23) = "!ow," RD (pin 25) = "high," WR (pin 24) = "low," A 1 (pin 27) and AO (pin 26) = "low." The analog input select data is presented to DO (pin 22) and D1 (pin 21) and the desired channel (1 to 4) is selected. The conversion resolution mode is also selected during "write" mode by presenting a "high" for 10-bit mode or "low" for 8-bit mode, to D3 at pin 19. V REF «" 11 Addressing the Inputs 00 .. 0100 00 .. 0011 D Initiate "write" mode (CS = 0, RD = 1, WR = 0, A1 IA2 = 0) . D Present data for analog channel select to DO, D1 . r-A'"..--I I .----' I 00. 0010 00 . . 0001 .---' I .----' I 00 .. 0000 1020 0 Analog Input (LSB = 1021 VREF 11024) Total Unadjusted Error 11. 1022 1023 1024 CHO= CH1 = CH2= CH3= DO L H L H D1 L L H H D Present conversion resolution data to D3. 10 BIT = H 8 BIT = L During the write mode the only available function of the tJPD7002 is data input from the controlling system. When the write function is terminated the AI D conversion process starts. The Conversion Process 00. Analog Input Transfer Characteristics with Respect to VREF During the "write" mode the internal sequence controller is initialized and ready to take control of the conversion process on the rising edge of the write pulse. All conversion functions take place with thetJPD7002 in the "not selected" mode with the control signals set at: CS = "low," RD and WR "high ... AO" and A1 "don't care." In the AID section the analog signal is input via the multiplexer and compared to VREF at pin 8 (VREF sets the maximum full-scale input signal which can be converted). At this point the internal sample and hold for auto zero function and full scale correction are accomplished. The processed analog signal is then passed to the analog section where the integrating capacitor is charged for a given time period controlled by the clock. In this case the period is 8192 clock periods. The capacitor is then terminated to ground and the falling slope is measured by the number of clock cycles to the zero crossing point. The number of clock cycles from peak to zero (falling slope) is proportional to the value of VIN. The integrator is then set up for the next conversion cycle. Analog Input 6-64 NEe The digital section converts the pulses from the analog section to 12-bit code and sends the converted code to the conversion data register where the data is latched and ready for "reading" by the controlling device. The data is then "read" in two bytes by addressing AO and A1 while in the read mode. A 1 = "low" AO = "high" reads the high data byte (DO to 07), and A1 = "high" AO = "either" reads the low data byte (07 to 04). During the low data byte read DO to 03 are low and the data on 04 and 05 (bits 11 and 12) may not be accurate data. The internal status can also be checked while in the read mode by setting AO and A1 both "low." Operation of Individual Sections Sequence Controller (See Sequence Chart) The Sequence Controller controls the internal sequence of AID conversion and the operation of the three-state 1/0 buffer. It is initialized by the write mode operation (analog MPX address and 10-/8-bit choice). After the write mode operation, the Sequence Controller starts the AID conversion, and outputs an EOC signal when the conversion is completed. There is no power-on-reset circuitry. AID Conversion Block In the AID section, an analog signal is input through the MPX and is compared to VREF, after which it is converted to a digital output signal. Full scale analog input is equal to VREF. GND as an analog input is equal to zero scale. AID conversion time depends on both analog input voltage and conversion mode (10/8 bit). Three-State 1/0 Port Section The three-state 1/0 port section is controlled by the Sequence Controller. It accepts the MPX address input and conversion mode input (10-/8-bit choice). The three-state 1/0 port section outputs the internal status and conversion data highllow bytes. JlPD7002 Conversion Data Latch After the end of conversion, the AID section outputs new data to the Data Latch. The output of the Data Latch is con nected to the three-state II 0 ports, and the data can be read at any time. When Data Read occurs simultaneously with an internal data transfer, a read error occurs. Therefore, two read operations should be made, unless Data Read occurs after the end of conversion. Status Latch The status latch stores the status data internal to the chip, and the internal operation state can be referenced by the status data. Status includes the following: BUSY, EOC: Internal sequence state of pPD7002. Write mode operation sets BUSY, and this is reset at the end of conversion. EOC is set at the end of conversion, and High Byte Read Operation resets EOC. MSB, 2nd; 10·/S·Bit Flag MPX The data stored in the conversion Data Latch when the status reading operation is made can be output. Therefore, the data is refreshed at the end of conversion. Access to the pPD7002 from the CPU can be made by both interrup~nd polling methods. In the interrupt method use EOC as an interrupt signal. In the polling method, use EOC and BUSY in Status Byte. After the AID conversion, the data in the conversion Data Latch does not change, and can be read repeatedly. Therefore, fundamental instructions like Load, Store, Move, etc. can be used to access data (by placing the address of the pPD7002 in memory area). Note that the access time (tRD) and the data setup time (tDW) of the pPD7002 are longer than that of the 8080 and 8085. The following program example shows the accessing of the pPD7002 by polling method in an 8080-based system. MPX Channel Address Functions MPX Address Bit Analog Input Channel CHO CH1 CH2 CH3 00 6-65 II • NEe JlPD7002 Control Terminal Functions Control T8rminals CS RD WR AI A7 Internal Function Mode Data 110 Terminals x x Hoi seiected ............................................................ H H H Not satected H Write mode Dlta latch AID start tnput status. 01. DO = MPX addrass 03 = 8·bitIl0·blt convarsion designation. Note 1. 07 = Flag Input. L H Not selactn ............................................................ L H L H H L H L Not selected H H High impedanca H Tast mode Tast status Input status. Note 2 L Read mode tnternal stltUS 07 02 H Reid mode High data byta 07-00 = MSB - 8th bit ~ •.••~ ...•H••.• ~••••..••~a~ .~o.d.e ••.••..••.. ~?~. ~a~~ ~~~ •...••••• L High Impedance H Raid mode Low data byte = EOe. 06 = BUSY. 05 = MS8. 04 = 2nd MSB. 03 = BII O. = Fllg Output. 01 = MPX. 00 = MPX 07-00 = 9th - 10th bit 03-00 = L Noles: 1. Designation of number of conversion bits: 8 bit = L; 10 bit = H. 2. Test Mode: used for inspecting the device. The data input-output terminals assume an input state and are connected to the AID counter. Therefore. the AID conversion data read out after this is meaningless. Bit Function Write Mode Function Read Mode Stalus Outpul High B,te Oulput Low B,te Outpul 10-Bil Nole 2 8-Bil 10-Bil Nole 2 8-Bil Eoe MSB MSB 9th Note 3 Output BusV 2nd 2nd LS8 Note 3 Output MSB Note 1 3rd 3rd 011 Note 3 04 Output 2nd Bit Note 1 4th 4th 110 10/8·BIt lo/8·BIt Note 1 5th 5th 012 Low Nota 3 03 02 110 Fllg input Flag Output Note 1 6th 6th Low Low 01 110 MPX Addrass MPX Note 1 7th 7th Low Low DO 110 MPX Addreas MPX Note 1 Bth Bth low low Bit 110 07 Output 06 05 Low Noles: 1. Previous conversion data. 2. In 10-bit mode. thepPD7002 operates as a 12-bit converter. Therefore. 11th and 12th bit data appear at 011 and 012. and the output of 011 and 012 varies with analog input; however. the data contain internal noise and are meaningless. 3. Not to be determined. 6-66 ttlEC pPD7002 Typical Applications Typical Microprocessor Interface 1. The high level input voltage of thepPD7002C is 2.2 V. In a minimum component system configuration, ~ 50 kO resistors to DBo-DB7, Ao, A1, CS, RD, and WR is recommended. The fan-out of DBo-DB7 is 1 TTL level. In larger systems, use bus drivers as shown here. s~~:mt::::~u~.18~~==========~~======:J 16 Address Bus 2. Use EOC as an interrupt signal if you have an interrupt-driven system. CD 3. Use a 100 Hz low pass filter to decrease the conversion error. Using the diode protection circuit shown here is effective protection against high voltage surges. Analog Input 4. The pPD7002 uses the integration technique for AID conversion, and it operates at a very low current level. The external integrating capacitor (CINT) is directly connected to the internal integrator. Using the guard pattern as shown below makes the operation less sensitive to leakage current. CH, ® ® CH, I Xu CH, D pPD7002C CH, x, VREF 5. Capacitors are tied to the X and Xo pins to stabilize the oscillation, use a ceramic capacitor about 50 pF. About 50 ms is required for stable oscillation after initial power-on. Therefore, the first Write Mode Operation should occur after this interval. 1 Guard @ 0.1 63-o02454A Use of Bus Drivers System Bus A I '\ DB, DB, DB, DB, DB, DB, DB, DB, DB, DB, DB, DB, DB, DB, DB, DB, ' - - OlEN CSc- pPB8216C Ole DO, Dl, DO, Ol, DO, DL., DO, LJ LJ LJ LJ DB, DB, DB, DB, Ole DO, Dl, DO, iffi CSt- pPB8216C ' - - OlEN CS Dl, DO, Dl, DO, LJ LJ LJ LJ DB, DB, DB, DB, cs RD pP07002C 83-0024538 6-67 fttIEC pPD7002 Typical Applications (Cont.) Noise Reduction The pPD7002 is an integrating AID converter; however, it operates at a relatively high speed and the normal fnode noise rejection cannot be expected. Obseivance of the following points will minimize noise induction to the input of the analog circuit. Diode Protection Circuit +5V o 1S953 ,. Analog Signal Input o Voo {} CH o tlPD7002C 1S953 Use lower impedance in GND connection Place the bypass capacitors for supply voltage and VREF and analog input close to the pPD7002 (one point GND is also effective) Isolate analog circuitry from digital circuitry: Component layout - GND wire layout - Shielding of analog circuitry (pin configuration of the pPD7002 is suitable for the layout shown in the next figure) 83-002455A Shield for Analog Circuitry Guard Pattern Guard Pattern pwe Digital Circuit Pin 4-INTO cp? 0 ~---II-CINT Shield Case 83-002456A 83-002457A 6-68 JlPD7003 8-BITCMOS HIGH-SPEED A/D CONVERTER NEe NEe Electronics Inc. Pin Configuration Description The /.IPD7003 is a high speed, high performance, low power, 8-bit analog-to-digital Converter designed to be easily interfaced to the 8080 and 8086, 8- and 16-bit microprocessors. Using the parallel conversion technique, the /.IPD7003 features a conversion speed of 4 /.IS and eliminates the need of sample and hold circuits in most applications. The /.IPD7003 is also capable of running under DMA control using a DMA controller such as the pPD8257. Available in a 24-pin ceramic/plastic DIP, the /.IPD7003 is the ideal converter for high speed 8-bit designs. DBo (LSB) DB, GNDD GNDA DBs 7 OB7 (MSB) ClK I.c. (TEST) V+ ""L=---_ _--"'-r-" MODE 83-002458A Features D High speed conversion (250 k samples/sec. max.) D Input consists of 255/1 matched autozeroed comparators D No missing codes over temperature range D Linearity ±1.25 LSB max. D Three-state outputs D Overrange output D Operates from single +5 V supply D Low power consumption (50 mW) Pin Identification Pin Name Function DO, 7th bit output 2 OB2 6th bit output 3 NC Non connection 4 DOa 5th bit output 5 004 4th bit output 6 DB5 3th bit output 7 006 2th bit output 0 DB7 MSB output 9 OVER Overrange output 10 V+ Power supply (+5 V) 11 YREF Relerence voltage input (positive) 12 V+ Power supply (+5 V) Absolute Maximum Ratings 13 MODE MODE control (note I) TA = 25°C 14 TEST Low: Device test (used lor inspecting tha devica) High: Conversion 15 CLK Low: Previous data output High: Quantizing Ordering Information Part Number Package Operating Temperature Range JlPD7003C Plastic DIP -20°C to +10°C JlPD7003D Ceramic DIP -20°C to +OO°C Operating Temperature. CPackage -20 to +10°C Operating Temperature. 0 Package -20 to +10°C Storage Temperature All Input Voltages Power Supply Power Dissipation Analog GNO Voltage -65 to +125°C -0.3 to V+ +0.3 Y -0.3 to +1 V 300 mW ±0.3 V 16 CS Chip select 17 DACK DMA Acknowledge 10 DE Low: Data output High: High impedance 19 AGND Analog ground Comment: Stress above those listed under "Absolute Maximum 20 VIN Voltage input Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 21 YREFIGNDI AGND GND lor VREF 22 23 GND Digital ground 24 DBo (LSB) LSO II Analog ground 6-69 t\'EC pPD7003 Pin Identification (Cont.) Pin Name Function 19 GNDA Analog ground 2D Noles: 1. tnputs DE Mode VSIN Analog input 21 VREFN Reference voltage input (negative) (Nole 2) 22 GNDA Analog ground 23 GNDD Digital Ground 24 DOD LSD output 1 B·BiI Register Data refreshed with every CONV j o D No change 2. Tie to the analog ground unless external zero adjustment required. Block Diagram RI2 Over Range Latch r-----------------i;~-----oOVER R R Selector 256 - 1 Encoder (ROM) 8 Bit Register R ,,2 R/2 CMP X 256 Input Buffer TEST 83-002459C 6-70 fttIEC JlPD7003 DC Characteristics TA = +25°C, V+ = VREF = 5.0 ± 0.25 V Limits Symbol Parameter Powar Supply Currenl ICC High Laval Output Voltage VOH Min. Typ. Max. Unit 6.0 18.0 mA 2.8 Tesl Conditions V = 4.0 pI, tWLC 10 = -2.0 mA tCY = 2.0 ps Nota 1 Low Level Output Voltage VOL 0.4 V 10 = -1.0 mA Digital Input Leakage Current IILK 10 pA oV5VIN 5V+ Digital Output Leakage Current IOLK 10 pA oV5V05V+ 3.57 mA CLK = H or L Note 1 1.19 1.79 Relerence Input Current IREF Analog Input Resistance RIN 35 kO VEN pF lelk = 1 MHz; unmeasured pins relurned to Ground pF lelk = I MHz; unmeasured pins returned to Ground mW tCY CREF 100 Analog Input Capacitance CIN 100 Power Dissipation Po Relarence Input Capacitance 50 = 2.5 V, tCY = 4 ps, twLC = 2 ps Note 2 = 4.0 ps. tWLC = 2.0 ps Noles: 1. This means DC current. Tie the bypass capacitors (electrolytic capacitor~ 10IlF, ceramic capacilor=0.01IlF) to V+ and VREF pins, in order to absorb rush current (= 10 rnA). 2. DC input equivalent circuit is shown below. Tie the bypass capacitor (> 0.01IlF) to Ihe analog input pin. 3 rnA peak current flows inlo this pin. Conversion Characteristics AC Characteristics TA = 25 ± 2°C; V+ = 5.0 V TA Limits Parameter Symbol Min. Typ. tOED Output Delay Time Delay Time to Floating Max. Unit Test Conditions 100 350 ns DE! - DO '1'5'0'" 450···· ·n~···· Coily'!'':: DO" .. incn ······· ............................................ toso 100 350 ns CS ! - DO .incov " ...... '1'0'0' .. 350' ... 'n~' ... cONi! ','':: oVER .. ~~~~ ........ ?~ ... ~~~ .....n~ .... ~~ .'.-:. ~~ ... . tFSo 150 450 ns CS , - DO = 25 ± 2°C; V+ = VREF = 5.0 V; ICY = 4.0 ps; IWLC = 2.0 Jis Limits Parameter Symbol Min. Typ. Resolution RES Nonlinearity NL Full Scale Error Temperature Coefficient Zero Scale Error Temperature Coefficient Unit Test Conditions Dits 8 Full Scale Error Zero Scale Error Max. ±1.25 LSD ±1.o0 LSD +0.75 LSD 20 -0.75 20 ppmfOC Nole: IlPD7003C: TA = O'C to +70'C. 6-71 ttlEC tJ PD7 OO3 Recommended Operating Conditions Converter Operation TA = O°C to 70°C: pPD7003C, TA = -20°C to +80°C: pPD7003D Um~!! Parameter Supply Voltage Symbol Min. Typ. Max. Unit TBst Conditions Referring to the block diagram, the reference voltage is set externally to some desired level which references the individual internal components such that V REF is divided equally by 256 resistors in a ladder/divider configuration. The applied voltage to V,N is then compared to the reference level and the individual samples are sent to the selector section where the individual signals are multiplexed to form an address data word. The data word is then further encoded to form the final 8-bit data byte by the encoder ROM, and stored in the 8-bit register until the Output Enable Command. Then the data is sent to the data bus via a three-state buffer. V+ 4.75 5.0 5.25 V Reference Inpul Vollage VREF 4.0 V+ V+ V Analog Inpul Voltage Y,N -0.1 V++O.I V Higb Level Logic Inpul VIH 2.4 V+ V Mode Select V,L -0.1 0.8 V There are two modes of operation for the pPD7003. Figure 1 shows the timing diagram for mode "0" where the converter is operating in continuous output mode. The analog input is sampled when the clock is in the "low" state. When the clock is in the "high" state the conversion from analog-to-digital takes place and the resultant data is output on the next falling edge of the clock pulse and the cycle is repeated. Low Level Logic Inpul Sampling Rale 10 250k IImes!s 100 Conversion Cycle Time 'CY 4.0 CONY High Level Widlh IWHC 2.0 ps CONY Low Level Wldlh IWLC 2.0 ps CONY Selup Time ISCE 0 CS Selup Time ISSE CS Hold Time ps I - DE I ns CONY 100 ns CSI-DEI IHES 0 ns DEI-CSI DE Selup Time 'SEC 600 ns DE 1- CONY I DE Hold Time IHCE 400 ns CONY DE Low Level Wldlh IWLE 400 Digilal lopul Rise and Fall Time l r. If Note I Note 2 ns 50 ns Noles: 1. ISCE (ns):::: ICY (ns) - IWLE (ns) -100 (ns). 2. IWLE (ns) :::: tCY (ns) - tSCE (ns) -100 (ns). 6-72 I - DE I The second mode (Mode 1) is shown in figure 2. In this mode of operation, one conversion takes place while the clock is in the "low" state and the resultant data is held as long as output enable and Chip Select (CS) or DMA Acknowledge (DACK) are "low." Data refresh is inhibited until CS and DACK are recycled. MODE = "HIGH" Data is refreshed on the falling edge of ClK, loaded during the "low" clock state, and converted and output during the "high" clock state. MODE = "LOW" Data is loaded and converted when Output Enable is "low" and refreshed only when OE makes the transition from high to low again. Note that in either ca~ data will only be accepted and output when OE and CS or DACK are active ("low"). Output enable should not be changed during the intervals shown in figure 3. The timing for output enable change versus clock transition is 600 ns before and 500 ns after the rising or falling edge of ClK any attempt to change OE during these periods will be inhibited. t-IEC JlPD7003 Timing Waveforms Figure 1. (MODE;O) Figure 2. (MODE;1) tFSO ~ OVER _______ :~VR ==========:*I..______*"_ 83-OI)1677A 83-002460A Figure 3. Timing Chart II OE Level Change: OE Level Change: DE Level Change: Inhibited Inhibited Inhibited 83-0024628 6-73 pPD7003 6-74 ftt{EC pPD7004 10·BITCMOS SUCCESSIVE APPROXIMATION A/D CONVERTER ~EC NEe Electronics Inc. Description Pin Configuration The pPD7004 is a 10-bit monolithic CMOS analog-todigital converter using the Successive Approximation Register (SAR) technique. The pPD7004 incorporates an 8-channel multiplexed analog input and full microprocessor interface to achieve a high degree of versatility. The designer has a choice of either serial or parallel output and interface to 8080 type microprocessors or advanced signal processors like the pPD7720. Analog Input CH 4 Analog Input CH! Analog Input CH 2 Analog Input CHa Analog Input CH, Analog Input CHr R.f.rence Input V REF Analog Input CHo 5 GND v+ GND CS Chip Select D87/SO 08./51 DBs/SHIFT RDISCKI 9 AO OB4/SCKO Features DB3 WRISTS /SO'EN Me Mode Select CLOCK INPUT DB,/CODE D 8-channel multiplexed analog input D Serial or parallel interface D 10-bit resolution D Linearity: 1 LSB max. (TA = 25°C) D D D D Analog Input CHa 2 D8,IDEV1 EOC End of Conversion Output DBo/DEVO v+ 83-002464A Conversion time: 100 ps (fclk = 1 MHz) Input voltage range 0 to V+ Temperature range from -40 to +85°C Operates from single +5 volt supply Conversion Characteristics TA = 25°C, V+ fclk = 1 MHz = VREF = 4.5 to 5.5 V, LImits Ordering Information Part lumbar Package IlPo7004C Plastic DIP Parametar Operating Temperature Range Nonlinearity 10 10 NL lero Scale Temperalura Coenicienl TA = 25°C -0.310 +7.0 V Inpul Voltage, V, -0.3 10 V+ +0.3 V Halaranca Voltage, VREF -0.3 10 V+ +0.3 V -4010 +85°C Operallng Tamparalura, TOPT Resolution lero Scale Error Absolute Maximum Ratings Supply VoIIIDa, voo Symbol Min. Typ. Max. -0.5 Test Conditions -4010 +85°C 10 Bil ±1.0 LSB ±0.5 LSB ppmfDC 2 Full Scala Error Unit 0.5 Full Scale Temperalure Coenlclanl LSB ppmfDC -40 lo+85°C LSB -4010 +B5°C (T = TOPTI Siorage Temperalura, TOPT Comment: Stress above those listed under ''Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device atlhese or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Nonlinearity NL ±2 -40 10 +85°C 6-75 II t-t{EC JlPD7004 Pin Identification Parallel Mode Pin Symbol Direction CH4 Analog Inpul CH4 CH5 Analog input CH5 3 CH6 Analog inpul CH6 4 CH7 Analog input CH7 5 V+REF Positive reference Inpul 6 GND 0 Dala bus (MSB) DB6/SI 0 Data bus (2nd) DB5/SHIFT DB4/SCKO Function Ground DB7ISO 10 Serial Mode Direction Function 0 Serial oUlput Serial inpul LSB/MSB lst select Data bus (3rd) 0 Data bus (4th) I/O Serial clock output I/O Serial OUlpUI enable 11 DB3/S0EN 0 Dala bus (5th) 12 DB2ICODE I/O Data bus (6th) Code select 13 DBlIOEVI I/O Data bus (7th Frequency divide ratio set 14 DBO/DEVO I/O Data bus (LSB) Frequency divide ratio set 15 V+ 16 EOC 17 CLOCK Power supply 0 End of conversion (active low) Clock input = Parallel. L = Serial) 18 MC MODE select (H 19 WR/STB Write input 20 AO Address input Internal/external shill clock 21 RD/SCKI Read input Serial clock input 22 CS Chip select 23 v+ Power supply 24 GND Ground 25 CHO Analog input CHO 26 CHI Analog input CH 1 27 CH2 Analog input CH2 2B CH3 Analog input CH3 6-76 Strobe Input ttiEC pPD7004 Block Diagram CLOCK v+ ? ? CHO cr- Programmable CHI q- Divider I I I I Frequency MPX I I CKI ? ? ? ? -- s:= l............-tWA ~,. ._IW_O CS'A'=?_~ _~ tARl" K = : . = I _tRR- ___ ----- AD ~ I+- -----=x ___ IRO -+ 1-. --10 ' __ __ The pPD7004 gives the designer a choice of the type of data output format, either a 2's complement or binary, and the speed of operation by providing a programmable frequency divider. These options may be selected by the controlling system at any time by the "initialize" mode. The "initialize mode" is set with CS and WR both "low." RD and AO are set "high." Code select is accomplished by presenting either a "high" for 2's complement or "low" for binary output at DB2 (pin 12). The divide ratio of 1/1 to 118 is set by presenting a 2-bit code to DBO (pin 14) and DB1 (pin 13). DBO L H L H Figure 2. Data Output Timing Diagram 08 0_1 Initializing the Converter 1/1 1/2 1/4 1/8 o Ir------- 83-002465A Ratio Chip Select (CS) "low" and AO (pin 20) "high" DRead (RD) set "low" and Write (WR) set "high" o Output high byte (MSB to 8th bit) o AO set "low" Output low byte (9th bit and LSB) (2) Read Mode (1) Write Mode CS,~~~ Referring to figure 2, the sequence is: The Conversion Sequence ThepPD7004C uses the Successive Approximation Register (SAR) technique to convert analog voltage levels to 10-bit digital code in either 2's complement or binary format. Regardless of the type of data output (either serial or parallel), the conversion process is the same. Once the clock frequency and the output data format have been set, and the analog input selected, the conversion process begins with the analog level compared to the existing level from an internal10-bit digital to analog converter. The DIA output level is proportional to the existing code output from the Successive Approximation Register which is proportional to the input level from the comparator. DB1 I L H H 6-79 6 NEe pPD7004 Data Bus 110 Operation (Parallel Mode MC Pin Symbol 22 CS is Viii 21 Ho 20 AD function ii x x Operation L H x x No Operation OB7 14 = H) Initialize MPX address selling oB2 = CODE oB2,1,o = Analog selecl H= 2's camp CH select 0,0,0-1, I, 1 L = binary OR1, ORO = divide = CHD - CH7 ratio 0,0-1,1 = 1/1-118 oBo High byte read Low byte read DB7 - oBo oB7,oB6 = MSB- 8th Inhibit =9th, LSB oB5 - oBD = lOW level Serial 110 Operation (Serial Mode 1, 2, MC = L) Sarial Mode I (External SCK, AD = Pin Symbol SO 8 Direction 0 SI Sarial Moda 2 (Signal Processor Mode, AD LI function Direction Sarial output (three s!!!!1 OIl!.!!!. outpul at the failing edge of SCKI or SCKo. Tie to V+ Sarill Inl!!!!J!.ata read at the rising edge of SCKI or SCKO. 9 SC Shift select (H/L - LSB/MSB first) 10 SCKo Tie to GND 11 SOEN Tie to GNo 12 CODE Code select (H = 2's complement, L = binary) 13 DIVI I = HI function Frequency i 4....... oivo ............... i....... Divide rilio siHlng o o Serial clock output (= Internal clock) Serial output enable (active low) DlVl. 0 = 0, 01,1 = 11111 8 19 STB Address strobe input MPX addresses are Iitched at the rising edge 01 STH Input. Tia 10 GNo 21 SCKI SCKI controls the shift operation of 110 Interlace shift register. Data are output at the failing edge, and Input at the riSing edge. Tie to V+ 22 CS Chip salect signal input. Low level 01 CS resets the internal sequence, and 110 interface is enlbled. Internal sequence reael signal Input. Selll!ence controller are raset at the low level 01 CS, and AID conversion starts at the rising edge of ca. Notes: 1. In serial mode 1. I/O pins listed below are strobed by Cs si!l.!!!!!:...Therefore, when CS = HIGH, input signals are ignored and output pins are left at high impedance state. Input terminal; SI, STB, SCKI Output terminal; SO 2. In serial mode 2 (signal processor interface mode). By initialization, analog input MPX of CH7 is automatically selected. 6-80 ftiEC pPD7004 Parallel Operation L MC A,cr-----.,..--r"""\ WR " - _ - 1 -.... cs 83-0024698 Serial Operation Successive Approximation Register - C M P SCQ--------, s.Q-----l 5cr---i~>-~ ___1 10-911 Bidirectional ShiH Register so 133-0024706 6-81 NEe pPD7004 Timing Waveforms Serial Mode 1 SI so - --------- .... ~---,~- ~ __ _Jx~ ____________ ~ 83-002467B Serial Mode 2 SO ----~_ _ __' ...._ _ _ __ _ ___'x'-___ 83-0024688 6-82 ttlEC pPD7004 Timing Waveforms (Cont.) Parallel Mode Timing Chart (MC = H) 1. Sequence Example High Byte Read , Low Byte 2. Status Write (Executive as Initialization) ~--------------~I '--____-.J! \~----------- xxxx '----------~! '--____-.J! I XXX)( Internal Sequence 4. Data Read \~ AiD Conversion Clear ________-JI \~ ____---II --_-_-_-_-_-_--_."vvvv'XlO~r-----------..,XXXX~-rr---------------_-----Byte _ _ _ _ _ _ _ _..... ........_ _ _ _ _ _ _ _ _ _ _.._ " .......... " _ _ _ _ _ _ _ _ _ _ _ _ _ H;High L;LowByte ~:x..l DB ( > 83-002471C 6-83 JlPD7004 6-84 !\fEe fttfEC II FUNCTIONAL BLOCKS 7-A FUNCTIONAL BLOCKS t-IEC Section 7 - Functional Blocks pPC398 Monolithic Sample-and-Hold Circuit ........................................ 7-1 pPC494 Switching Regulator Control Circuit ......................................... 7-3 pPC751/752 Quad Addressable Read/Write Amplifier ............................... 7-13 pPC754 Magnetic Servo Head Preamplifier ........................................ 7-19 pPC1042 Switching Regulator Control Circuit ...................................... 7-21 pPC1060 Precision 2.5 Volt Reference Regulator ................................... 7-27 pPC1555 Precision Timer Circuit .................................................. 7-29 pPC1571 Compander ............................................................ 7-35 pPC1663/1664 Ultra-Wideband Differential Amplifier ............................... 7-41 pPC3423 Overvoltage "Crowbar" Sensing Circuit .................................. 7-45 pPD5555/5556 CMOS Timers ..................................................... 7-51 7-8 jiPC398 MONOLITHIC SAMPLE·AND·HOLD CIRCUIT ~EC NEe Electronics Inc. Description Pin Configuration The tlPC398 is a monolithic sample and hold circuit which combines J-FET and bipolar circuitry on the same substrate to provide a high input impedance input buffer and a high speed output buffer. Operating as a unity gain input buffer circuit, DC accuracy is typically 0.004% and acquisition time is as low as 6 tls with a maximum gain error of 0.01 %. This device is ideal for data acquisition circuits requiring high speed and high input impedance. '-../ v- [ 1 OHset [ 2 7 pPC398C 3 5 4 6 Input C V- [ Logic to Logic Reference Differential Voltage Output ±15V -0.3 to +7.0 V Output Short Circuit Ouration Hold Capacitor Short Circuit Ouration Indefinite 10 s 350 mW Power Dissipation Operating Temperature Range Ordering Information -55 to +150°C Storage Temperature Range Package Hold Capacitor 36 V D D D D D Plastic OIP Logic Reference Absolute Maximum Ratings Input Voltage Range [Note 1) I'PC39ac Logic Input TA = 25°C Voltage Between V+ and V- Part Number P P P P 83-002547A Features Fast acquisition time Gain accuracy: 0.004% Input offset voltage: 2 mV Direct interface to TTL/CMOS LF398 direct replacement 8 Temperature Range Note: 1. For supply voltages less than ±15 V, the absolute maximum input voltage is equal to the supply voltage. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Equivalent Circuit v+ Offset 1 --------~-----, I I 30 k I I >--+--~ 5 Output Input Logic Input 3 I I :~________ J 300 Logic Reference L ___________ _ Hold Capacitor 4 V 83-002546C 7-1 NEe jlPC398 Typical Connection Recommended Operating Conditions TA = 25°C, V± = ±15 V v+ v- Limits Parameter S¥mbol Power Supply Voltage V± Min. T!!l- MHX, ___ .. it r-I~~h J,.. .. J Test (;Q"rlit!o~s ±5 ±15 ±16.5 Output Analog Input Analog Input Voltage VIN -11.5 +11.5 Sample Mode Logic Input Voltage VSH 2.7 5.25 Hold Mode Logic Input Voltage VSH -15 Logic Input Voltage Slew Rate SR 0.2 Hold Capacitor CH 0.001 Digital Input V r VREF = 0 • V 5V ---.J 83-002548A 0.5 VREF = 0 Guarding Technique (Bottom View) Vips 0.1 Logic V· pF OUT V83-002549A Electrical Characteristics TA = 25°C, V± = ±15 V, - 11.5 V S VIN S + 11.5 V, C H = 0.01 fiF, RL = 10 kO Limits Parameter Symbol Min. Typ. Max. Unit Input Offset Voltage Vi. 7.0 mV Input Bias Current Ib 50 nA Input Impedance Gain Error 0.01 Feedthrough AHenuation Ratio Output Impedance n 10" RiN % dB 80 1. Test Conditions 4.0 n f = 1 kHz Hold Step Voltage VHS 2.5 mV Vo = 0 Leakage Current into Hold Capacitor IOLK 200 pA V±= ±5Vto ±18 V Acquisition Time taq 4 ps Ll.VO = 10 V. 0.1% Error. CH = 1000 pF ......................................................................................... 20 tSq Hold Capacitor Charging Current ICH Logic Input Current liN Logic Threshold 3iippiy VoiiilYu iiejHliiiun niliiu Supply Current 7-2 Ll.VO = 10 V. 0.1% Error. CH = 0.01 pF rnA 10 VTH 0.8 SViiil 80 Icc IlS 2.4 pA V dB ±6.5 rnA V±=±15Vto±18V ftt{EC IlPC494 SWITCHING REGULATOR CONTROL CIRCUIT NEe Electronics Inc. Description Pin Configuration The JlPC494 is a switching regulator controller designed for use in switch mode power supplies (SMPS) using Pulse Width Modulator (PWM) technique. The on-board control circuitry includes a voltage reference, dual error amplifiers, oscillator, pulse width modulator, pulse steering flip-flop, dual output drivers and dead time control circuit. The JlPC494 is available in the plastic DIP package and the G2 mini flat package. DeadTime Control Features o Complete PWM power control circuit o Adjustable dead time (0 to 100%) o No double pulsing of same output during load o o o o transient condition Dual error amplifiers have wide common mode input voltage capability (-0.3 V to V+ - 2 V) Circuit architecture provides easy synchronization Uncommitted outputs for 250 mA sink or source Equivalent to TL494 83-002491 A Equivalent Circuit v+ Ref. Out 12 o---------------~ Output Control 13 ,.0-------------1 GNDO---------------~ Dead-Time~ Control Non-Inv. Input o-------------j Inv. Input 0------------1 16 Non-Inv. Input Inv. Input ,.o--------------j o--------------j Feedback o------------------~ 83-0024908 7-3 t-{EC pPC494 Ordering Information Recommended Operating Conditions Limits Part Number Package Temperature Range pPC494C Plastic DIP -20°C to +85°C pPC494G2 Minillat -20°C to +85 °C Paramorer S:pply TA = 25°C 41 V Error Ampillier Input Voltage V+-0.3V Output Voltage 41 V Output Current 250 mA TDtal Power Dissipation. CPackage 1000 mW Total Power Dissipation. GPackage (Note I) 780 mW Operating Temperature Range -20 to +85°C Storage Temperature Range -65 to +125°C Note: 1. Mounted on 5x5 em Glass-Epoxy PC board (thickness 1.6 mm) Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 12 V+ VDltage Absolute Maximum Ratings Supply Voltage Symbol Min. Typ. Max. Unit 40 V Output VDltage Vo Output Current 10 -0.3 200 mA ErrDr Amplifier Sink Current 10 -0.3 mA Timing CapacitDr Ct 0.47 10.000 nF Timing Resistance Rt 1.8 500 kG OsciliatiDn Frequency lose 500 kHz Operating Temperature TOPT +85 cC -0.3 Tost Conditions 40 40 -20 Electrical Characteristics V+ = 15 V, f = 10kHz, -20::; TOPT::; +85 ce, unless otherwise noted Limits Parameter Typ. Max. Test Conditions Symbot Min. Unit Output VDltage VREF 4.75 5.25 V Line RegulatiDn REGIN 25 mV 7 VoS V+ oS 40 V.IREF = 1 mAo TA = 25°C lDad RegulatiDn REGL 15 mV 1 mA::; IREF::; 10 mAo TA = 25°C 0.03 %rC Reference Section Temperature CDeHlcient ShDrt Circuit Output Current 0.01 IREF = 1 mAo TA = 25°C -20°C::; TA::; +85°C.IREF = 1 mA ISHORT 35 mA VREF = 0 lose 10 kHz Ct = 0.01 pF. Rt = 12 kn 10 % 7 VoS V+ oS 40 V. Ct. Rt cDnst.. TA = 25°C % O°C oS TA oS +85°C. Ct = 0.01 pF. Rt = 12 kn % 7 V oS V+ oS 40 V. Ct = 0.01 pF. TA = 25°C. RT = 12 kn Oscillator Section Frequency Standard DeviatiDn DI Frequency Frequency Change with Temperature .t.fILI.T Frequency Change with VDltage .t.fI.t.V 2 Dead-Time Controt Section Input Bias Current Input ThreshDld VDltage 7-4 -2 Ib Maximum DUty Cycle (Each Output) -10 45 VTH 0 3.3 /lA ooS VIN oS 5.25 V % VI = 0 V Zero duty cycle. maximum duty cycle ~EC j.lPC494 Electrical Characteristics (Cont.) vee = 12 V, TA = 25°C, unless otherwise noted Limits Parameter Symbol Min, Test Conditions Typ. Max. Unit 10 mV VOAMP = 2.5 V 25 250 nA VOAMP = 2.5 V /lA VOAMP = 2.5 V 7 V,; V+,;40V Error Amplifier Section Inpul OHsel Voltage Vio Inpul OHsel Currenl lio Inpul Bias Currenl 0.2 Common Mode Inpul Vollage, low -0.3 V Common Mode Inpul Voltage. High VCC-2 V 7 V,; V+,; 40 V dB VOAMP = 3 V Open loop Vollage Ampillicalion AVOL Unity Gain Bandwidlh 60 500 GBW CMRR Common Mode Rejeclion Ratio Output Sink Current Output Source Current 74 65 BO 0.6 10 SINK 0.3 10 SOURCE -2 10 SINK 0.3 650 kHz = 0.7 V mA VOAMP mA VOAMP = 3.5 V PWM Section 4 Input Threshold Voltage Input Sink Current 4.5 0.6 V Zero Duty Cycle mA V!PIN3j = 0.7 V 100 /lA VCE = 40 V. V+ = 40 V -100 /lA V+ Output Section Collector CuioH Current ICBO Emitter CutoH Currenl ICEO 2 = VCO = 40 V ...V.C.E~S.A!I.••.....•....1: 1.••.•.. 1:~ ...••. Y.....I~.=: .2.0.0. ~~'. ~~.=: .0: .c?~~?~ ~~!I!e~ ......•......•....• VCE!ONj 1.5 2.5 V IE = 200 mA, Vc = 15 V, emitter lollower Collector Saturalion Voltage OUlput Voltage Rise Time, Common Emitter tr 100 200 ns V+ = 15 V, RL = 150 n, TA = 25°C Oulpul Voltage Rise Time. Emitter Follower Ir 100 200 ns V+ = 15 V. RL = 150 n. TA = 25°C Output Voltage Fall Time, Common Emitter If 70 200 ns V+ OUlput Voltage Fall Tima, Emitter Follower tf 70 200 ns V+ = 15 V. RL = 150 n, TA = 25°C o 12.5 mA V+ = 15 V, all olher inputs and outputs open mA V!PIN4j = 2 V, see ligure 1 = 15 V, RL = 150 n. TA = 25°C Total Device Siandby Current ICCSB Oias Current 10 Nole: Standard deviation is a measure of the statistical distribution about the mean as derived from the formula: u = V _c=~,,:-:-(X_n--:=_X)_2 n=1 N 7-5 ~EC pPC494 Test Circuit Test Circuit 15 V (4) Test Circuit Test Input 1500 2W RL v+ Dead Time 1500 2W C, 1-+----4>-0 Output 1 (3) I-.....----<>Oulput 2 83-002492A Typical Voltage Waveforms Voltage aiel Voltage at C2 Voltage aley AIi .AA.AAA AAA Ii AAAA AAAA A.A IrrrrrrrryvyyyYVrryrYI Dead Time Control Input Function Table Output Control Input (13 pin) 7-6 Output Function At Ref-Out Normal push-pull operation Grounded Single-ended or parallel output ttiEC pPC494 Operating Characteristics TA =25 ± 2°C, = 15 VIN V Maximum Power Dissipation Mis-Operation Prevention Circuit Characteristics "-}P [: 1.2 Thermal Resistance R8JA ;= 125 °C/W ~ 1.0 ~ ~ o i° 0.8 .~ C ..;°5 0.5 ~:" ~ ......... 0.4 E .; ;;: 0.2 o o 25 50 100 75 125 Ambient TempElrature (OC) Supply voltage (V) Reference Voltage vs. Supply Voltage Reference Voltage vs. Temperature 40 V+ = 15 V IREF=lmA € ;;E- V 4 o 20 . o '" 0 ~ S o 0 J > 3 g s 0 / ~ .; 2 a: ~ 11 ~ ~ 1 / o II a: r--------r-------t--------t--------r-------- ~ ~ o 10 15 20 25 30 35 ~ -50 ~------~------~25~----~5=0------~7~5------~10; -25 40 Ambient Temperature (OC) Supply Voltage (V) Frequency vs. RT and CT 500 ~ 1Cr: 50 I;" ~ ! 20 10 """ ----- "--- ""- ~ I" ~ Frequency vs. Temperature v+ = ~ ........... 200 N J 10 4/:, 20 -.- '" ........ 50 Timing Resistance (kO) ~~ 0 ,~ """ '0K"- '" ...,> ..'" ~ -:::''''>0 0. 0 , " V+ = 15 V Rt=12kO Ct = 0.01 J.iF 15 V 0" 1 ~ &) ~ ~ 0 ~ -2 0 0 ......... 1--, ............ ........ ........... ~ ,z -4 ------ -- -6 ........ 100 200 500 --25 25 50 75 100 Ambient Temperature (ec) 7-7 D t\'EC pPC494 Operating Characteristics (cont.) T A =25±2°C. VIN= 15V Open-Loop Voltage Gain vs. Frequency Duty Cycle VS. Dead Time Control Input Voltage 120 v-vJv ~ ! ~~/l~~ A~ 10 20 ~ 0 30 40 50 100 / V '" iii ~ c ~ 80 .......... j 0 > ~ 60 0. ~li ~ 40 "" ...... ~ '" 0 v+ = 15 V Rt = 12 kO CI = 0.01 f.JF 20 o 10 1 100 10k lk ~ 1M lOOk Frequency (Hz) Dead Time Control Input Voltage (V) Collector Saturation Voltage VS. Output Current Standby and Bias Current VS. Supply Voltage 12 Ib I I II VeE (ON) (N~tel) HSB (Note 2) V VeE - (sat) ~ 1--- VOT = 2 V (4 pin) v+ terminal biased other terminal open. 40 80 120 Output Current (rnA) 7-8 Note 1. Note 2. 160 200 o o 10 20 Supply Voltage (V) 30 40 t-IEC pPC494 Typical Application Circuit (lC) Circuit ------OVOUI } (sense Output Terminal 01 S.M.P.S. n JP 2 GND Vee 12 V R12 1100 -Iosense R11 1100 C, +Iosense E, E, C, R, R10 1100 1100 R, 3.9 k VR, 2k R, 5.1 k C, R, 0.01 fJF 24 k Cs: recommend film capacitor 'ose =- 40 kHz VR, C, 10JiF + II 2k R, 7.5 k +5 V (VREF.) 83-001939C Connection Diagram Output Function Push· Pull Operation Output Control Input (13 pin) At Ref·Out IJPl Wiredl Output Mode Output Voltage Waveform Open Collector IRg. RIO 0 01 Emitter Follower IRII. R12 0 01 Single·Ended or Partial Output Grounded IJP2 Wiredl Lr1J"1..JlJ1IU_ Open Collector IRg. RIO 0 01 C1. C2 Emitter Follower IRll. R12 0 01 E1.E2~_O 0 7-9 ttiEC J.lPC494 Typical Application Circuits Forward Type +12 V (12) v+ C11-'(:::.a)_-+~ (9) E1 (13) Output To EA.II (Over Current Protection) Control (14) Ref Oul To EA. I (Vo Sense) GND GND 83-001941B Push-Pull Type (Isolated) v+ GND To EA. I To EA.II -!-12 V (12) (11) (10) (9) (a) (7) C, v+ E, E, C, (13) GND (14) Ref Out 83 0019428 7-10 I NEe pPC494 Typical Application Circuits (Cont.) Push-Pull Type (Non Isolated) V+ (40 Y max) (12) v+ C, (11) ., r(1_0.,)--JV\,..,..-t:~ •, (13) . + (9) VOUT C, (8) (14) Rei Out To EA.II To EA.I 83-0019439 Stepdown Chopper + V+ (40 V max.) + YOUT (12) v+ C, (11) ., (10) ., (9) I i c, ~ -" To EA.II To EA.I (Over Current Protecllon) 83-OO1944A II 7-11 t-IEC jJPC494 Synchronized Operation Mis-operation Prevention Method If synchronized operation is needed, master-slave circuit can be used. This circuit is shown below. Initially, Rt terminal of slave Ie is connected to Pin 14 (Ref Out) and internal oscillator is stopped. If the supply voltage drops below 2-2.5 V, the misoperation prevention circuit is disabled. However, the internal flip-flop is still active and each output will be high. Thus, if prevention from this condition is desired, the following circuit may be used. Synchronized Operation Mis-operation Prevention Method v+ v+ (12) OUT RT (6) (7) (12) 1 REF (14) OUT 1k CT (5) GND v+ ~ (8) GND CT (5) I I I I +next CT terminal 83-00194SA 7-12 J) 83-0D1946A (M): Master (S): Slave (6) 2.7V GND r, RT (7) 1(12) v+ 620 n RT (M) CT "t 1 REF (14) v+ 2SA1152 ftt{EC tJ PC751/752 QUAD ADDRESSABLE READ/WRITE AMPLIFIER NEe Electronics Inc. Pin Configuration Description ThetlPC751 and thetlPC752 are monolithic integrated circuits designed for reading and writing data in high performance magnetic disk storage systems, and are designed to mount on the head stack arm of hard disk units. Each IC contains four read preamplifiers, four write drivers, an output line driver, head select decoder circuitry, and fault monitoring circuits. These devices offer three modes of operation: Read, Write and Idle. v- ===~ The tJPC752 is similar to the tlPC751 in function, but provides a lower differential gain in the read mode for higher inductance and higher output heads. WS (Write Select) v+ H21 (Head 2-1) US (Unsafe) H22 (Head 2·2) we (Write Current) HOl (Head 0·1) Ne H02 (Head 0·2) Ne H31 (Head 3-1) Ne H32 (Head 3-2) OX (Data Xl H11 (Head 1-1) OY (Data V) - " ' - - - - , - r r . - - n - r r - - - I - H12 (Head 1-2) HS2 (Head Select 2) CE (Chip Enable) v-==:::::::J L.:::===GND All signal levels and current specifications are fully IBM 3350 head and support arm compatible. 83-002583A Electrical Characteristics Ordering Information Package Operating Temperature Range pPC751 B Ceramic Flat DoC to +70°C pPC752B Ceramic Flat DoC to +70°C Part Number r;::=== GND HS1 (Head Select 1) Absolute Maximum Ratings Test Conditions (unless otherwise specified) Parameter Range Unit VWS ± 0.01 -4.00 ± 0.01 0.00 ± 0.01 3.50 ± 0.01 000 + 0.01 . - 0.00 6.00 V+ VVWS Positive Supply Voltage -0.6 to 7.0 V VCE Negative Supply Voltage -5.5 to 0.6 V Lh Max. 0.1 0.3 to v+ +0.3 Rh Max. 0.01 v- - Input Voltage Storage Temperature Range -65 to +150°C VCT oto +70°C VCT Operating Moving-Air Temperature Range Operating Junction Temperature Range +150°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections 01 this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Read/Write/ldle Read Write Read/Write pH ± 0.01 3.50 ± 0.01 6.00 ± 0.01 200 ± 1 RU 101 RL2 IWC IWC 40 Ambient Temperature 25 ± 1 0 Read/Write/ldle Read/Write/ldle Read 0.00 VUS Mode Read/Write/ldle V Write Read/Write/ldle D Read/Writelldle V Read/Write/ldle 0 mA Read ±1 ±2 mA Write °C Read/Write/ldle Recommended Operating Limits Head Selection Table Limits Fatamelef Mi~. Max. ~nil Mode v+ 5.7 6.3 V Read/Write/Idle V- -4.2 -3.B V Read/Write/ldle v+ V Read/Write/ldle Unsafe Voltage Head Center Tap Voltage Write Current (lwC) 4 3.2 + 0.3 Head Setected VHSI VHS2 VLHS VHHS o VLHS VLHS 3.B V Write 45 rnA Write VLHS 7-13 t-{EC JlPC751/752 Connection Diagram r-~--------------------------------l ~ rI T,we LJ I I I I ws¢.-- RL1 ~ 1 1 Write Select ~ T I HS2J. T VH ' I I I I I I I I I I ~I <:: I f Read Pre-Amp Chip Enable ~ ~ .l ~~!=r > "t Read Pre-Amp Head 0 - Head 1 Head 2 - Head 3 ~ .J Write Driver > "r Read Pre-Amp ~ L!,Write Driver > I H01 11- "1 L__________________________________ I tvus I -t> I I I I I VHS 11 .l ~~!~r I I I veE MARS Unsafe Read Pre-Amp Read Amp N I A -I I I lOv HS11 t t I T RL2 CE t Iwe Gale I I I I ox Vws lus l I I I I I I I H02 H11 I~ I I I I I l H12 H21 I:}I I I I I I 1 H22 H31 I:}'I I I I I JI H32 -::- l~ 83-Q02584C 7-14 ttlEC /lPC751/752 Mode Select The circuit has three modes of operation: Read, Write and Idle. The state of the Chip Enable and Write Select determines the mode of operation as shown in the following tabie. Mode Select Limits Test Conditions Min. Max. Unit 5.5 6.3 V Idle 0.0 0.7 V Read/Wrile IHCE -110 -50 pA Idle, VCE = V+ - 0.5 V ILCE -1.3 -0.7 mA Read/Wrile, VCE = 0.0 V Wrile/ldle Parameter Chip Enable Write Select 3.2 3.8 V -0.1 0.1 V 0.35 2.7 mA Wrile/ldle Ilransilion unsafe currenl oH) 0.7 Wrile Ilransilion unsafe currenl on) Read/Idle ......................................................................................... IHWS 3.5 mA ILWS 0.1 mA Read/Idle Switching Delay 0.5 JJ.S All modes Supply Current Head Select Limits Parameter Min. Max. 20 mA Read/Wrile ICCID 150 pA Idle IEERW 70 mA Raad/Wrile IEEID 40 mA Idle ICCRW 12 Test Conditions Unit Head Select Sum of all head input currents with Iwe = 0 Limits Test Conditions Max. Unit IHcIW) 3.0 mA IHCIR) 0.16 mA Read, VCT = 0.0 V mA Idle, VCT = 3.5 or 0.0 V IHCIID) Min. 0.10 Limits Parameter Total Head Input Current Parameter One of four heads may be selected by controlling the state of two head select inputs. The head is selected as specified below: Wrile, VCT = 3.5 V Min. Test Conditions Max. Unit VHHS -0.97 -0.61 V Temp VlHS -2.38 -1.52 V Temp IHHS 240 pA ILHS 60 pA Swilching Oalay 50 ns = DoC = DoC - 70°C 70°C 7-15 II NEe pPC751/752 Read Mode (pPC751 B) In the Read mode the circuit functions as a low noise differential amplifier. The state of the head select inputs determines which amplifier is active. Read Mode (pPC751 B) Limits Min. Parameter Max. Unit 18.8 pF Test Conditions Input Current oillanntial Input Capacity VIN = 0 V n VIN = 0 V. 25°C ......................................................................................... 585 Dlllarential Input Resistance (Damping Resistor) 915 565 915 0 VIN = 0 V. DOC ......................................................................................... 585 Output oHset Voltage Common Mode Output Voltage oillerential Gain -0.75 984 n 100 mV -0.50 V VIN = 0 V. 70°C VIN = 0 V 28 43 V/V VIN = 1 mVp-p. oVoC.1 = 300 kHz. 25°C: ......................................................................................... 30 45 V/V VIN = 1 mVp-p. DVoC. I = 300 kHz. DOC: ......................................................................................... 27 Gain Linearity (DC) 40 0.9 Bandwidth V/V 1.1 30 MHz VIN = 1 mVp·p. OVOC. I = 300 kHz. 70°C Vo (VIN = 5 mY) - Vo (VIN = 0 mY) / 5.0 mV Vo (VIN = 0.5 mY) - Vo (VIN = 0 mY) 5.0 mV liN = On. VIN = 1mVp.p Gain@low =-3dB Gain @ 300kHz Input Noise 6.6 /lVRMS VIN = 0 V. liN = 0 n. 15 MHz power bandwidth Common Mode Input to Dillanntial Output Rejection Ratio 45 dB VIN = 5 mVp-p. DVDC. I :s 5 MHz Power Supply Rejection RatiO (referred to the avCC or a VEE = 0.1 Vp-p input) 45 dB VIN = 0 V. I:s 5 MHz Channel Separation 40 Unsafe Carrent 40 dB VIN = 1 mVp-p. OVDC. I = 300 kHz. three channels driven 0.1 mA Wrlle Current = 0 mA 45 mA Write Current = 45 mA Read Mode (pPC752B) The same as pPC751 B except for the following characteristics. Read Mode (pPC752B) Limits Parameter Min. Max. Unit TBst Conditions Output oHset Voltage ......8:~ .......... !~:~ oiHerential Gain 7.5 Gain Linearity Input Noise 7-16 (~C) .......... ~~~ ....... y!~ ~ ~ ~~p:~ •• ~~~~••f.~~~~.k.H~•. ~~~~ ...•.....•••.•••• 8.5 13.25 V/V VIN = 1 mVp-p. OVDe.f = 300 kHz. DoC ......................................................................................... 0.9 12.5 V/V 1.1 25 VIN = 1 mVp-p. oVoC.1 = 300 kHz. 70°C Vo (VIN = 5 mV) - Vo (VIN = 0 mY) /5.0 mV /lVRMS Vo (VIN = 0.5 mY) - Vo (VIN = 0 mV) 5.0 mV VIN = 0 V. liN = 0 n. 15 MHz power bandwidth NEe pPC751/752 Write Mode In the Write mode the circuit functions as a current gate. Externally supplied Write current is gated by the state of the head select and data inputs to one side of one head. Write Mode Limits Parameter Min. Max. Test Conditions Unit Differential Input Voltage 0.225 Single Ended Input Voltage -2.0 -0.45 V OX DY Input Current -2.0 +2.0 mA V Current Gain 0.95 1.0 Write Current Voltage -3.7 -3.0 V IWC = 45 mA Hud Current Transition Time 15 ns IWC = 45 ms. LH = 0, 1= 5 MHz Head Current Switching Delay Time 15 ns IWC = 45 ms, LH = 0, I = 5 MHz ns IWC = 45 ms, LH = 0, I = 5 MHz; data rise and lall time SIns Head Current Switching Hysteresis IWC = 45 mA 0.1 mA IWC = 30 mA, 1= 2 MHz. LH = 9 JlH ......................................................................................... Unsale Current Unsale Switching Delay Time . . . . . .~O......................... ~~........ I~~ 20 mA IWC ~ .3~. ~~'. ~ ~ ~. ~~~'. ~~.=:.~ ~~ = 45 mA, RH = 00 .................. . one side 01 head only 1.0 Jis IWC = 3D mA, 1= 2 MHz, LH = 9 JiH ......................................................................................... ..... .. :~ ........... ~.~ ........... ~~ ........ I~~ ~ .3~. ~~'. ~ ~ ~.~~~,. ~~ .=:.~ ~~ .................. . 4.0 JiS Unselected Head Current 1.0 1.5 mAo·p Differential Head Voltage 9.0 Vo·p IWC = 45 mA, RH = 00 IWC = 45 mA, 1= 2 MHz, LH = 9.5 JlH IWC = 45 mA, LH = 10 JlH II 7-17 IlPC7 51/7 52 7-18 NEe NEe NEe Electronics Inc. pPC754 MAGNETIC SERVO HEAD PREAMPLIFIER Pin Configuration Description The tJPC754 is a two stage wide band differential amplifier which features a very narrow gain range and 30 MHz bandwidth. This device is designed to be used primarily as the preamplifier for the servo head of the model 3348 head/arm assembly. Features D Very narrow gain range D 30 MHz bandwidth Ordering Information Part Number Package JlPC754D Ceramic DIP Operating Temperature Range ,uPC754D Note: Pin 8 cannot be connected to any circuit, Absolute Maximum Ratings Power Supply Vollage Differential Input Vollage 83-002S85A -12 V ±1 V Connection Diagram Operating Temperature Range Storage Temperature Range -65 to +15D O C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Output 1300: Note: A O.1I1F ceramic capacitor is recommended for good power supply noise fillering. 83-002S86A 7-19 II t'tIEC pPC754 Recommended Operating Conditions Limits Parameter Symbol Min. Typ. Supply Vollage V- Inpul Signal VIN Ambienl Temperature TA Max. -7.45-8.3 -9.15 Unit Test Conditions V mVpp 0 70 °C Electrical Characteristics TA = 25°C, V- = -8.3 V ±10% Limits Parameter Symbol Min. Typ. Max. liD 77 93 Bandwidth 8W 10 30 Inpul Resistance RIN 800 1000 Input Capacitance CIN Differential Gain Output Dynamic Range (Differential) 3 tcc Output Offset Vos Equivalent Input Noise PSPR 50 65 mV RS 14 JlV RS dB % -0.2 %/oC 70 dB 7-20 = 1300 ±600 Gain Sensitivity (Temperature) 55 RL V- = -9.15 V ±1.3 eMRR = 2 mVpp rnA 35 Gain Sensitivity (Supply) CMRR, tnput Relerred = 130 0 VIN 0 mVpp 26 RL pF 350 Power Supply Current PSPR. Input Relerred MHz 1250 Test Conditions Unit = 0, RL = 130 0 = 0, RL = 1300, BW = 4 MHz RS = 0, I:S 5 MHz Rl = 1300 TA = 25°C to 70°C, RL = 130 0 I:S 5 MHz t-IEC pPC1042 SWITCHING REGULATOR CONTROL CIRCUIT NEe Electronics Inc. Description Pin Configuration The tJPC1042 is a switching regulator control circuit designed for use in Switch Mode Power Supplies (SMPS). The tJPC1042 uses the Pulse Width Modulator Technique (PWM) and features on chip voltage reference, dual error amplifiers, oscillator, pulse width modulator comparator, pulse steering flip flop, dual phase output drivers, and deadtime adjustment. The tJPC1042 is ideal for forward and push-pull converters with minimum external circuitry. + InpulA Compensation 1 -lnpulA Compensation 2 GN02 Compensation 3 Co + Input B C. - Input B VREF Dead Time AdJ, GND1 ' - -_ _..--Jr 83-002495A Features Ordering Information D Internal oscillator has symmetrical triangular waveform D Adjustable dead time (0 to 100%) D Includes a misoperation-preventing circuit at low input voltage D No double pulsing of outputs D Error amplifier II can operate with 0 V input voltage level Part Number Package JJPC1042C Plastic DIP Operating Temperature Range Equivalent Circuit I-------------------------~ I 11 15 V+ I I I I I ~ I RT 10 CT I I I LowV. Stop m rh DAdl. Compen- 3 satfon 2 .,...Input A -lnpulA Compensation 1 L I I I I Oscillator ~ 1T F/F 01- ~ J J .,-f" com p I 2 1 I I E"., Amp. 1 ( +5V I-bL B '" +5V :1 I Error Amp. 2 ~------------------- 13 Co I I I l ,. GND2 I 5 I 6 I I : II 12 I I I I Comp.2 I I I I I N\J\A-K I i I 16 I I 9HV I 7 HV Ref. Voltage I 9 I I I I + Input B -Input B 4 Compen. satlon 3 8 0 GND1 ______ I 83-002494C 7-21 ~EC tJPC1042 Recommended Operating Conditions Absolute Maximum Ratings TA = 25°C Limits Supply Vollage Output Currenl [Each Output) 30 V Parameter 40 V Supply Vollage V+ Oulpul Vollage Vo OUlput Current 100 mA 40 mA Reference Output Current Total Power Dissipation 800 mW Operating Temperature Range -20 to +85°C Storage Temperature Range -40 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Symbol Min. Typ. 10 5 Reference Output Current IREF 0 Oscillation Frequency fose 20 Max. Unit 12 16 V 24 32 V 20 40 mA mA 40 100 kHz Electrical Characteristics V+ = 12 V, T A = 25°C unless otherwise noted Limits Symbol Min. Typ. Max. Output Voltage Vo 4.6 5.0 5.4 V Line Regulation REGIN 13 35 mV Load Regulation REGL -2.5 -10 mV 750 pV/oC Parameter Test Conditions Unit Reference Section Ripple Rejection VREF orilt d8 10 = 0 8 V oS V+ oS 20 V, IREF =0 ooS IREF oS 20 mA f = 120 Hz RR 60 AVREF/t.T 200 V+[L to H) 7.5 V OoSV+oSI2V VHYS 0.5 V OoSV+::s12V -20°C::; TOPT::; +85°C Low Voltage Stop Section Startup Voltage Hysteresis Vollage Oscillator Section Maximum Oscillation Frequency fmax kHz 100 IniUal Accuracy ±5 ±IO % RT, CT constant Temperature Stability -6 -10 % -20°C::; TOPT::; +85°C Output Voltage [High) VOH Output Voltage [Low) VOL V 4 2 Line Frequency Stability V ±I ±2 1% 8 V::; V+::; 20 V Error Amplifier t Section Input Offset Voltage Input Offset Voltage Drift Input 81as Current Vio ±2 ±IO mV t>.Vlol t>. T ±4 ±10 pV/oC 18 +1.3 +10 pA Large Signal Voltage Gain AVOL 72 Common Mode Input Voltage Viem 1.2 Common Mode Rejection Ratio eMRR Small Signal 8andwidth GBW 7-22 d8 87 4.0 70 -20°C::; ToPT::; +85°C V dB MHz AVI = 0 d8, CI = 560 pF, C2 = 150 pF Test Conditions t-IEC JlPC1042 Electrical Characteristics (Cont.) V+ = 12 V, TA = 25°C unless otherwise noted Limits Symbol Parameter Min. Typ. Max. ±3 ±10 mV ±3 ±10 p.V/oC -1.5 -10 p.A Test Conditions Unit Error Amplifier 2 Section Inpul Ollsel Voltage Vlo t.Vlo/ t. T Input Offset Voltage Drift Inpul Bias Current Ib large Signal Voltage Gain AVDL 72 Common Mode Input Voltage Vlcm 0 100 dB 3 Common Mode Rejection Rallo CMRR 70 Small Signal Bandwidth GBW 1.2 V dB MHz Maximum Oulpul Currenl 1.0 AV2 = 0 dB, C3 = 220 pF, C4 = 470 pF rnA Dead Time Adjustment Section Inpul Bias Currenl Ib -4.5 p.A Inpul Voltage [0% Duty) VIN 1.35 V Inpul Voltage [100% Duty) VIN 3.3 V Output Section Colleclor 10 Emiller Voltage VeE Colteclor 10 Emlnar culon Current ICED Colleclor Saluration Voltage V 40 0.55 VCE[SAT) 10 p.A 0.7 V IC= 1 mA Ic=20mA os .................................................................. IC = 20 mA, V+ = 12 V, Rl Risa Time Ir 80 Fait Time If 70 ICCSB 12 Tolal Siandby Currenl ~ 560 0 ns 15 mA V+ = 20 V, IREF = 0 Operating Characteristics TA = 25°C Oscillator Frequency vs. Maximum Power Dissipation 1.2 RT and CT 1M II V+=12V /:r 1.0 ........... 0.8 ~ 0.6 0.4 ...... 100 k ....... ~w ........ 10 k ....... ...... 2200 pF 0.2 i"-... y- r- r-/_ r-- 1k 50 75 Ambient Temperature (Oe) 100 125 o ~ ---- ~- f---- r'-/-...,..-:::: .700 P. F ; ' F / 0.01 JiF 25 ~20pF /470 PF 1000pF 20 -----r--- 40 60 80 100 Timing Resistor (kO) 7-23 !\fEe JlPC1042 Operating Characteristics (Cont.) TA = 25°C =9;J Error Amplifier I~ AV1 vs. Frequency 120 1--_ _+-__ 100 ! .. '" . I +-11 III 1--~h,....~4.... c C1 C2 560 pF 150 pF 1000 pF 560 pF - - 1 4700 pF 1500 pF 0.047 JiF 4700 pF 3 + 2 J :~ iii ff V+::= 12 V i= ~ V 8 10M ~ V c "'~ 1M 100 k Output Section Rise Time and Fall Time vs. Collector Current Correct Saturation Voltage vs. Collector Current 10 i ~ 10 k Frequency (Hz) Frequency (Hz) € C, 470 pF 1000 pF 40 <' / 12 .s c ~ 11 II " --r--- v+ = 12 V I--- I ,Iii I o 10 15 20 Total Standby Current (rnA) 7-24 I 25 II 30 -25 25 50 Ambient Temperature (0C) 75 100 NEe JlPC1042 Typical Application lose ::- 40 kHz + V+ (8 to 16 V) GND 2 Loop Gain { AV1(Ll=~ AV1(L) 2.5 k =, RF2 100 RF2; RF2 Feedback Resistor for Gain Control Normally: C1-C4 Capacitors tor Phase Compensation 5k RF2 (100k) '=; - AV2(L) =. - 60 dB 40 dB R, RF2 5k AV1(L) (3.6k) (100 k) 50k 100 R1 (6.8 k) C, (10p) II c, Cs: Soft Start Capacitor Vo Sense -10 Sense R1. R2: Resistor lor Dead Time Control (-20 to -50 mY) 83-002504C 7-25 ttlEC pPC1042 Internal Waveforms (Timing Charts) Oscillator Waveform Triangular Oscillation Output 2V Dead Time Adj. Input Voltage (Pin 7 Input Voltage) Error Amplifier Output Voltage (Pin 3 Output Voltage) Comparator 1 Output T· Type Flip- Flop Input (NAND Gale Output) T-Type FlipFlop Q Output T-Type FlipFlOp 0 Output I II ~ II I -----, I Comparator II Output OuiputCA ON OutputCB LJ ON U u 83-002S05C 7-26 NEe NEe Electronics Inc. pPC1060 PRECISION 2.5 VOLT REFERENCE REGULATOR Description Pin Configuration The pPC1060 is a precision low voltage reference regulator which uses the band gap voltage reference technique. It features low temperature drift and low supply current drain. The pPC1060 is ideal for use in instrumentation and D/A converter applications. Input C Output [ GNO c: 1 7 6 :.J NC :.J NC :.J NC 5 J 8 \J 2 tlPC1060C 3 NC[ 4 NC 83-002507A Features o o o o Ordering Information High accuracy: Vo = 2.5 V ± 1% Low temperature drift: t:,yo/6T ::; 40 ppm/oC Low supply current: Icc::; 1.5 mA Equivalent to MC1403 Part Number Package IlPC1060C Plastic DIP Operating Temperature Range Equivalent Circuit Input R13 R" Q13 Q14 Q, Q, R8 R, R, Q11 II Output R, R, C, GND 83-{){125068 7-27 ,..,EC pPC1060 Recommended Operating Conditions Absolute Maximum Ratings Inpul Voltage Limits 40 V Power oissipalion Parameter 350mW Operating Temperalure Range Min. Input Voltage Range -20 to HO°C Storage Temperature Range Symbot -55 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Output Current 10 Power Dissipation Po Operating Temperature TOPT Typ. Max. Unit 4.5 40 V o 10 mA 350 mW +70 C' -20 Electrical Characteristics T A = 25°C, VIN = 15 V, 10 = 0 Limits Parameter Test Conditions Symbol Min. Typ. Max. Unit Vo 2.475 2.50 2.525 V t.Vo/t.T 40 ppm/oC -20'C 05 TA 05 +70'C Vo 7.0 mV -20'C 05 TA 05 +70'C Line Regulation REGIN 4.5 3.0 mV 15 V 05 VIN 0540 V 4.5Vo5VINo515V Load Regulation REGLoAO 10 mV 60510o51omA Input Current liN 1.5 mA Ripple Rejeclion Ralio RR 90 dB 5 V 05 VIN 05 15 V, 10 = 0 f= 120Hz Output Noise Voltage en 80 JlVp.p 4.5 V 05 VIN 05 40 V 005 10 05 10 mA 10SHoRT 17 mA Vo = 0 Output Voltage Temperature Drill Output Voltage Output Voltage Change Output Short Circuit Current Typical Circuit Input t 1:'" ,uPC1060 Output leo 0.111 GND ~ 83-0025086 7-28 ttiEC jiPC1555 PRECISION TIMER CIRCUIT NEe Electronics Inc. Pin Configuration Description The J.lPC1555 is a highly stable precision timer capable of producing oscillation in the astable mode and accurate time delays in the monostable mode. In the astable mode as an oscillator, the free running frequency and duty cycle are accurately controlled using two resistors and a capacitor. In the monostable or time delay mode, only one external resistor and capacitor is required. The totem pole output drivers can sink or source up to 200 rnA making these devices ideal for driving small speakers, transducers, and single ended AC/DC converters. Features D D D D Operates in both astable and monostable mode Output can drive TTL loads Adjustable duty cycle NE555 direct replacement tJ PC1555C 83-002568A Equivalent Circuit R, 5k R11 6.2 k 0" R12 3.9k R, 7.5 k Output 5 Control Vottage 213 Vee R, 10 k R, 5k R, 100 R, 83-0025678 7-29 II NEe IlPC1555 Absolute Maximum Ratings Ordering Information TA = 25°C Voltage Between V+ and GND Puwer mSilpaLlOii, C Package 600mW Power Dissipation. G2 Package 440mW oto +70°C Operating Temperature Range Storage Temperature Range Package Operating Temperature Range I'PCI555C Plastic DIP O°C to +70°C I'PCI555G2 Plastic Miniflat O°C to +70°C Part Number 18 V -55 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Electrical Characteristics TA = 25°C, V'= +5Vlo +15 V Limits Parameter Supply Voltage Supply Current Symbol Min. V+ 4.5 Icc Typ. 16 10 Threshold Voltage Vlh 2/3 V+ Threshold Current Ith 0.1 Trigger Voltage VTRI6 Trigger Current ITRI6 Reset Vollage VRST Reset Current IRST Control Voltage Level Max. 15 Test Conditions Unit V mA V+ = 5 V. RL = mA V+ = 15 V. RL = 00. Vo = 0 V 00. Vo = 0 V V 0.25 5 J.1A Note 1 V V+=15V 1.67 V V+ = 5 V 0.5 J.1A .............................................................................. 0.4 0.7 1.0 0.1 V mA 9.0 10 II V V+= 15V .............................................................................. 2.6 3.33 4 V V+ = 5 V V+ = 15 V. ISINK = ID mA .............................................................................. Outpul Vollage Orop (Low) 0.1 0.25 0.4 0.75 V V+ = 15 V. ISINK = 50 mA 2.0 2.5 V V+ = 15 V, ISINK = 100 mA .............................................................................. 2.5 V V+ = 15 V. ISINK = 200 mA .............................................................................. 0.1 0.35 V V+ = 5 V.ISINK = 5 rnA 12.5 V V+ = 15 V. ISOURCE = 200 rnA .............................................................................. 12.75 13.3 V V+ = 15 V.ISOURCE = 100 mA 2.75 3.3 V V+ = 5 V.tSOURCE = 100 mA Rise Time Output 100 ns Fall Time Output 100 ns Output Voltage Drop (High) Timing Error, Aslable: Initial Accuracy Drift wilh Temperature Drift with Supply 0/0 RA, RB = 1 k to 100 kO. C= 0.1 J.1F 50 ppm/oC ......................................... 0.01 O/O/V Notes: 1. This will determine the maximum value of RA + Rs for 15 V operation. The maximum total resistance is 20 MO. 7-30 !ttIEC J1PC1555 Operating Characteristics TA = 25°C Minimum Pulse Width Required lor Triggering 1.2 I Supply Current vs. Supply Voltage 12 I v+ = 15 V 10 1.0 VI ]: ~ l' ..~ ,.."g 0.8 0.6 TJ~1250CI E 0.' / 0.2 ......tt. ~ 'I -20 o e ~ VV VTJ =(5 C .& ~ ..... 0 ~ ~ ........::: I'""'" ~~ -::::::-- ~ "- 25°C ~ -:"',)OC_ 15 10 Lowest Voltage Level of Trigger Pulse (V) Supply Voltage (V) High Output Voltage Drop vs. Output Source Current Low Output Voltage vs. Output Sink Current 10 l - i-- ~ l - f- r- / -20°C/ 1 l5°C/ -- t-- JL/--;I V/ V 20CC~ 25°C, '-.. 70°C "] J/ _L ~OOC~ 0.1 ~ ~ 1-"1"'" 0.01 10 30 50 100 1.0 5.0 3.0 ISOURCE (rnA) Low Output Voltage vs. Output Sink Current 50 30 100 Low Output Voltage vs. Output Sink Current 10 10 V+-10V V+=15V 20 c e 25"C ....... - L. ~ )'JI 70°C ~ S ~ 10 ISINK (mA) .-l 20°CI 1 25°C 25°C '-.. 0.1 70"C ..& b:=== ~::::::-~ -II ~ ~V I'""'" ..::::;: i 00C ~ 20 e ~ 0.Q1 1.0 .., ....-:; ........-:::: ~c V" 70°C o. 1 r-:;...- V JQ 10 ISINK (mA) 30 50 100 0.0 1 1.0 3.0 5.0 10 30 50 100 ISINK (rnA) 7-31 II t¥EC pPC1555 Operating Characteristics (Cont.) TA = 25°C Discharge Transistor (Pin 7) Voitage vs. Sink Current Output Propagation Delays vs. Vuaage Le-vel oi Trigger Puise '.2 TA = +25°C V+=5V '.0 ! ic c ° V :::- 0.8 V+~5V / 0.6 ~ :!. e 0.4 "- VV ~V ~ '00 1--+++-+-+-70t-OCt-t-+--+--t-I-t-i-~-Il,l'-I-t-t--T--r ......- / f-- ~ / 0.2 V+ =10V, 15 V I I I 0.2 0.' 0.3 '.0 ':-o.:::o,..L..J.--'-~o:':.,-.l..'-'--'---'----'-L..L-'----,~o----'.--'-'-'---:'=00 ISINK (mA) Pin 7 Lowest Voltage Level of Trigger Pulse (V) Applications The total period for one cycle of output HIGH and output LOW is: Monostable Operation When the timer is operated as a monostable multivibrator, one external capacitor (C 1), and one external resistor (R 1), are used as shown in figure 1. When the trigger input is reduced below 1/3 V+, the timer internal flip-flop is set. This releases the short circuit across the external capacitor and the Q output goes HIGH. The voltage across the capacitor voltage reaches 2/3 V+, the internal comparator resets the flip-flop and the external capacitor (C 1), is rapidly discharged, provided the trigger voltage is returned above 1/3 V+ (figure 2). The output is now in LOW state and a new timing cycle may be initiated. The time that the output is in the HIGH state is given by 1.1 R.C., or can be taken directly from figure 3. Both the charge rate and internal threshold are directly proportional to the supply voltage. Thus, the timer output pulse width is independent of the power supply voltage. If a LOW is applied to the reset input, the output is forced LOW and the external capacitor discharged regardless of the other inputs. t f=_1_= t (R1 + R2)C1 1 0.693(R1 + R2)C 1 The astable free-running frequency can also be found from the graph shown in figure 6. The duty cycle, the timetheoutput is LOW divided by the period, is given by: t2 R2 D------- . - t1 + t2 - Figure 1. R1 + R2 Monostable Circuit 5Vto15V {JPC1555 Astable Operation Output When the timer is operated in the astable mode, two external resistors (R1 and R2), and one external capacitor (C 1), are used as shown in figure 4. With this connection scheme, the external capacitor (C1), charges and discharges between 1/3 V+ and 2/3 V+. The charge time (output HIGH) is: t = 0.693(R1 + R2)C 1 The discharge time (output LOW) is: t2 = 0.693R2C1 7-32 = t1 + t2 = 0.693 The frequency for this period, T, is: Reset '----+---+---1 0---+---<>----1 u Control ,Io.O'"F f' III 83-002S77A I t-IEC Figure 2. pPC1555 Figure 5. Monostable Waveforms Astable Waveform t - 0 1 ms/div -- Tri ger Voltage 2 VI div I J "H" "L" / Capacitor Voltage Cl 2 V/diJ "L" -1I J "H" ,,~.J Capacitor Voltage "H" l Output Voltage 5 Vldiv 5vLv "H" "l" "H" t - 0.5 ms/div Output Voltage 1.7 V/div I I I~/ / / /1 / ~/ / L Rl = 9.1 kO, Cl = O.01I1F, RL = 1 kG Figure 3. Time Delay Figure 6. Free Running Frequency 100 100 10f----_+_ ~ . ~ 1.0 0 ~ [ il 1.0 u 11 :5 ~ 0.1 0.1 U 0.Q1 0.01 1.0 Time Delay Figure 4. 10 100 1.0 k 10 k 100 k Free Running Frequency (Hz) Astable Circuit 5Vto15V RL • f-- ~' r- 7 2 JlPC1555 OUiPUt t-- 3 61---- 4 51-- I R, Control Voltage 0.01 JiF 83~OO2580A 7-33 tJ PC1555 7-34 ttlEC NEe NEe Electronics Inc. JlPC1571 COMPANDER Description Pin Configuration The tJPC1571 is a dual gain control circuit in which either channel may be used as a dynamic range compressor or expander. Each channel contains a fullwave rectifier, a temperature compensated variable gain cell, and an operational amplifier. CRECT[A] CRECT[B] INRECT[A] INRECT[B] 1Nt:..G[A] -Input B -Input A Ras RaA This circuit is well suited for use in telephone systems, limiters, voltage control amplifiers, and noise reduction circuits. Features 1Nt:..GIB] v+ Output B ' -_ _ _--',THD Trims 83-003293A Ordering Information D Single power supply operation D Temperature compensated D Complete compressor and expander in a single package D Dynamic range greater than 70 dB D Outputs fully protected against short circuits R3 pPCI571C -IN Package Operating Temperature Range 16 pin Plastic DIP Absolute Maximum Ratings TA = +25°C Power Supply Input Voltage [Note I) Power Dissipation Storage Temperature Block Diagram THO TRIM Part Number 16V 16 V 400mW -55 to +125°C Note: 1. Applies to all input terminals. Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. vo 83-Q03294A Recommended Operating Conditions Parameter Operating Temperature Power Supply Rectifier Capacitor Symbol Limits Min Typ Max 0 70 Top V+ 6 8 CRECT 2.0 2.2 13.5 Unit °C V pF 7-35 t\'EC pPC1571 Electrical Characteristics = 8 V, eRECT = 2.2J.1F TA = +25'e, v+ Limits Parameter Power Supply Current Internal Reference Voltage V"' Change with Temperature Output Current Slew Rate S,mbol Min Icc Vrel AVre,/AT 1.7 10 SR ±10 Total Harmonic Distortion Expander Output Noise Unil 2.5 4.0 rnA 1.8 1.9 15 30 V mV/oC lunity THO -1.5 1200 1800 VII's % ppm/oC 0 +1.5 dBm 0.5 2 % dBm dB dB +20 -100 Gain Variation A VN AGA -0.2 0 +0.2 Gain Variation B AGB -0.5 0 +0.5 Compressor Output Vo -20.2 -40.4 -61.0 -20 -40 -60 -80 -19.5 -39.3 -5B.3 dB dB dB dB Expander Output Vo -10.5 -20.7 -31.5 -10 -20 -30 -40 -9.8 -19.6 -29.0 dB dB dB dB Channel Separation CS 60 7-36 Cornlitim.. s VIN =0V TA = O°C to HO°C rnA 0.2 Change with Temperature Unity Gain level Max -20 Internal Resistor Tolerance Test Typ dB TA = O°C to HO°C VIN = Vo AI = 3 kHz VIN = -30 dBm TA = 0° to HO°C I = 1 kHz to 5 kHz = -20 dB = -40 dB = -60 dB = -80 dB VIN = -10 dB VIN = -20 dB VIN = -30 dB VIN = -40 dB VIN VIN VIN VIN t\'EC J1PC1571 Operating Characteristics TA = 25°C Power Supply Characteristics Expander Characteristics +20 f: 100 Hz to 10 kHz C E :: 3 ~ :s u ~ 2 I (} I J L / -60 J V V / Noise Level 10 -80 -80 20 -60 -20 -40 Power Source Voltage (V) +20 Output Level (dB) Distortion-Output Voltage Characteristics (Compander) Compressor Characteristics 10 +20 --1.0 iii ci ~ :.:,..: -- 0 ~ :iC V '/ / J ~ / 0.1 100 Hz. 1 kHz TO kHz -20 V ] / i -40 / ,~ Noise Level ,..,. 1 '/ f: 100 Hz-10 kHz 0.1 0.01 10 1.0 -80 -80 V V V -60 II II / / 1/ 60 -40 20 +20 Output Level (dB) Output Voltage (V) Frequency Characteristics (Compander) +20 Y,N = +10dB Ii0dB Ulll iii ~ ~20 ] 8'.. 'I-- lllllB -40 lU~B -60 -80 10 I-- ........... 11111 100 1k 10k TOOk Frequency (Hz) 7-37 II t-rEC IlPC1571 Gain Cell Operation Compressor Operation The gain cell is a multiplier comprised of two transistor pairs. 1, and 12 are fixed within the IC; IG is a control (;urreni suppiied by ihe reciifier. This current determines the amount of output amplification: Using the pPC1571 as a compressor involves placing an expander in the op-amp feedback circuit. For exampie, if the input increases by 6 dB, the output is limited to 3 dB. The 3 dB increase produces a 3 dB increase in the output of the gain cell, which results in a 6 dB increase in feedback current. 10 = IG· liN IG • VIN 140pA = R, .84 Gain=---V IN (avg) v+ Vo = (gain) (VIN) Notethat op-amp feedback isAC only. CDC and the two Roc provide DC feedback to set the DC bias at the op-amp output: Vapa (~C) = (1+ REF R4 The output of the compressor will be biased at 3 V DC, assuming the internal resistors are used: R2 v~ + ROC (total) ) V 20K R3 Va (~C) = (H - ) VREF R4 Note that external resistors may be placed in series with R3 to change the gain, or with R4 to change the output DC bias. Rectifier Operation 1I2pPC1571 The output current of the op-amp is averaged by CRECT R2 then doubled to become IG: VIN IG = R, R, (avg) Gain Cell 11---1 V+ I To Gain Cell I 2Dk I I 10k I t Rl Rectifier I 0-----..., R2 10K Roc t IG ±coe R3 vIN CIN O---j + vREF 83-003301A 7-38 2Dk I: CF" I~ ~ CRECT VREF Ci~ Roc UR \-+VOUT t-iEC /1PC1571 Expander Operation When connected as an expander, the input signal is applied to both the rectifier and the gain cell. When the signal drops by 6 dB, the gain current drops by a factor of 2 so the overall gain drops by 6 dB. Thus the output level will drop by 12 dB. Gain = (1.43) (VIN (avg)) Va = (gain) (VIN) R3 CIN1 R2 '{., '. Applications A. Automatic Level Control With the rectifier input tied to VIN, a very high performance ALC can be built. Gain is inversely proportional to input level, so a 20 dB drop in input produces a 20 dB increase in gain. Circuit shown will maintain a fixed output ±1 dB from -43 dBm to +14 dBm at 1 kHz. II 'pF I 33k 33k J. VIN 1 J.IF R3 20K 'OpF 30 pF o--O---1l---'1M-~---+---l 83-003304A 7-39 IJPC1571 7-40 fttIEC ~EC pPC1663/1664 UL TRA-WIDEBAND DIFFERENTIAL AMPLIFIER NEe Electronics Inc. PRELIMINARY INFORMATION Description Pin Configuration The flPC1663 and flPC1664 are video amplifiers with differential input and output stages. An ultrahighfrequency process (h = 6 GHz) improves ac performance compared with industry-standard type 733 video amplifiers. TheflPC1663 and flPC1664 are excellent as sense amplifiers for high-density CCOs, as video or pulse amplifiers in high-resolution displays, and in communications equipment. Features D Bandwidth and typical gain 120 MHz at AVOL = 300 170 MHz at AVOL = 90 700 MHz at AVOL = 8 D Very small phase delay D Gain adjustable from 8 to 300 D Frequency compensation not required D Pin compatible (flPC1664C) with type 733 D Pin compatible (flPC1663C) with type 592 tl PC1663C 53-003086A Ordering Information Part Number Package IlPC1663C 8·Pin Plastic DIP IlPC1664C 14-Pin Plastic DIP Operating Temperature Range oto +70'C oto +70'C Absolute Maximum Ratings TA = 25°C Voltage Between V+ and V- ±8V Power Dissipation IlPC1663C 500mW Power Oissipatlon IlPC1664C 570 mW Differential Input Voltage ±5V Common Mode Input Voltage ±6V Output Current Operating Temperature Range Storage Temperature Range II tlPC1664C 83-003087A 35 rnA -20 to +70'C -55 to +125'C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating oniy and funclionai operation or the device at lhese or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 7-41 t\'EC jlPC1663/1664 Equivalent Circuit , . , - J t-.. V r-... ::t- V ~ 1 1 2 Input Output Input G1A cr-- t---o G2A 0--- t---o '-- ~ G1B Output G2B ~ "-.i ,M"'I t V "'" V V ....... "'" L- 7-42 1/ ....... 83-003088B NEe pPC1663/1664 Electrical Characteristics Operating Characteristics TA = 25°e, V± = ±6 V TA = 25°e Limits Symbol Min. Typ. Max. Parameter Gain 1 Differential Voltage Gain Gain 2 Gain 1 Gain 2 90 Note 2 8 Note 3 MHz RS = 50 0; -3 dB point ns Rs = 50 0; VOUT = 1 Vp.p ns Rs = 50 0; VOUT= 1 Vp.p 700 2.9 2.7 Ir Gain 3 2.9 Gain 2 1.6 tpd Gain 3 1.2 lio 0.4 5.0 /lA Input Bias Current Ib 9.0 30 /lA Input Voltage Range VIN 1.0 0.6 1.5 V 0.35 1.5 \I 3.4 V Input Offset Current Output Offset Voltage Gain 1 Vo (OFFI Gain 2 Output Common Mode Voltage VO(CMI 2.4 2.9 Output Voltage Swing Vo (p,pl 3.0 4.0 Output Sink Current ISINK 2.5 3.6 Supply Current Notes: 1. 2. 3. 4. Icc 15 ~6V 83-002831 A Pulse Response Gain 1 Propagation Delay 10,OOOp ~----1-----1----11---lK 170 Gain 1 Gain 2 +6V 120 BW Gain 3 Rise Time Test Conditions Note 1 300 AVOL Gain 3 Bandwidth Unit V I I ~,'W Gain 3 ,1\ V Vp.p Oul mA 24 500 mV/div Vertical 20 ns/div Horizontal mA Gain select pins G1A and G18 are connected. Gain select pins G2A and G28 are connected. All gain select pins are open. Insert adjustment resistor (0 to 10 kO) between G1A and G18 when variable gain is necessary. Attention: Due to ultrahigh-frequency characteristics, the physical circuit layout is very critical. Supply vollage line bypass, doublesided printed-circuil board, and wide-area ground line layout are necessary for slable operation. Two signal resislors connected to bolh inputs and Iwo load resistors connected 10 both outputs should be balanced for slable operation. Pulse Response I '. ~, Gain 2 1ft U Oul 500 mV/div Vertical 20 ns/div Horizontal 7-43 NEe pPC1663/1664 Operating Characteristics (Cont.) TA = 25°C Maximum Output Voltage Swing vs Frequency [Single-Ended Video U~e] Pulse Response 2,0 In ~ J\ '. Gain 1 f"",. A < Out V 0,1 I 10 100 Frequency (MHz) 500 mV/div Vertical 20 ns/div Horizontal Measurement Circuit Single-Ended Gain vs Frequency V±= ±6 V ,------, pPC1663/1664 Input 50 ~ 750 I Output 200 0 40 "" -;; 30 ~ I o---t--+---i 60 20 I"- 10 750 Gain 1 Gain 2 200 (} Gain 3 83-002838A 0,1 10 100 Frequency (MHz) Phase Shift vs Frequency -r;r-. :'--- 111111111111111111111111f5;;; 0,1 10 Frequency (MHz) 7-44 100 t-IEC pPC3423 OVERVOLTAGE "CROWBAR" SENSING CIRCUIT NEe Electronics Inc. Description Pin Configuration The tJPC3423 is an overvoltage protection circuit (OVP) that protects sensitive electronic circuitry from overvoltage transients or regulator failures when used in conjunction with an external "crowbar" SCR. v+ [ 8 ] Output 1 "-./ Sense 1 [ 2 Sense 2 [ 3 Current Source [ 4 ~PC3423C 7 J Ground 6 ] Indicator Output 5 ] Remote Activation 83~OO3247A Features Absolute Maximum Ratings D Threshold voltage easily programmed by external resistors D Programmable trip delay D 300 mA output current D Equivalent to MC3423 TA = 25°C Parameter Ordering Information Part Number Operating Temperature Range Package pPC3423C Recommended Operating Conditions Min Typ Max 6.B V Remote Activation Input Voltage 7.0 V Output Current 300 rnA 600 mW Operating Temperature Range -20 to +70 °C Storage Temperature Range -40 to +125 °C Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Unit Supply Voltage V+ 4.5 36 V Output Current 10 0 300 rnA 10Undi 0 10 rnA Indication Output Current V Sense Voltage Comment: Stress above those listed under "Absolute Maximum Limits Symbol Unit 45 Total Power Dissipation B·pin Plastic DIP Parameter IIPC3423 Supply Voltage Equivalent Circuit 114 Circuit 1--------------- I I I I 2 II ----------------1 I I +----------------+-+-0 Current Source I I Sense11 I I I I OL_ I I I I I I _ ___________ .-l L __ 7 GND 3 Sen882 5 6 Indicator Output Remote Activation 83-0032468 7-45 !\fEe pPC3423 Electrical Characteristics Y+ = 5.0 Y, T A +25°C Limits raiiimatar Symbol .'1111 TYii Vo V+ - 2.2 V+-1.8 Output Voltage Indication Output Voltage VOLllndl Vsensel Vsense2 AV. en •e/ A T Sense Voltage (1), (2) Sense Voltage Orift Remote Activation Input Current IIH Remote Activation Input Current IlL Source Current V 0.2 0.4 2.6 2.8 V 40 pA pA 10= (OOmA 10(lndi = 8 rnA -0.04 0.1 -250 Isource tr Output Current Rise Time 2.4 Test Cunuiiions Uiiii 300 pA mA/pS Propagation Delay tpd 400 0.5 Supply Current Icc 5.0 ps 8.0 rnA VIH = 2.0 V VIL = 0.8 V See Test Circuit 10 = 100 rnA pin 5 grounded, other terminals open Test Circuit 'source Test Circuit r---------------- -----------------, I I I I I I I .. Isource Sense 1[ I I 5V or 36 V I I 3V I I I I I I I I L __ ____________ --1 0utput 7 6 VEE Indicator Output Sense 2 Remote Activation 7-46 83-0032488 NEe pPC3423 Typical Applications 1. Basic Application +Vo Line Fuse 1 1--------------R, I I I Isource V, -----------------1 I I + I I 2 .--'---- I I I Sense 1 DC Power I Supply '--- VREF =2.6V If] utfi> I [l R2 L __ - - - - - - - - - - - ---7 GND 3 Sense 2 5 4 +Isource i ~ ...--'-- V r Load Q ,. : Ra 8 _~ _ _ _ _ _ _ _ _ _ _ _.JOutput - J Crowbar SCR 6 Indicator Output Remote Activation vc( + j'C Vo Line 83-0032508 7-47 NEe pPC3423 Typical Applications (Cont.) 2. Application when programmable duration of overvoltage condition before trip is needed +Vo Line _~V+ Fuse ,--------------- -----------------1 R, I I I I Isource I + I I I 2 ,.....-- Sense I I 11 I I Supply I '---- R2 I I I I +Isource 1?1 -~-~ ~-: ,.....-- V I I DC Power 4 I VREF = 2.6 V I I L __ ----------7 Load GND 3 ~ I RG OJ _ _ _ _ _ _ _ _ _ _ _ _ .J0utpUI - --Sense 2 5 8 '--r-Crowbar SeR 6 Indicator Output Remote Activation Vo Line 83-0032498 Timing Chart line Voltage Vtrip ----.. Voltage Waveform of Capacitor C Slope of Voltage Waveform Voltage Waveform Vsense Veil = 01 Capacitor C Iso~ce Duration Tpt tpl = IC's Output [pin BJ o ~s:~;;:e Vsense = 26 V [Typ.) , - - - - I_ _- - - - - - ' - - - - - ' - - - - - - - - - ----..lime 83-0032518 7-48 t-IEC pPC3423 Operating Characteristics TA = 25°C Maximum Power Dissipation VB. 1.0 Supply Voltage Ambient Temperature 0 10 lind) =0 non repetitive ~ O. 8 40 i .l! o.6 "~o-o "-"'"m~" ......... 0 c i"'00.'60'CIW i J"... .. O. 4 10 =200 mAT= 300 " ..... ........... 0 i II O. 2 10 = 200 rnA T=100ms- r-- 0 0 25 75 50 125 100 0 50 25 100 75 Ambient Temperature (Oe) Ambient Temperature ("e) Source Current VB. Ambient Temperature Output Saturation Voltage VB. Output Current SenH1=3V V+-GND=5V Seftle2=3Y See Test Circuit -...... 400 1 - r- r--.. ....... r- 1--0. . 1 V+-GND=36V Ii --;-....J, I l""- t--,. -r-...J. V+-GND-5V I 125 J- ~ - .L I 1 1 200 J -20 20 40 60 o 80 1m 10m Output Current (A) Indication Output Voltage VS. Output Current vs. Supply Volt.ge Supply Current 10 10 V+-GND Sense 2 Pin 5 Connect to 5V 3V ~It~~(~e~ln.'. Open ~ f > -- !-- i 0 I ........ § I II 100m AmbJent Temperature (Ge) 100m / 10m 100p I .... 1m 10m Indication Output Current (A) I 100m 2 0 f- - - I II II 10 20 30 40 50 Supply Current (rnA) 7-49 NEe pPC3423 Operating Characteristics (Cont.) TA = 25°C -- YS. Supply Current Ambient Temperature Pin 5 Connect to v+ = Pin 7 (GND) 36 V ~ V+:::: 5V c ~ o i.i: 5 - - Other Terminals Open r-- I- 4 20 20 40 Ambient Temperature (0C) 7-50 60 80 t-IEC pPD5555/5556 NEe Electronics Inc. CMOS TIMERS Pin Configurations Description ThepPD5555/56 are CMOS RC timers providing significantly improved performance overthe standard bipolar 555/556 timers, while at the same time being direct replacements for those devices in most applications. I mproved parameters include low supply current, wide operating supply voltage range, THRESHOLD, TRIGGER and RESET currents as low as 2 pA, no crowbarring of the power supply during output transitions, higher frequency performance, and no requirement to decouple control voltage for stable operation. Specifically, the pPD5555/56 are stable controllers capable of producing accurate time delays or frequencies. The 5556 is a dual 5555, with the two timers operating independently of one another, sharing only V+ and GND. In the one-shot mode, the pulse width of each circuit is precisely controlled by one external resistor and capacitor. For astable operation as an oscillator, the free running frequency and the duty cycle are controlled by two external resistors and one capacitor. The circuits can source or sink current large enough to drive TTL loads or provide minimal offsets to drive CMOS loads. G N D D 8 V+ Trigger 2 7 Discharge Output 3 6 Threshold Reset 4 5 Control tJPD5555C/G2 83-001892A Discharge A V+ Threshold A 2 Discharge B Control Voltage A 3 Threshold B Reset A 4 Control Voltage B Output A 5 Reset B Trigger A 6 Output B GND ....7_ _ _---'8,TrlggerB Il PD 5556C/G2 83-002768A Ordering Information Part Number Package Type IlPD5555C Plastic DIP Single IlPD5555G2 Plastic Miniflat Single Features IlPD5556C Plastic DIP Dual o IlPC5556G2 Plastic Miniflat Dual o o o Exact equivalent in most cases for industry standard 555/556 timers Low supply current 3 to 16 V operating voltage range Timing from microseconds through hours II Equivalent Circuit r---~---~-----~------~--4r----r---------4r--~V+ Threshold o--------t Output Triggero--------t-----t--r-----+_~ L-_ _ _~_~_ _ _ _~t_~__--+--~--+_~---+---oGND Discharge 83-002769B 7-51 NEe pPD5555/5556 Appl ications Figure 1. V+ = 3 Monostable Operation to 16 v - I I Trigger 2 Vldlv Ir lJ lJ H H Output 5 V/dlv L Capacitor C1 Voltage, 2 V/dlv I I L V1I / 1 r / / 1 L t - 0.1 ms/dly (R1 = 9.1 kO, C1 = O.01I1F, RL = 1 kO) 100r-----r-----r-----~----~----~----~ 1.0 f----1----I~- 0.1 f-----V----V----·";/'---_--bo''----t7''---t 0.01 i.o"'---Y--V'----/7''--- Time Delay 83-0016938 Figure 1 shows thepPD5555 operating as a monostable (one-shot) multivibrator. The sequence of operation is described below. 1. When the trigger input is reduced below 1/3 V+, the timer internal flip-flop is set. 2. This releases the short-circuit across C1 and the output goes high. 3. When the voltage across C1 reaches 2/3 V+, an internal comparator resets the flip-flop. 4. If the trigger voltage has returned above 1/3 V+, C1 discharges rapidly. 5. The output ls ~C\N !O\''/ and a nc'vv t:m:ng cycle may be initiated. 7-52 The time that the output is high can be taken from the graph in figure 1 or calculated by this formula: t(seconds) = 1.1 x R1 (MO) x C1 (pF) If a low is applied to the reset input, the output is forced low and C1 is discharged regardless of the other inputs. ~EC pPD5555/5556 Applications (Cont.) Figure 2. Astable Operation V+=3Io16V AL Al H H Output Voltage. 5 Vldlv R2 L J L ,V~V Capacitor C1 Voltage 1.7V/dlv J ~V t- 0.5 msJdlv (Al = A2 = 4.8 kCl, Cl = O.lpF, AL =1 kn) l00~~--~~--~---.-----'-----r----, 10~~--~~--~~-+~---+----~----~ 1.0 ""----~----f300.,------+~=--+~--_+----~ 0.1 f-----"",------~----+~,-----+~--_+~--~ 0.01 f--='-=F----~----+~---+~--_+~--~ 0.01 0.1 Free~Runnlng 1.0 100 Frequency (kHz) 83·0028308 Figure 2 shows the pPD5555 operating as a freerunning multivibrator. Capacitor C1 charges and discharges between 1/3 V+ and 2/3 V+. The free-running frequency can be obtained from the graph in figure 2 or calculated by the formula below. In the formulas, the corresponding units in which time, frequency, resistance, and capacitance can be expressed are: Time Charge time (output high): t1 = 0.693 (R1 + R2) C1 Discharge time (output low): t2 = 0.693 R2 C1 Period: t = t1 + t2 = 0.693 (R1 + 2R2) C1 1 ms Frequency Resistance Hz MI} kHz kl} MHz I} Capacitance pF 1 Frequency = - =0.693 -::(R:-:1-+'-2=-=R::-:2:7)-::C:-:'1 Duty cycle (output low): D = f R1 :~R2 7-53 II ttlEC pPD5555/5556 Electrical Characteristics Absolute Maximum Ratings TA = 25°C; V+ = 3 to 15 V unless otherwise specified. TA = 25°C limits Symbui min. iyp. max. Supply Current ICC 115 250 140 350 213 Threshold Voltage iinii IlA 50 Threshold Current Trigger Voltage pA 1/3 VTRIG Power Dissipation. IlPD5555 Plastic Mlniflat Plastic DIP 350mW 440mW V+=5V Power Oisslpation.IlPD5556 Plastic Mlniflat Plastic DIP 550 mW 570mW V+=3 V Operating Temperature pA V+=5V V+=3V Reset Voltage (VOUT becomes low.) 0.4 1.1 2.0 0.4 1.1 2.0 v 100 Reset Current pA 20 V+ = 15 V V+=3V Vresel = V-. V+ = 15 V V+ =5V V+=3V 0.06 Output low level 0.14 14.25 14.85 Output High level VOH 4.0 Output Rise Time Output Fall Time 0.4 VOL tf v 0.4 v V+=15V. Islnk = 3.2 rnA V+ = 5 V. Isink = 3.2 rnA V+=15V. Isource = 1 rnA V+ = 4.7 5 V. Isource = 1 rnA 40 ns 40 ns V+ ±0.3 V 100 rnA -20 to HO°C Storage Temperature V+ = 15 V 10 ITRIG Output Current V+ = 15 V V V+ 50 Trigger Current V+=5 V V+ = 15 V 10 18 V Input Voltage V V+ Supply Voltage Test iionliiiions V+ = 5 V. RL =10 MO. CL = 7 pF V+ = 5 V. RL = 10 MO. -55 to +125°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device al these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Recommended Operating Conditions Paramater Symbot Mfn. Typ. Max. Unit 500 kHz V+ 16 V V ISINK 3.2 rnA Oscillation Frequency Supply Voltage (Note 1) Input Voltage Output Sink Current Output Source Current ISOURCE Operating Temperature TOPT rnA -20 70 'C Note: 1. To reduce transient switching noise on the supply voltage line. install a bypass capacitor from V+ to ground. Connect the capacitor. with value listed below. close to V+. V+ C <10V 2: 10 V 0.047 1lF 0.11lF Timing Waveform CL = 7 pF Max Osc Freq fOSC 500 kHz Astable Operation Propagation Delay (V+ =5V) tpd 350 ns Monostable operation; trigger level =0.1 V+ Min Trigger Pulse Width (V+ = 5 V) tlr 160 ns Trigger level =0.1 V+ 213 V+ V 2 % Control Voltage Timing Error iniiiai Accuracy Temperature Drift Supply Voltage Drift Waveform 2V Y+=sv Rl.R2=1 to 10 kO. --5-0---p-pm-l-oC Cl = O.IIlF. V+ =5to %/V 15 V I I I I III I I,," I I • No Overshoot • YOH can reach V+ without pull-up resistor 7-54 t-IEC pPD5555/5556 Operating Characteristics TA = 25°C Supply Current (Static) VB. V+ Output Sink Current VB VOL 500 100 ./ 50 V+=15V!~ I - - 400 iC 1/ V'3V / /: V ./~V 300 ~ il ~ - 200 ~ In 100 o o J / . / ......:.. V I,....5 i ~ ::l 10 12 16 14 18 . / .h" "/ ~ 1 20 .01 .05 10 .5 .1 Supply Voltage (V) Output Low Voltage (V) Dynamic Current vs Frequency Output Source Current VB VOH 50 Y+Jsv./ 1 - ~ il / 10 ./ 5 / ~ ! i o ./ 10 100 0.1 1000 0.01 0.05 0.1 50 l V /' ~ i ~~ u ! Trlgger~ I 1000 Output c I. e ~ 10' I ~ f 10' i l..F\... 50% 500 I -::;;7 V v+ o 0.1 0.01 0.05 0.1 II 10 1500 ./""I-""y:j' = 5 V 1 ~ I-- y+ =3V . / V.,.. 0.5 1 Propagation Delay (Monostable) 1/ 10 C I v .... V V V O.S V+-VOH (V) Discharge Current vs. Discharge Voltage V+=15V ~ ./'". / Frequency (kHz) 100 i!!-- / / ' '/ )" ./ /'" i ~~!!!!!!!!!!!!!!!~!!!!!!!!!!!!~~~~ V /' "/ ./ 0.5 ./ /' ....- 0.5 Discharge Voltage (V) 10 o V ./ ISV 20 30 Minimum Trigger Voltage (%v+) 7-55 J.lPD5555/5556 7-56 NEe t-IEC CHARGE COUPLED DEVICES 8-A III CHARGE COUPLED DEVICES ttlEC Section 8 - Charge Coupled Devices pP0791 4096-Bit eeo Image Sensor ....•...................................•....•.. 8-1 pP0795 1024-Bit eeo Image Sensor .............................................•.. 8-9 pP0799 2048-Bit eeo Image Sensor .......•....•.••.............................. 8-17 8-B ftt{EC pPD791 4096·BIT CCD IMAGE SENSOR NEe Electronics Inc. PRELIMINARY INFORMATION Description Pin Configuration The .uP0791 is a CCO (charge-coupled device) linear image sensor that changes optical images to electrical signals. It has 4096 photo-elements, two lines of 2061bit CCO charge transfer registers, two output amplifiers, and two compensation signal amplifiers. The photo-elements have excellent response characteristics because of their PN junction construction. They are 7 by S .um separated by 2-.um channel stoppers. The CCO charge transfer registers have very high transfer efficiency, above 99.996 percent. 83-003149A Features Pin Identification D Excellent photo-electrical characteristics D Single 12-volt power supply D Compensation amplifier signal can reduce output signal noise D High resolution of 16 dots per mm across 2S.6-cm page D Transfer efficiency above 99.996 percent D 24-pin ceramic OIP Pin Applications Facsimile OCR (optical character reader) Instrumentation Ordering Information Part Number Package Operating Ambient Temperature IlPD7910 24-pin ceramic DIP -25 to +55°C *Function Name NC No connection ID Test input >IR Test input Transler gate clock input 5 >TG NC 6.7 >2· >1 Register clock input 8 >R1 Reset gate clock 1 input 9 VRD Reset part power supply input 10 CS1 Compensation signal 1 output 11 12 VDUTl GND Ground 13 VDD Output amplifier power supply input 14 VDUT2 Output 2 (bit 2. 4. 6...) 15 CS2 Compensation signal 2 output 16 VOG Output gate bias input 17 >R2 Reset gate clock 2 input 18.19 Register clock input 20.21 >1. >2 NC 22 G2 Test input 23 GI GND Ground 4 24 No connection Output 1 (bit 1. 3. 5, ...) II No connection Test input 'All NC pins should be connected to ground. 8-1 t-IEC pPD791 Block Diagram VRD "R2 <;>17 <;>9 VOD <;)13 Transfer Gate L-l----o CS2 15 10 tfiTG • 2 tfi2 ,. '-+-+--0 Vout2 '-+-+---0 Vout1 11 Test Photo-Elements [4096 bits + 8 invalid bits] '--t--ocs, fl2. GND 10 16 VOG 8 tfiR1 12 GND 83-003148C Photo-Element Construction Aluminum Electrode Channel Stopper I\~ 8-2 ~EC pPD791 Electrical Characteristics TA = +25"0; source of light, 2856 K tungsten lamp; exposure period =5.0 ms; f1/>1' f1/>2' and fl/>R = 1 MHz; external load resistance = 2 kn; Voo and VRO = 12.0 V; VOG = 3.2 V; VGl and VG2 = 0 V. LImits Symbol Min VSAT SE 300 SaturatiDn Exposure Parameter SaturatiDn Output Voltage Typ Max Test Conditions Unit 400 mV 0.22 Ixes Photo-RespDnse NonunlfDrmlty PRNU ±5 ±10 % VOUT = 200 mY; Infrared cui filler, CDrnlng 1·75 Average Dark Signal ADS 2 10 mV ND exposure Dark Signal Nonunilormily DSNU 10 20 mV ND exposure 150 230 mW Current of pins 9 and 13 x supply vDltage 1.1 1900 3000 11m mVllxes Working PDwer CDnsumplion Po Spectral RespDnse Range Limits SR 0.3 Sensitivity S Ollset Voltage Vlo 1300 4 Oulpul Delay Time 10 Dillerence belween VOUT1 and VOUT2 70 6 8 V 0% level Df VOUT in timing waveforms 50 120 ns See timing wavefDrms. ±10 % VOUTl = 200 mV dVOUT Reference Characteristics Recommended Operating Conditions TA = -25 to +55"0 Limits Parameter Input Capacitance aiI/>I Dr "'2 (pins 6, 7,18,19) Input Capacitance at "'H (pins 8, 17) Inpul Capacitance at "'TG (pin 4) Oulpullmpedance al VOUT Dr CS (pins 10, 11, 14, 15) with 2·kn exlernallDad reslslDr 400 5 50 800 1200 pF 10 100 1.0 15 150 2.0 Symbol Min Typ Max Unit Oulpul Amplifier Supply VDltage VOU 11.4 12.0 12.6 V pF Reset Part Supply VDltage VRU 11.4 12.0 12.6 V Oulpul Gale Bias VDltage VOG 2.7 Tesl Terminal GI VDllage VGI Tesl Terminal G2 VDllage VG2 Test TermlnallD VDltage VIO kn TA = +25"0 Tesl Terminal "'IR VDltage -0.3ID +IB V Reset Part Supply Voltage, VRU -0.3tD +18 V Output Gate Vollage, VOG -0.3tD +IB V Regisler CIDCk Signal VDltage, VI/>I1/>2 -0.3ID +18 V Transler Gale CIDCk Signal VDltage, VR -0.3 to +18 V Operallng Temperature, TOPT -25 to +55"C StDrage Temperature, TSTG Parameter pF Absolute Maximum Ratings Outpul Amplifier Supply VDllage, VOU limits Min Typ Max Unit -40 tD +100"C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. High Level DI Reglsler Clock Signal 3.7 0 12.0 V 15 0 VI/>IR 9.0 Low Level 01 Reglsler Clock Signal VI/>I1/>2L -0.3 High Level Df Transler Gale CIDCk Signal VRH 9.0 LDW Level of Resat Gate CIDCk Signal VI/>RL -0.3 Register Clock Signal Frequency (see Note) V V 0 10 VI/>I1/>2H Resel Gale Clock Signal Frequency (see Note) 3.2 V V 12.0 12.5 V 0.5 V 12.0 12.5 V 0 0 0.5 V 12.0 12.5 V 0.5 V fl/>I1/>2 3.5 MHz f100 ns. (See Timing Waveforms.) 8-3 II 0> ~:! .J,.. 3 ~ III :e ... II .r ""l < 'l::: " a .... CD ... CD 0 3lit Voun VOUT2 4>1 4>2 4>., tR_ (>10 n8)• 1/)1 and t/J2 are symmetrical. 4>.2 • The crossing voltage of t/J1 and above VOG + 1 V. fl should be kept • The register clock pulse should be not more than 2061 cycles. VOUT1 • Width of the transfer gate pulse should be less than 20 pa. VOUT2 tp 83-0031478 ~ n t-IEC pPD791 Definitions of Electrical Parameters Saturation Output Voltage [VSAT]. An output signal level above which the PRNU (photo-response nonuniformity) is ::::10% or the response is nonlinear. Saturation Exposure [SE]. Product of illuminance (Ix) and exposure period (s) in which the output is saturated. Photo-Response Nonuniformity [PRNU]. Percentage of peak output level and bottom output level against average output level of all valid photo-elements in static and uniform light. PRNU (%) =(VMAX or VMIN 1 Working Power Consumption [Pw]. Product of supply voltage and current when supply voltage is 12.0 V. Spectral Response Range Limits [SR]. Short side and long side limits of response spectral range having sensitivity above 5 percent of sensitivity of most sensitive wavelength. .....·--------100% 1) x 100 n n~Vj j=1 where n = number of valid photo-elements Vj = output voltage of each photo element --jll------------*"--S% ---,----Wavelength - - _ 83-003154A Sensitivity [S]. Quotient of the output level divided by exposure (Ixes). Offset Voltage [Vas]. Output terminal potential with no exposure. 83-003152A Average Dark Signal [ADS]. Average output level of valid photo-elements with no exposure. 1 n ADS (mV) =n~ Vj j=1 Dark Signal Nonuniformity [DSNU]. Peak output level with no exposure. ----,t:::::::::::::::EC=+' ~====:::::::::=.rr- I DSNU 83-003153A 8-5 ~EC pPD791 Example of Driving Circuit (Sheet 1 of 2) +5V TG Reg 1 pF r- 28 MHz ~~gll 1 I I I I I I I I I I I I I I I I I I I I I I I I "PD".l1 --I R1 I I I R2 L _____ J ,uPB74LS10 IL _ _ B3-003159C 8-6 ~EC pPD791 Example of Driving Circuit (Cont.) (Sheet 2 of 2) i - I "0026" TG +12Y 2700 2700 Reg 1000 pF Rl R2 1000 pF I 1000 pF I "0026" type MOS memory Interface Output 2 Note: 1. Supply voltage forelock generating is +5 V. 2. If ringing is present on the ¢'R waveforms, try connecting a resi,tor and capacitor In series between pin 8 (¢,R1) and grounnd and between pin 17 <¢'R2) and ground as damping circuits. Approximate values are 68 0 and 330 pF. 63-003160C 8-7 ~EC J.lPD791 Operating Characteristics TA = 25°C Dark Signal Signal Output 10r--------r-------,--------~------_,------_, 500 400 s; ~ 300 ! .5 ~ /' 200 iii 100 o /' / L V .° a: ..o 1l, > , .5 Co ~ o 0.1 0.2 _ _ _ __ L_ _ _ _ _ _ 0.8 0.7 ~ ~ ~ / 0.6 a: 0.5 0.4 / / ----- '\.\ \ \ ~ 0.8 Wavelength (Jim) 8-8 60 u. \ I- " " ~ 0.1 0.6 50 1.0 1.2 '" '" "'- White fluorescent lamp Lens: f = 38 mm F4.5 ~ ~ \ 0.3 0.4 ............ 80 0.2 o 40 MTF 100 • ./ a: 30 ~i Ambient Temperature T A (OC) Relative Spectrum Response 0.9 ~ _ __ L_ _ _ _ _ _L __ _ _ _ 20 0.3 Exposure (Ix.s) 1.0 L_~ 40 .......... r--...... .............. 20 o o 10 Spatial Frequency (dots/mm) 12 14 16 NEe NEe Electronics Inc. JlPD795 1 024·BIT CCD IMAGE SENSOR PRELIMINARY INFORMATION Description Pin Configuration The I1P0795 is a CCO (charge-coupled device) linear image sensor that changes optical images to electrical signals. It has 1024 photo-elements, two lines of 525bit CCO charge transfer registers, a drive unit, a sample-and-hold circuit, and an output amplifier. The drive unit simplifies the external circuit and reduces total drive power. The sample-and-hold circuit substantially reduces output signal noise. The photo-elements have excellent response characteristics because of their PN junction construction. They are 14 by 9 11m separated by 5-l1m channel stoppers. The CCO charge transfer registers have very high transfer efficiency, above 99.996 percent. Features o o o o o o GHD VRD VOG Applications Facsimile OCR (optical character reader) Instrumentation Photo-Element Construction ¢TGO ¢IR Pin Identification Pin Name 'Function GND Ground 4>10 Register clock input 4>RO Reset gate clock input 4>SHO NC Sample-and-hold clock input Transfer gate clock input 9 4>TGO G2 10 V+ Drive unit power supply input 11 ID Test input 12 G1 Test input 13 4>IR NC Test input 14,15 16 VOG Output gate bias Input 4 5,6,7 8 No connection Test Input No connection 17 VRD Reset part power supply input 18 VOD Output amplifier power supply input 19 VOUT GND Ground 20 Aluminum Electrode He He 83-00330BA 3 Excellent photo-electrical characteristics Single 12-volt power supply On-chip drive unit and sample-and-hold circuit High resolution of 8 dots per mm across 12.8-cm page Transfer efficiency above 99.996 percent 20-pin ceramic DIP He He Output • Ail NC pins should be connected to ground. II Ordering Information Channel Stopper Pari Number Package JlPD795D 20·pin ceramic OIP Operating Ambient Temperature 83-003150A 8-9 1::: ex> ~ "..... a CI CD 01 1---1 10 v' 0 > - - - - - - --- ~~ Pulse Width 4 O¢s", 17 VRD VOD r 1 Photo-elements (1024 bits t 8 invalid bits) Transfer Gale GND Leakage Current Drain Channel / ceD Charge Transfer Register (525 bits) 83-003307C ~ o !\fEe pPD795 Electrical Characteristics TA = +25°C; source of light. 2856 K tungsten lamp; exposure period = 5.0 ms; VGG. VOD. and VRD = 12.0 V; fljil0 = 250 kHz; fljiRO = 500 kHz. Limits Parameter Typ Symbol Min VSAl SE 400 650 mV Saluralion Exposure 0.15 0.20 Ixes Saluralion Oulpul Vollage Max Test Conditions Unit Photo-Response Nonunlformlly PRNU ±5 ±10 % Average Dark Signal ADS 3 10 mV No exposure Dark Signal Nonunllormlly DSNU 5 15 mV No exposure mW Currenl of pins 10. 17. and 18 x supply vollage Working Power Consumpllon Spectral Response Range Limits 200 Po SR 0.3 S 2000 Sensllivily 3250 VOUT = 200 mY; infrared culliller. Corning 1·75 pm 1.\ 4500 mV/lxes Ollset Voitage Vlo 4.0 V 0% level of VOUT in liming waveforms Feed·Through Delay Time 10 50 100 ns See liming waveforms. Feed·Through Level VFT 70 120 mV Feed·Through Pulse Wldlh Ipw 70 120 ns Reference Characteristics Recommended Operating Conditions TA = -25 to +55°C Limits Parameter Min Typ Limits Max Unit Parameter Symbol Inpul Capacitance al4>10. 4>RO. 4>SHO. or 4>TGO (pins 2. 3. 4. 8) 5 10 pF Rise Time and Fall Time 01 Feed·Through Pulse 50 100 ns Resel Pari Supply Voitage 1.0 2.0 kO Drive Unit Supply Voitage Oulpul Gale Bias Vollage Tesl Terminal Gl Vollage VGl Tesl TerminarG2 Vollage Tesl TermlnallD Voitage Oulpullmpedance al VOUT (pin 19) 0.5 Absolute Maximum Ratings TA=+25°C OUlpUI Amplilier Supply Vollage. VOO -0.310 +15 V Resel Part Supply Vollage. VRO -0.310 +15 V Drive Unll Supply Voltage. V+ -0.310+15 V Oulpul Amplilier Supply Voitage Min Typ Max Unit VOO 11.4 12.0 12.6 V VRO 11.4 12.0 12.6 V V+ 11.4 12.0 12.6 V VOG 1.0 1.25 \.50 V 0 V VG2 0 V VIO 12.0 V Tesl Terminal 4>IR Vollage VljilR 0 High Lavel of Reglsler Clock Signal VljilH 2.4 4.5 V 5.5 V Oulpul Gale Vollage. VOG -0.310 +15 V Reglsler Clock Signal Voitage. VIji 10 -0.310 +15 V Low Level 01 Reglsler Clock Signal VljilL -0.3 0 0.5 V Transfer Gale Clock Signal Voltage. VljiTGO -0.310 +15 V VljiTGH 2.4 4.5 5.5 V Resel Gale Clock Signal Voltage. VljiRO -0.310 +15 V High Level of Transfer Gale Clock Signal Sample·and·Hold Clock Signal Vollage. VljiSHO -0.310 +15 V Low Level 01 Transfer Gale Clock Signal VljiTGL -0.3 0 0.5 V Operaling Temperalure. TOPT -2510 +55°C High Level 01 Resel Gala Clock Signal VljiRH 2.4 4.5 5.5 V Low Level of ResBl Gale Clock Signal VljiRL -0.3 0 0.5 V High Level 01 Sample·and·Hold Clock Signal V.pSHH 2.4 4.5 5.5 V Low Level 01 Sample·and·Hold Clock Signal VljiSHL -0.3 0 0.5 V Iljil0 250 500 kHz fljiRO 500 1000 kHz Slorage Temperalure. TSTG -40 10 +100°C Comment: Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Register Clock Signal Frequency Reset Gate Clock Signal Frequency 8-11 D I is' 00 .!.. I\) CD .. ~ c ,.a 'l::: ... co 01 !. I~ ~ 10n5 ¢SHO VFT Vour -----J-- 5 P.---1 ¢TGO 1~onS-+l1 Min. 4110 t.- Min·~""-r---'-00-n-.--I Min. • The register clock signal 1/110 should be not more than 526 cycles. • Width of thea transfer gate pulse ¢TGO should be less than 20 /is. 83-003310C ~ n t\'EC JlPD795 Definitions of Electrical Parameters Saturation Output Voltage [VSATj. An output signal level above which the PRNU (photo-response nonuniformity) is :::::10% or the response is nonlinear. Saturation Exposure [SEj. Product of illuminance (Ix) and exposure period (s) in which the output is saturated. Working Power Consumption [Pwj. Product of supply voltage and current when supply voltage is 12.0 V. Spectral Response Range Limits [SRj. Short side and long side limits of response spectral range having sensitivity above 5 percent of sensitivity of most sensitive wavelength. ,,·--------100% Photo-Response Nonuniformity [PRNUj. Percentage of peak output level and bottom output level against average output level of all valid photo-elements in static and uniform light. PRNU (%) =(VMAX or VMIN 1) x 100 1n n~Vj 11, g <; > , , j=1 0. where n = number of valid photo-elements Vj = output voltage of each photo element o --,f-------------'l.---S% ----,----Wavelength - - _ 83-003154A ..!...~v· nj=1 J Sensitivity [Sj. Quotient of the output level divided by exposure (Ixos). Offset Voltage [Vosj. Outputterminal potential with no exposure. 83-003152A Average Dark Signal [ADSj. Average output level of valid photo-elements with no exposure. ADS (mV) 1n =n~ Vj j=1 Dark Signal Nonuniformity [DSNUj. Peak output level with no exposure. -'C~~:b£~====~r- I DSNU 83-003153A 8-13 III ~ >C III .j>. 3 22 pF V 3.3 kQ CD 9- .!:o Supply voltage for clock generating circuit: 5 V I I I I I I '\0 I licK QA I: I ttPD ~ -----.----, Qs QC - . i I , (RCO I D CO (II ::I n QD ::;' n c ::;: IJPB74LSOO IU Q I I I ".... ca , I L _________ _ 'l:::: +12V Q: C QD L ___ I 0.22 pF ~ 12 .n 0.047 pF 1.S .n L -, I L "P04011 I ~ 2.2 .0 2.2 .0 2200 I I I I I I I I ________ J ~ (l ~EC pPD795 Operating Characteristics TA = 25°C Signal Output Dark Signal 10r-------,--------,--------,--------r-------, 1000 800 ;;- /' .§.. 600 ! c5 ~ 400 .,.!1' 200 V / V /' / 0.1 0.2 0.3 Ambient Temperature T A (0C) Illuminance (Ix.s) MTF Relative Spectrum Response 1.0 1\ D•• . ° !. c i ;l! ,-/ 0.8 0.7 0.6 I 0.5 0.4 0.3 0.2 / / \ ........... \ / / 80 \ \ 0.4 0.8 ............. ............. ... ~ '" \ 1.0 "" ............. 40 20 \. Wavelength (ttm) While Fluorescent Lamp Lens: t = 38 mm, F4.5 ~ \ 0.6 r--..... r-..... i'-. 60 V 0.1 o -....... 100 o 1.2 o Spatial Frequency (dots/mm) 8-15 IJPD795 8-16 NEe t-1EC tJ PD79 9 2048-BIT CCD IMAGE SENSOR NEe Electronics Inc. PRELIMINARY INFORMATION Description Pin Configuration The jlP0799 is a CCO (charge-coupled device) linear image sensor that changes optical images to electrical signals. It has 2048 photo-elements, two lines of 1037bit CCO charge transfer registers, an output amplifier, and a compensation signal amplifier. The photo-elements have excellent response characteristics because of their PN junction construction. They are 14 by 9 jlm separated by 5-jlm channel stoppers. The CCO charge transfer registers have very high transfer efficiency, above 99.996 percent. 83-003275A Features Pin Identification D Excellent photo-electrical characteristics D Single 12-volt power supply D Compensation amplifier signal can reduce output signal noise D High resolution of 16 dots per mm across 25.6-cm page D Transfer efficiency above 99.996 percent D 24-pin ceramic DIP Pin Applications Facsimile OCR (optical character reader) Instrumentation Ordering Information Name *Function NC No connection 2 Vno Reset part power supply input 3 4 100 ns, (See Timing Waveforms,) 8-19 II ~ ~ 3 0 :::s ca :e :~ ¢2 - - , . . 1 2 3 4 5 6 7 " ~~ _. 00 o .... CD CD t3 ~ 8 ¢R11-J ~ n n n n n n n n n n n n n n n n VOUT 1 20 ns < t¢l < 100 ns = : t t ' . F 120'0100 n,) t - 90% - 90% ¢1 -10% ¢2 <(11 --l--l--10% and ¢2 are symmetrical. Min Min 0% ~;:;::""-------' 90% ¢R 'OO'-L~ • The crossing voltage of <1>1 and 1/)2 should be kept above VOG t 1 LT . {\ v. • The register clock signal should be not more than 1038 cycles. • Width of the transfer gate pulse should be less than 20 ps. 8:!-003276C ~ n !\fEe pPD799 Working Power Consumption [Pwl. Product of supply voltage and current when supply voltage is 12.0 V. Definitions of Electrical Parameters Saturation Output Voltage [VsAT1. An output signal level above which the PRNU (photo-response nonuniformity) is 2':10% or the response is nonlinear. Spectral Response Range Limits [SR1. Short side and long side limits of response spectral range having sensitivity above 5 percent of sensitivity of most sensitive wavelength. Saturation Exposure [SE1. Product of illuminance (Ix) and exposure period (s) in which the output is saturated. --------100% Photo-Response Nonuniformity [PRNU1. Percentage of peak output level and bottom output level against average output level of all valid photo-elements in static and uniform light. PRNU (%) =( VMAX or VMIN 1n n2Vj 1) x 100 j=1 where n = number of valid photo-elements Vj = output voltage of each photo element --,It-------------'\---S% --...,----Wavelength - - _ 83-003154A Sensitivity [Sl. Quotient of the output level divided by exposure (Ixos). Offset Voltage [Vosl. Output terminal potential with no exposure. 83-0031S2A Average Dark Signal [ADS1. Average output level of valid photo-elements with no exposure. 1 =n2 Vj n ADS (mV) j=1 Dark Signal Nonuniformity [DSNU1. Peak output level with no exposure. -'~~~35£~====~r- I OSNU 83-0031S3A 8-21 t-IEC pPD799 Example of Driving Circuit (Sheet 1 of 2) 3 pF ~ 3.3 kO I I-:-c-rr,s-~a-~~-e~-o~-:)t'or 0 ----- 3.3 kO -- I I ~-------I 2MCl -----;;pB74LSOO----i I I I I I I I I I I I IL ___ ..J I J I PPB74LS163, CK aA as ac I I aD Reg 10 Cl ...J 1100PF TG 83-003277C 8-22 t\'EC pPD799 Example of Driving Circuil (Coni.) (Sheet 2 of 2) +12V R Reg L TG _ _ ....l "0026" type MOS memory Interface Note: (1) Supply voltage tor clock generating circuits Is +5 (2) If ringing's present on the tPR waveform, Iry connecting a resistor and capacilor In series between pin 3 and ground .s a damping circuit. Approximate values are 68 0 and 330 pF. v. 83-003278C 8-23 t-IEC pPD799 Operating Characteristics TA = 25°C DaiK Signa: 1000 800 V ;- g ./ 600 !o ~ 400 ~ 200 '/ / V / 0.1 0.2 0.3 Ambient Temperature T A (DC) Illuminance (Ixos) Relative Spectrum Response 1.0 1\ 0 .• I~ 0 .• 0.7 ~ ~ ~ 0: ;l! 0.6 0.5 0.4 0.3 0.2 MTF 100 / / / / \ ./""'00. \ / If 0.1 \ \ 0 .• Wavelength (fJm) 8-24 I'-......, ~ ~ \ ::::; 40 \ 20 '\. 0.6 White Fluorescent Lamp Lens: f = 38 mm, F4.5 r--... -........... 60 o 0.4 r--. I'---.. 80 1.0 " o 1.2 o Spatial Frequency (dots/mm) ~ t\'EC PACKAGING INFORMATION 9-A II PACKAGING INFORMATION fttIEC Section 9 - Packaging Information Packaging Information ......•••..............................•.....•...•........... 9-1 Thermallnformation ............................................................. 9-13 Taping Specifications .................•............•.......•.•••................. 9-15 Surface Mounting Specifications .................................................. 9-23 9-8 NEe PACKAGING INFORMATION B-Pln Plastic DIP (300 mil) Item A MIllimeters Inches 10.5 max .413 max .1001TP) B 2.541TP) c .5 ,002 0 2.7 min .106 5.80 max .228 .5 .002 G 6.401TP) .2521TP) H 7.62 .300 .25 .010 Notes: I.. A 1. Each lead centerline Is located within .25 mm [.01 Inch] of Its true position [TP] at maximum malerial condition. 2. Item "G" to center 01 lead' when formed parallel. 0 -If.I 63-0033928 B-Pln Plastic DIP (300 mil) (I-/PC3423 only) Item Millimeters Inches A 10.5 max .413 B 2.541TP) .1001TP) - - - - - - - ---_. ---_._C.5 .002 o .138 3.5 4.7 3.8 .185 .150 -,._,,--,-"- G 6.401TP) .2521TP) H 7.6 .299 .3 .012 1.2 .047 Notes: I. ' A 1. Each lead centerline is located within .25 mm [.01 Inch] of its true position rTP] at maximum material condition. 2. Item "0" to center of leads when formed parallel. -III 83-0033959 9-1 NEe PACKAGING INFORMATION 14-Pln Plastic DIP (300 mil) Item Millimeters A 20.32 max Inches .BOD max a 2.54 max .100 max C 2.'4 [TP[ .100[TP} 0 .50 ± .10 .020 .047 min ~:~g: F 1.2ml" 3.6 ± 0.3 G .51 min .020 min H 4.31 max .170 max 5.08 max .200 max 6.' .252 ------------ -----7.62 [TP} -----K .25 Notes: !:~~ .142 ±.O12 I. . 7 1 1 A .300 [TP} .O10~::~ 1, Each lead centerline is located within .25 mm [.01 inch] of its true position [TP) at maximum material condition. 2. Item" J" to center of leads when formed parallel. c a 83-0033916 16-Pln Plastic DIP (300 mil) 16 Item Millimeters Inches A 20.32 max 0.8 max a 1.27 max .05 max C 2.'4 [TP} .10 [TP} 0 + .004 .5 ± .10 .02 17.78 .70 1.2 min .047 min - .005 G 3.5 ±.3 .138 ± .012 H .51 min .02mi" 4.31 max .17max 5.08 max .2 max K ... .3 [TP} M .2' N 1.0mi" 7.62 [TP} . 81 A N .252 +.10 - .0' .01 + .004 - .003 K Fhl .039 min Noles: 1. Each lead centerline is located within .25 rnm [.01 inch] of Its true position !TP] a1 maximum mate· ~!~! eo!'!:d!t!o:':. 2. Item "K" to center of leads when formed parallel. u u u \l \-83-001489B 9-2 ~EC PACKAGING INFORMATION 18-Pln Plastic DIP (300 mil) 18 Item Millimeters Inche. A 22.86 max .9max B 1.27 max .05 max C 2.S' [TP[ .10 [TP[ D .S±.10 .02 20.32 .8 F 1.2 min .047 min G 3.5 ±.3 .138 ± .012 H .51 min .02 min 4.31 max .17mBx S.OB max .2 max K .3 [TPJ 6.' .252 +.10 -.OS .25 N 1.0 min Notes: +.004 - .OOS 7.62 [TPJ M .01 10 ·1, +.004 -.003 .039 min 1. Each lead centerline is located within .25 mm ,.01 Inch] of its true position (TP] at maximum material condition. 2. Item "K" to center 01 leads when formed parallel. 20-Pln Plastic DIP (300 mil) 11 20 Item MIllimeters Inches A 25.40 max 1.0max B 1.27 max .05mBX C 2.54 [TPJ .10 [TPJ D .5±.10 .02 22.86 .9 +.004 -.005 1.1 min .043 min G 3.5± .3 .138 ± .012 H .51 min .02 min 4.31 max .17 max J 5.08 max .2 max K 7.62 [TPJ .3 [TPJ 6.' .252 +.10 -.05 M .25 N .8 min .01 10,1 A N + .004 - .003 .035 min Notes: 1. Each I.ad cent.rllne Is located wlthln.25 mm [.01 Inch] of Its true position [TP] at maximum materia_ condition. 2. Item "K" to cenler of leads when formed parallel. ~149'8 9-3 ~EC PACKAGING INFORMATION 22-Pln Plastic DIP (400 mil) 12 22 Item Millimelers Inches A 27.94 max 1.100 max B 1.27 max .osa max C 2.54ITPI .100ITPI 0 .50±.10 020 +.004 . -.005 1.2m.n .D47mln 3.5 ± 0.3 .138 ± .012 G .51 max .020 max H 4.31 max .170 max I 5.72ma. .226 max 10.161TPI .400ITPI 8.6 .339 K M .25 !:~: .O10~::: a.8mln .031m'n Nole.: 1. Each lead centerline I. located within .25 mm (.01 Inch) of Iwlrue position [TPJ at maximum material condition. 2. Item" J" 10 centar of leads when formed parallel. 83-00339GB 24-Pln Plastic DIP (600 mil) 24 Item MIllimeters Inches A 33.02 max 1.3 max .10 max B 2.54 max C 2.54ITPI .101TPI 0 .5±.10 .02 27.94 1.1 +.004 -.005 1.2m.n .047 min G 3.8±.3 .138 ± .012 H .51 min .02 4.31 max .17 max 5.72 max .226 max K 15.24ITP] .60 ITP] M .25 13.2 .01 +.004 -.003 Notes: 1. Each lead centerline Is located wlthln.25 mm [.01 inchl of its true position [TP] at maximum material condition. 2. Item "K" to center of leads when formed parallel. A K ~~ .. .. I 9-4 . 121 min .52 +.10 -.05 13 --t~D . 11- .n t-IEC PACKAGING INFORMATION 28-Pln Plastic DIP (600 mil) 28 Millimeters Inches A 3B.1 max 1.5 max 8 2.54 max .10 max C 2.54 [TPJ .10 [TP] 0 .5 ± .10 .02 33.02 1.3 Item --- .. _----_.1.2min .... _-----_. .G_ - -3.6_±.3 ... .51 min H + .004 - .005 .047 min .142 ± .012 .02 min ----4.31 max ------- .17 max 5.72 max - - - - - - ----- M .226 max - ----'----- 15.24 [TPI .60 [TPI 13.2 .52 .25 15 + .10 .01 - .05 + .004 - .003 Notes: 1. Each lead centerline is located L \.{ ,H within .25 mm [.01 inch] 01 Its true position [TP] at maximum mat8~ rial condition. 2. Item "K" to center of leads when formed parallel. H!1!H H H H H H H H H ,H, . db: ~ J H . c G 4- 8 M 0-15" 83-0014078 28-Pln Plastic Shrink DIP (400 mil) 15 28 lIem MIllimeters Inches A 28.46 max 1.121 max B 2.67 max .106 c 2.54 [TPI .100 [TPI o .50 ± .10 24.89 .98 .9 min .035 min G 3.2 ± 0.3 .126 ± 012 H .51 min .020 min 4.31 max .170 max 5.08 max .200 max 10.16 [TPI .400 [TPI 8.6 .339 M Notes; .25 ~:~~ .01 ~:~~~ 1. Each lead centerline is located within .25 mm [.01 Inch] of its true position [TP] al maximum material condition. 2. Item uK" to center of leads when formed parallel. E 83-0015198 9-5 t\'EC PACKAGING INFORMATION 14-Pin Ceramic Package (300 mil) Millimeters Inche. A 19.9max .78 max .09 Item B 2.35 C 2.501TPI .1ITPI 0 .06 .018 15.2 .6 F 1.5 .059 G 3.0 min .118 min H .Smln .02 min 4.58 max .181 max M 5.08 max .2 max 7.621TPI .3ITP) S.O .25 .25 .01 Not••: 1. Each lead centerline Is located within .25 mm [.01 Inch) of ''''rue position [TP] a. maximum mate~ rial condition. 2. Item "K" to center 01 leads when formed parallel. 83-0015238 16-Pin Cerdlp Package (300 mil) 16 Item MIllimeters Inches A 19.9 max .784 max B 1.0S .042 c o 2.501TP) .101TP) .46 ± .10 .016 ± .000 17.78 .70 1.5 .059 G 2.54 min .10 min H .Smln .D19 min M .181 S.OB max .20m_x 7.621TP) .301TP) 6.0 .25 +.10 -.05 . .I rna. 4.58 max .25 6 A q 11-1 H HRR Hlr-I! 0098+ .0039 -.0019 Notes: 1. Each lead centertine is located within .25 mm [.01 Inch] of Its true position [TP] at maximum mala rial condition. 2. Item "K" to center of leads when formed parallel. M dg: . +; . M 83-0015168 9-6 t-IEC PACKAGING INFORMATION 18-Pln Cerdlp Package (300 mil) 18 Item MIllimeters Inches A 23.2 max .91 max B 1.44 .055 C 2.54ITP] .1DITP] D .45 .02 20.32 .8 1.2 .Dfi G 2.5 min .1 min H .5 min .02 min 4.6 max .18 max K M 5.1 max .2 max 7.62ITP] .3ITP] 6.7 .26 .25 .01 10 [i ~ ~ ~:~ ~ ~ 1.1 A Noles: 1. Each lead centerline is located within .25 mm [.01 inch] of its true position [TP] at maximum material condition. 2. Item uK" to eenter of leads when formed parallel. 63-0015178 20-Pln Ceramic DIP (pPD795D) 28.0 (1.10) max. Unit: in millimeters (inches) 25.4 (1.00) Cover Glass 22.4 (0.88) Thickness: 0.5 millimeters Refraction ratio: 1.76 (in air) 20.0 (0.79) 0.5 ~~~?~~i~=~~:~k:~1(D.D2D) -- 8.3 10.3 (0.41) max. (0.33) 7.2 (0.28) 11.5 (0.45) 2.0 From surface of chip to outside of glass 1.27 (O.OSO) bJ~~~Yr~~~~~~~~('DiF9)* 0.25 (0.0098) --+ + - 0.5 (0.020) -110.46 (0.018) 1. 10.45 (0.41) ±O.35 2.54 .1 (0.10) 83-0033866 9-7 ~EC PACKAGING INFORMATION 24-Pin DIP (pPD791D) Unit: in millimeters (inches) __-----------''-C3::.O:-:(1.69) max. i" Cover Glass "" "" Thickness: 0.5 millimeters Retraction ratio: 1.76 (in air) From surface of chip to outside of glass 1.40 (0.055) 2.54 (0.10) I· 15.5 (0.61) -::0.3 ·1 83-0033898 24-Pln DIP (pPD799D) Unit: In millimeters (Inches) Cover Glass Thickness: 0.5 millimeters Refraction ratio: 1.76 (in air) From surface of chip to outside 01 glass 1.40 (0.055) 0.25 (0.0098)-+lf_ 15.5 (0.61) ±O.3 83-0033908 9-8 I t-IEC PACKAGING INFORMATION 8-Pln Plastic Mlnillat (225 mil) Item MIllimeters Inch.. A 5.70 max .22 max a .94mB. .037 max C 1.27 [TP[ .05 [TP) 0 .40 ~:~: .O16~:= .1 ±.1 .004 1.49ma. .059 max G 1.80 min .071 max H 6.5 ± .3[TP) .258 ± .Ol1[TP) 4.4 max .15~:~ K 1.1 max .6 ±.2 I. .173 max .OO6~::: 1 4 A .1 H .004 max .024 ±.008 Each lead centerline Illac.ted within 0.12 mm (0.005) of It, true poIltlon (TP) at maximum material condition. Note: 0 ± .004 'Ib~ E 0 C --.1 t J a 14-Pln Miniflat Ie (225 mil) 14 Item MIllimeters Inches A 10.46 max .412 max a 1.42 max .056 max C 1.27[TP) .050[TP) 0 .40 ~:~~ .O16~::= .1 ±.1 .004 ± .004 1.8max .071 max G 1.49 .059 H 6.5 ±.3 .256 ± .012 4.4 .173 1.1 K .15 .043 ~:~: .6 ±.2 Nole: .006 ~:::: .024 ~:::: Each lead centerline is located within 0.12 mm (0.005) of Its true position (TP) at maximum material condlllon. o A ~u --n== ~L~ D C a E 83-0033948 9-9 ttiEC PACKAGING INFORMATION 24-Pln Ceramic Flatpack B L'~======~Ir======~ r~~LilllJ~~ Item A - Mllllmelers Inches .43 ± .05 .017 ± .002 G a 1.27 Iyp .050lyp C 6.35 min .250 min D 6.60 ± .15 .260 ± .006 19.30 ± .15 .780 ± .006 -----F 13.97 Iyp .550lyp G 10.11 ± .18 .398 ± .007 H 7.49 ref .295 ret I 3.05 .120max K .305 .012 min .13 ± .03 .005 ± .001 tl· -I c I -I D H II 83-0033968 3-Pln SIP TO-220 G Item Inches .420 max A 10.86 max a 2.54 [TPJ C . -.29 .031 D 1.3 .051 8 +.34 .100[TPJ ~::~~ 6.35 max .250 max F 12.7 min .500 min G 5.85 min .230 min H 3.0 Note: 9-10 Millimeters :::~ M .118 :::~: 4.82 max .190 max 1.3±.2 .051 ± .OOB K 2.8 ::;: .110::~~ .5± .2 .020 ± .008 M 5.33 max .210 max N 15.87 max .625 max Each lead centerline is located within .25 mm [.01 Inch) of Its true position [TP] at maximum malerial condition. N a ~ L K ~I t\'EC PACKAGING INFORMATION 3-Pin SIP TO-92 Millimeters Inches A 5.2 max .205 max .067 max Item a 1.27 max C .S .002 D 2.54 .100 14mln .551 min 5.5 max .217 max G 4.2 max .165 max H 1.77 max .070 max 83-0033998 9-Pin Plastic SIP Item Millimeters Inch,s A 22.86 max .900 max a 1.27 max .os C 2.S'[TP[ .100[TP[ D 1.1 min .004 min 2.9 min .114 min F 5.08 max .200 max G 5.72 max .225 max H 3.0 max .118max 1.5max .059 ~:~:~ ~:~~ .006 ~:~~: .25 K M Note: 1.1 i--------i]. J I' A 'I L f I _a .00' .S .2 .51 min .2 min Each lead centerline Is located within .25 mm [.01 inch] of its true position [TP] at maximum material condition. 83-0033878 9-11 PACKAGING INFORMATION 9-12 t\fEC t\'EC PACKAGING INFORMATION 2. Thermal Information 14 Pin Through 20 Pin Cavity DIP Dissipation Derating Curve The power dissipation capability of semiconductor devices is limited by the maximum allowable junction temperature, the ambient temperature, and the thermal resistance between the junction and the ambient environment. The temperature difference between the junction and the ambient environment is determined by the following equation. 1000 OP Amps and Comparators j" ",,1~W/OC 600 ~ c ~ I!. 600 ':0 ; D/A AID Converters 400 ° 0. TJ-TA=P D 8JA where T J = junction temperature, °C TA = ambient temperature, °C PD = power dissipation, W 8JA = thermal resistance, junction to ambient, °CJW J! The maximum allowable junction temperature is 150°C, however, the maximum junction temperature of plastic package I C's shou Id be 125°C because of the storage temperature range limitation. 8JA = 90°CJW typo TJ max = 150°C The dissipation derating curves that follow assume the ambient environment is still air, and that no heatsink is used. 1. ~ 200 20 40 100 60 60 Ambient Temperature (0C) The maximum power dissipation value has been fixed considering the practical applications. 900mW 500mW Operational Amplifiers and Comparators OJA, AID Converters 3. 8 Pin Plastic Molded DIP Dissipation Derating Curve 8 Pin Metal Can Package and Cavity DIP 600 Dissipation Derating Curve 600 500 j" E i 500 ........... ~W/OC ~ g 400 ..is "" [ 300 ! 400 i ........ .~ i5 300 ! 200 Q, 5mW/OC ........ J! ~ c.. 200 100 ~ >- 100 20 40 60 60 100 Ambient Temperature (0C) 20 40 60 60 100 Ambient Temperature ("C) 8JA = 200°CJW typo TJ max = 150°C The maximum power dissipation value of 500 mW has been fixed considering the practical applications of operational amplifiers and comparators. (except for tJPC4556C, tJPC4557C, tJPC4560C, tJPC1555C) 8JA = 200°C/W typo TJ max = 125°C The maximum power dissipation value of 250 mW has been fixed considering the practical applications of operational amplifiers and comparators. 9-13 t-IEC PACKAGING INFORMATION 4. 8 Pin Plastic Molded DIP 1000 i .sc l° I ............ 600 'ii ..° When the miniflat IC's are mounted on a hybrid IC, the heat radiation throuQh the leads is increased. When resin coated, the heat radiation through the environment is further increased. As a result, the thermal resistance in the mounted state is much smallerthan in element form alone. 800 Q ; 6. Miniflat Package Dissipation Derating Curve 400 7mW/oC ~ It is suggested that the heat dissipation in actually mounted condition be fully investigated. ~ ~ I- 6A. 200 8 Pin Mini flat Package Dissipation Derating Curve 600 20 40 60 80 --- - 100 500 AmbientTemperature (0C) i E ~ (For pPC4556C, pPC4557C, pPC4560C, pPC1555C) pPC4556, pPC4557, pPC4560C pPC1555C 14 Pin Plastic Molded DIP 800 100 25 100 8 Pin Mini flat Package DisSipation Derating Curve 600 " " ' " 7mW/oC ........... 500 I'-... i .s 200 .2 I i 20 40 60 80 100 Ambient Temperature (0C) = 140°C/W typo T J max = 125°C ..is~ ---+ 550mW i'.. 400 8JA 75 50 Ambient Temperature (OC) 68. I, 600 :;c ~ I I- The maximum power dissipation value of 440 mW has been fixed considering the maximum junction temperature and the practical applications of miniflat IC's. .sc ..;° ........ 8JA = 220°C/W typo TJ max = 125°C Dissipation Derating Curve ° ~ "'i'.. 200 700mW 600mW 1000 ~ ~ Q. I ........ is 300 The maximum power dissipation value has been fixed considering the maximum junction temperature and the practical applications of those IC's. i ~ 5mW/OC ':g 8JA = 140°C/W typo TJ max = 125°C 5. ........... 400 ~ 400 ......... ~ r--- ---f---- 5.5 mW/oC .""- 300 a. 200 jj One Element Only ""'- ~---- (!. 100 The maximum power dissipation value of 570 mW has been fixed considering the practical applications of operational amplifiers and comparators. 25 50 75 100 Ambient Temperature (OC) 8JA = 180°C/W typo TJ max = 125°C The maximum power dissipation value of 550 mW has been fixed considering the maximum junction temperature and the practical applications of miniflat IC's. 9-14 t-IEC PACKAGING INFORMATION Taping Specifications Tape and reel shipping has been used for many years in Japan for shipping surface mount transistors and capacitors. Currently, 75% of surface mount transistors are shipped via this method. Tape and reel specifications, formally established by Japanese Standard RC-1009A for 12 mm tape, has now been expanded to include surface mount ICs. Surface mount technology in the United States has recently come of age, and in May of 1985 the EIA developed Standard EIA481 for Embossed Tape and Reel Packaging. NEC has adjusted the current Japanese standard to comply with EIA481, and is now shipping surface mount devices to this specification. Because of the need for electrostatic packaging, NEC chose to manufacture the tape using carbon/PVC material. This type of "filler mixed" plastic is diffiCult to emboss, thus the actual tape manufacturing is done by the Sumitomo Bakelite Corp in Japan. Figure 1. The actual manufacturing process is shown in Figure 1. First, rolled sheet material is slittized and embossed. Next, the sprocket holes are punched, and aligned with the embossed pockets to a tolerance of ±50 microns. Finally, the pocket holes are punched, and the tape is cut to length and put on the reel. Specifications: NEC's embossed tape is manufactured to EIA481 specifications with special attention paid to dimensional accuracy. See Table 1 and Figure 2. Table 2 and Figure 3 show Reel Dimensions. Figure 4 illustrates the Tape End Configurations. Figure 5 shows component placement in the tape pockets. Table 3 gives the device package-to-tape width specifications. Figures 6,7 and 8 show the tape and reel specifications for the specialized case of 8, 14 and 16-pin miniflats. Manufacturing Processes of Embossed Carrier Tape Pocket Emboallng SliWa 0 Rolled Sheel W=8m,L=800to 1000m -- SprockalHoIe Opening Opening Gt 0 Longlll Cut and Pecking UI.Pocket uQulde 83-0031228 9-15 t-IEC PACKAGING INFORMATION Table 1. 8, 12, 16,24 mm Embossed Tape Tape Size n ,,.. tl! 0, IL, IU, 24mm 0 Po 1.5 +~.!O -u.U (.059 ~g.~~) i.75 ± a.in 4.0 ± .iii (.069 ± .004) (.157 ± .004) I (Max.) Ao. Bo. Ko 0.400 (.016) See Noie i Table 2 Bl 01 K Max. Min. Max. 8 mm 4.2 (.165) 1.0 (.039) 12mm 8.2 (.323) 15mm 12.1 (.476) 24 mm 20.1 (.791) Tape Size 1.5 (.059) 3.5 ± 0.05 (.138 ± .002) 2.4 (.094) 5.5 ± 0.05 (.217 ± .002) 4.5 (.177) 7.5 ± 0.10 (.295 ± .004) 11.5 ± 0.10 (.453 ± .004) Constant Dimensions R P2 Min. 2.0 ± 0.05 (.079 ± .002) 2.0 ± 0.10) (.079 ± .004) 6.5 (.256) W 25 (.984) 8.0 ± .30 (.315 ± .012 30 (1.181) 12.0 ± .30 (.472± .012) 40 (1.575) 18 ± .30 (.630 ± .012) 50 (1.969) 24 ± .30 (.945 ± .012) Variable Dimensions P Tape Size 4.0±0.10 (.157 ± .004) 12.0±0.10 (.472 ± .004) 8.0 ±0.10 (.315 ± .004) 16±0.10 (.630 ± .004) 20±0.10 (.787 ± .004) 24± 0.10 (.945 ± .004) 8 mm 12 mm 16 mm 24 mm Notes: 1. Ao Bo Ko are determined by component size. The clearance between the component and the cavity must be within 0.05 (.002) min. to 0.50 (.020) max. for 8 mm tape. 0.05 (.002) min. to 0.65 (.026) max. for 12 mm tape, 0.05 (.002) min. to 0.90 (.035) max for 16 mm tape and 0.05 (.002) min. to 1.00 (.039) max. for 24 mm tape and larger. The component cannot rotate more than 20° within the determined cavity, see below. 2. Tape and components shall pass around radius "R" without damage. Typical component cavlly center line 82 9-16 003~23A ! t-IEC PACKAGING INFORMATION Figure 2. Embossed Carrier Dimensions i rt ::anceon 10pl'chn cumulative po-----+ 1--_ I ±O.2 [±O.OO8) For Machine Reference Only Including Dr.ft and Radii Concentrtc Around Bo u .., Direction of Feed °Top cover tape thlckn..1 (111 ~.;::.) Max Thick Bending radius See Note Z Table Emboa..d camber Embossment I. [3·r~ mmM.. 100mm • I I ~-~!~-~ ~ r---= . f ~ I ~=t---r llmm [.038) Ma. ~:~8:37---------- . 83-003124C 9-17 NEe PACKAGING INFORMATION Figure 3. Reel Dimension. 40 (1.575) Min. Accellhole at slot locatton ,IF·· J.t=41\' A ~,:\I ~,,~,..\ T.... llot In core fo,t.pe ...rt. Full Redlu,- 2.5 (.081) IIln Width lG (o3M) IIln Depth G( .....Urodothul»-.l1.-Drive Spok.. optIon.11f uHCI uterllked dlmen,loRl appty. 83-0031258 Table 2. Reel Dimensions rap. A B Size MIx. Min. 8mm 330 112.9921 1.5 1.0591 12mm 330 (12.9921 16mm 380 (14.173) C 13.0± 0.20 1.512 ± .0081 D N Min. Min. 20.2 i.7951 50 1.19691 (.331 ~~81 (.488 ~:'~8) 164 +2.0 . ---tI.08 (.646 ~:'~8) 24 +2.0 -0.08 (.961~:) 32.4~:: (1.276~~:1 32mm 444 +2.0 . -0.0 44 min (1.748 ~:.~ 609 (23.9761 Metric dimensions will govern. English measurements rounded and for reference only. 9-18 84+1.5 . ---tI.O 12.4 ~~~ 24mm 55mm G 100 13.937) 58.4 ~~:~ (2.220 ~:'~81 r Max. 14.4 1.5671 18.4 (.7241 22.4 1.882) 30.4 (1.1971 t-IEC Figure 4. PACKAGING INFORMATION Tape End Configurations End User Direction of Feed 83-0031268 Figure 5. SO-/C Devices Typical User Direction 01 Feed 83-OO3127B 9-19 ftt{EC PACKAGING INFORMATION Table 3. SO·/C Devices Component Tape Size mm (WI Part Pitch (PI 8 14 16 12 16 16 8 8 8 14L 16L 20L 24L 28L 16 16 24 24 24 12 12 12 12 12 pee 18 20 28 44 24 16 24 32 12 12 16 24 pee 52 68 84 100 124 32 44 24 32 36 80·!(; 225 mil MF SO·IC 375 mil MF Figure 6. 44 40 44 56 48 Embossed Carrier Dimensions 1.5~~·1 Direction 01 Feed 8.0±O.1 ~6'9±O'1 l4J=-+ 9-20 83-0031308 NEe PACKAGING INFORMATION 80 W 5.4± 0.1 12.0 ± 0.3 5.5 ±0.1 10.45 ± 0.1 16.0 ± 0.3 7.5 ± 0.1 Package 8p SMF 14, 16p SMF SMF: 225 mil Miniflat BpSMF 14,16SMF 18.4 Max 22.4 Max w T SMF: 225 mil Miniflat Figure 7. Reel Size 1+-------330Max-------.j Figure 8. -u: 83-0031316 Cover Tape Peel Strength: 40 ± 25 g 9-21 fttfEC PACKAGING INFORMATION Taping Mounting Placement and Fixing with Position Adjustment Release and Pick up o Vacuum Check Vacuum Check Carrier Tape o Q Adhesive Tape to Roll Up Wheel 2 to 3 sec/pes 1 to 2 sec/pes 63-0031288 Taping Placement Sealing by Thermal Compression from Feeder Roll Stamping Base Embossed Carrier Tape 0.2 to 1 sec/pes to Peeling Wheel C)~coyerTape I 0 Vacuum Check CArr1tj{r-l--:---i.....,h,ffL Emboss.. Carrier Tape] 9-22 .J ftIEC Surface Mount Information PACKAGING INFORMATION Figure 2. Cross Section of a Mlnlflat IC Figure 3. Compatible Footprint Pattern for NEC Mlnlflat IC and SOIC Structure The designation for industrial linear IC (ILlC) in the miniflat package is "G2." Figure 1 shows a cutaway view of the miniflat G2 package. The die (chip) is mounted to the center lead frame island, with bonding pads to the external leads. The lead frame is made from 42 Alloy with silver (Ag) paste used for die attachment. The body is high-purity molded epoxy for high reliability. Figure 2 shows the package cross section. Package Outline In 1981, the EIAJ (Electronic Industry Association of Japan) set the standards for Surface Mount ICs. They required that devices manufactured in Japan attain higher resistance to environmental factors (humidity, shock, and vibration) than existing Small Outline Integrated Circuit (SOIC) devices. The resulting package is known as the 225-Mil S.O. Specification. Figure 3 illustrates the difference between the NEC miniflat (G2) and the S.O. type package. The body or molded portion of the NEC miniflat is 4.4 mm wide compared to 4.0 mm for the S.O. package. The lead bend of the NEC miniflat adds an additional 0.1 mm, for a net difference of approximately 0.5 mm in overall footprint width (miniflat vs. SOIC). All other dimensions (such as lead pitch, length, and spacing) are the same. The larger package size of the NEC miniflat allows a larger die to be mounted in 8- and 14-pin packages, (e.g. BIFET op amp), which increases the variety of circuits available in the G2 package. See Package Information Section for the outline dimensions of 8-pin and 14-pin G2 packages. Figure 1. Internal Structure (8-Pin Type) Resin [Epoxy] Note: Foot-print dimensions are in mil/mm. 83-003383A Handling Techniques To work with the NEC miniflat IC without jeopardizing the quality and reliabilty, it is necessary to exercise more care than when handling standard DIP ICs. Environmental conditions and handling precautions for the NEC miniflat IC family are described below. Circuit Design The electrical characteristics of the N EC miniflat IC are guaranteed the same as those of standard DIP ICs. Since heat radiation is improved when the IC is mounted on the substrate, power dissipation PT can be changed in actual use. However, the degree of change 9-23 tvEe PACKAGING INFORMATION largely depends on the method of mounting (size of substrate, coating method, etc). Therefore, full evaluation of the mounted board should be made in advance. Total Power Dissipation and Thermal Resistance Soldering and Flux Temperature Exposure to high temperatures over time should be carefully monitored to insure prolonged reliability. As An Absolute Maximum Rating, exposure to the following must not exceed 260°C for 10 seconds. Figures 4 and 5 show the total power dissipation characteristics of the NEC miniflat IC family. • Solder dipping • Soldering iron • High-temperature atmosphere As shown in the figures, thermal resistance for a single element is approximately 180°C/W for the 14-pin IC, and approximately 220°C/W for the 8-pin IC. Rosin flux (pine resin) is recommended as soldering flux. When mounted on a hybrid IC or PW-board, the heat radiation through the leads is increased. With resin coating, the heat radiation through the resin to the environment is further increased. As a result, the thermal resistance in the mounted state is much lower. It is suggested that the heat dissipation in actual finished mountings be fully analyzed prior to production. Figure 4. 600 500 E .5 300 ~ ~ 200 0. .... f' 100 25 Being super-miniaturized and employing a thinner plastic than standard DIP ICs, the miniflat IC has shorter leakage paths and requires much more protection against humidity. ~ 4.4mW/CC 1'-. " 1"-.. 75 50 Generally, anti-humidity protection is provided by resin coating after mounting on board. Examples of the process are described below. ...... 100 125 150 Junction Temperature (Oe) Figure 5. P.,-Tj Characteristic (14-Pin Type) 600 One element only 550mW 500 I"- ~ " "- E -; ~ 400 il. "1: is 300 ! 200 D,. " " ~ '" I"\.. i'- 50 75 100 Junction Temperature (Oe) 9-24 ~ " ~~I~ ~~~~~~~~~I"~I 25 • When sealed in an airtight package, no precoating is necessary. • When sealed with resin, a buffer coating may be required as the resin contraction may exert stress on ICs when sealing. Sufficient evaluation should be made on the actual board. For buffer coating, the use of resin with a certain degree of viscosity is suggested. Please consult the resin manufacturers for appropriate encapsulation resin and coating materials. 5.5mW/OC >- ~ Flux should be thoroughly removed after soldering. Alcohol, Chlorocene, and Freon are all acceptable solvents; however, prolonged immersion in these solvents may remove printed markings. Protection Against Humidity " r-..... g 400 ..t One element only ~440mW ~ Cleaning Ultrasonic cleaning can also be applied if other components mounted on the same board can withstand it. P.,-Tj Characteristic (8-Pin Type) I f- NOTE: Avoid flux containing chlorine. Residual chlorine after cleaning may affect reliability. 125 150 ,- .... , NEe NEG Electronics Inc. CORPORATE HEA~QUARTERS 401 Ellis Street P.O. Box 7241 Mountain View, CA 94039 TEL 415-960-6000 TWX 910 -379-6985 86 LINEAR CAT-02-86-USA-50K STOCK NO . 200100 "' 1986 NEC Electronics Inc.lPrinled in U.S.A.
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