THALES DIS AlS Deutschland MC56 Transmitter module for mobile applications User Manual MC55 56
Gemalto M2M GmbH Transmitter module for mobile applications MC55 56
Contents
- 1. Exhibit 8 User manual
- 2. Updated User Manual
Updated User Manual
MC55/56 Siemens Cellular Engine Version: DocID: 03.00 MC55/56_hd_v03.00 MC55/56_hd_v03.00 Page 1 of 104 Hardware Interface Description MC55/56 Hardware Interface Description Confidential / Preliminary 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Document Name: MC55/56 Hardware Interface Description Version: 03.00 Date: August 16, 2005 DocId: MC55/56_hd_v03.00 Status: Confidential / Preliminary General Notes Product is deemed accepted by Recipient and is provided without interface to Recipient’s products. The documentation and/or Product are provided for testing, evaluation, integration and information purposes. The documentation and/or Product are provided on an “as is” basis only and may contain deficiencies or inadequacies. The Documentation and/or Product are provided without warranty of any kind, express or implied. To the maximum extent permitted by applicable law, Siemens further disclaims all warranties, including without limitation any implied warranties of merchantability, completeness, fitness for a particular purpose and non-infringement of third-party rights. The entire risk arising out of the use or performance of the Product and documentation remains with Recipient. This Product is not intended for use in life support appliances, devices or systems where a malfunction of the product can reasonably be expected to result in personal injury. Applications incorporating the described product must be designed to be in accordance with the technical specifications provided in these guidelines. Failure to comply with any of the required procedures can result in malfunctions or serious discrepancies in results. Furthermore, all safety instructions regarding the use of mobile technical systems, including GSM products, which also apply to cellular phones must be followed. Siemens or its suppliers shall, regardless of any legal theory upon which the claim is based, not be liable for any consequential, incidental, direct, indirect, punitive or other damages whatsoever (including, without limitation, damages for loss of business profits, business interruption, loss of business information or data, or other pecuniary loss) arising out the use of or inability to use the Documentation and/or Product, even if Siemens has been advised of the possibility of such damages. The foregoing limitations of liability shall not apply in case of mandatory liability, e.g. under the German Product Liability Act, in case of intent, gross negligence, injury of life, body or health, or breach of a condition which goes to the root of the contract. However, Claims for Damages arising from a breach of a condition which goes to the root of the contract shall be limited to the foreseeable damage which is intrinsic to the contract, unless caused by intent or gross negligence or based on liability for injury of life, body or health. The above provision does not imply a change on the burden of proof to the detriment of the Recipient. Subject to change without notice at any time. The interpretation of this general note shall be governed and construed according to German law without reference to any other substantive law. Copyright Copying of this document and giving it to others and the use or communication of the contents thereof, are forbidden without express authority. Offenders are liable to the payment of damages. All rights reserved in the event of grant of a patent or the registration of a utility model or design. Copyright © Siemens AG 2005 MC55/56_hd_v03.00 Page 2 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Contents Document history..........................................................................................................7 Introduction ...................................................................................................................9 1.1 Related documents................................................................................................9 1.2 Terms and abbreviations .....................................................................................10 1.3 Type approval ......................................................................................................13 1.4 Safety precautions ...............................................................................................15 Product concept..........................................................................................................17 2.1 MC55/56 key features at a glance .......................................................................18 2.2 Circuit concept .....................................................................................................21 Application Interface...................................................................................................22 3.1 Operating modes .................................................................................................23 3.2 Power supply .......................................................................................................25 3.2.1 Power supply pins on the board-to-board connector .............................25 3.2.2 Minimizing power losses ........................................................................26 3.2.3 Monitoring power supply ........................................................................26 3.3 Power up / down scenarios..................................................................................27 3.3.1 Turn on MC55/56 ...................................................................................27 3.3.1.1 Turn on MC55/56 using the ignition line /IGT (Power on)......................28 3.3.1.2 Timing of the ignition process ................................................................29 3.3.1.3 Turn on MC55/56 using the POWER signal ..........................................30 3.3.1.4 Turn on MC55/56 using the RTC (Alarm mode) ....................................30 3.3.2 Turn off MC55/56 ...................................................................................32 3.3.2.1 Turn off MC55/56 using AT command ...................................................32 3.3.2.2 Emergency shutdown using /EMERGOFF pin.......................................33 3.3.3 Automatic shutdown...............................................................................34 3.3.3.1 Temperature dependent shutdown ........................................................34 3.3.3.2 Temperature control during emergency call ..........................................35 3.3.3.3 Undervoltage shutdown if battery NTC is present .................................35 3.3.3.4 Undervoltage shutdown if no battery NTC is present ............................36 3.3.3.5 Overvoltage shutdown ...........................................................................36 3.4 Automatic GPRS Multislot Class change.............................................................37 3.5 Charging control ..................................................................................................38 3.5.1 Battery pack characteristics ...................................................................39 3.5.2 Implemented charging technique...........................................................41 3.5.3 Operating modes during charging..........................................................42 3.5.4 Charger requirements ............................................................................43 3.6 Power saving .......................................................................................................44 3.6.1 No power saving (AT+CFUN=1) ............................................................44 3.6.2 NON-CYCLIC SLEEP mode (AT+CFUN=0) ..........................................44 3.6.3 CYCLIC SLEEP mode (AT+CFUN=5, 6, 7, 8) .......................................45 3.6.4 CYCLIC SLEEP mode AT+CFUN=9 .....................................................45 3.6.5 Timing of the /CTS signal in CYCLIC SLEEP modes ............................45 3.6.6 Wake up MC55/56 from SLEEP mode ..................................................47 3.6.6.1 Wake-up via /RTS0 and RTS1 (if AT+CFUN=0 or AT+CFUN=9)..........48 3.7 Summary of state transitions (except SLEEP mode)...........................................49 3.8 RTC backup.........................................................................................................50 3.9 Serial interfaces ...................................................................................................51 3.9.1 Features supported on first and second serial interface ........................52 MC55/56_hd_v03.00 Page 3 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.10 Audio interfaces ...................................................................................................54 3.10.1 Microphone circuit..................................................................................55 3.10.2 Speech processing ................................................................................56 3.10.3 DAI timing ..............................................................................................56 3.11 SIM interface........................................................................................................58 3.11.1 Requirements for using the CCIN pin ....................................................59 3.11.2 Design considerations for SIM card holder ............................................60 3.12 Control signals .....................................................................................................61 3.12.1 Inputs .....................................................................................................61 3.12.2 Outputs ..................................................................................................62 3.12.2.1 Synchronization signal ...........................................................................62 3.12.2.2 Using the SYNC pin to control a status LED..........................................63 3.12.2.3 Behavior of the /RING0 line (ASC0 interface only) ................................65 Antenna interface........................................................................................................66 4.1 Antenna installation .............................................................................................66 4.1.1 Antenna pad...........................................................................................68 4.1.1.1 Suitable cable types...............................................................................68 4.1.2 Hirose antenna connector......................................................................69 Electrical, reliability and radio characteristics.........................................................73 5.1 Absolute maximum ratings ..................................................................................73 5.2 Operating temperatures.......................................................................................73 5.3 Electrical specifications of the application interface.............................................74 5.4 Power supply ratings ...........................................................................................79 5.4.1 Current consumption during transmit burst............................................80 5.5 Electrical characteristics of the voiceband part....................................................85 5.5.1 Setting audio parameters by AT commands..........................................85 5.5.2 Audio programming model.....................................................................86 5.5.3 Characteristics of audio modes..............................................................87 5.5.4 Voiceband receive path .........................................................................88 5.5.5 Voiceband transmit path ........................................................................89 5.6 Air interface..........................................................................................................90 5.7 Electrostatic discharge.........................................................................................91 5.8 Reliability characteristics .....................................................................................92 Mechanics....................................................................................................................93 6.1 Mechanical dimensions of MC55/56....................................................................93 6.2 Mounting MC55/56 onto the application platform ................................................95 6.3 Board-to-board connector....................................................................................96 6.3.1 Mechanical dimensions of the Hirose DF12 connector..........................97 6.3.2 Adapter cabling ......................................................................................97 Reference Approval ....................................................................................................98 7.1 Reference Equipment for Type Approval.............................................................98 7.2 Compliance with FCC Rules and Regulations (MC55 only) ................................99 7.3 Compliance with FCC Rules and Regulations (MC56 only) ..............................100 Design example.........................................................................................................101 List of parts and accessories...................................................................................103 MC55/56_hd_v03.00 Page 4 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Figures Figure 1: MC55/56 block diagram .......................................................................................... 21 Figure 2: Power supply limits during transmit burst................................................................ 26 Figure 3: Power-on by ignition signal ..................................................................................... 28 Figure 4: Timing of power-on process if VDDLP is not used.................................................. 29 Figure 5: Timing of power-on process if VDDLP is fed from external source......................... 30 Figure 6: Deactivating GSM engine by /EMERGOFF signal .................................................. 33 Figure 7: Schematic of approved charging transistor, trickle charging and ESD protection .. 38 Figure 8: Battery pack circuit diagram.................................................................................... 39 Figure 9: Charging process .................................................................................................... 41 Figure 10: Timing of /CTS signal (example for a 2.12 s paging cycle)................................... 46 Figure 11: Beginning of power saving if CFUN=5 or 7 ........................................................... 46 Figure 12: RTC supply from capacitor.................................................................................... 50 Figure 13: RTC supply from rechargeable battery ................................................................. 50 Figure 14: RTC supply from non-chargeable battery ............................................................. 50 Figure 15: Serial interfaces .................................................................................................... 51 Figure 16: Audio block diagram.............................................................................................. 54 Figure 17: Schematic of microphone inputs ........................................................................... 55 Figure 18: DAI timing on transmit path................................................................................... 57 Figure 19: DAI timing on receive path .................................................................................... 57 Figure 20: SIM card holder of DSB45 Support Box................................................................ 60 Figure 21: Pin numbers of Molex SIM card holder on DSB45 Support Box ........................... 60 Figure 22: SYNC signal during transmit burst ........................................................................ 62 Figure 23: LED Circuit (Example)........................................................................................... 64 Figure 24: Incoming voice call................................................................................................ 65 Figure 25: URC transmission ................................................................................................. 65 Figure 26: U.FL-R-SMT connector ......................................................................................... 66 Figure 27: Antenna pad and GND plane ................................................................................ 66 Figure 28: Never use antenna connector and antenna pad at the same time ....................... 67 Figure 29: Restricted area around antenna pad..................................................................... 67 Figure 30: Mechanical dimensions of U.FL-R-SMT connector............................................... 69 Figure 31: U.FL-R-SMT connector with U.FL-LP-040 plug .................................................... 70 Figure 32: U.FL-R-SMT connector with U.FL-LP-066 plug .................................................... 70 Figure 33: Specifications of U.FL-LP-(V)-040(01) plug .......................................................... 71 Figure 34: Pin assignment (top view on MC55/56) ................................................................ 74 Figure 35: Typical current consumption vs. power control level............................................. 83 Figure 36: Typical current consumption vs. return loss.......................................................... 84 Figure 37: Audio programming model .................................................................................... 86 Figure 38: MC55/56 – top view .............................................................................................. 93 Figure 39: MC55/56 bottom view ........................................................................................... 93 Figure 40: Mechanical dimensions of MC55/56 ..................................................................... 94 Figure 41: Hirose DF12C receptacle on MC55/56 ................................................................. 96 Figure 42: Header Hirose DF12 series................................................................................... 96 Figure 43: Mechanical dimensions of Hirose DF12 connector............................................... 97 Figure 44: Reference equipment for approval........................................................................ 98 Figure 45: Schematic diagram of MC55/56 sample application ........................................... 102 MC55/56_hd_v03.00 Page 5 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Tables Table 1: MC55/56 key features .............................................................................................. 18 Table 2: Coding schemes and maximum net data rates over air interface ............................ 20 Table 3: Overview of operating modes................................................................................... 23 Table 4: Power supply pins of board-to-board connector....................................................... 25 Table 5: AT commands available in Alarm mode................................................................... 31 Table 6: Temperature dependent behaviour .......................................................................... 35 Table 7: Bill of material for external charging circuit............................................................... 38 Table 8: Specifications of recommended battery pack........................................................... 40 Table 9: Comparison Charge-only and Charge mode............................................................ 42 Table 10: AT commands available in Charge-only mode....................................................... 43 Table 11: Wake-up events in NON-CYCLIC and CYCLIC SLEEP modes............................. 47 Table 12: State transitions of MC55/56 (except SLEEP mode) ............................................. 49 Table 13: DCE-DTE wiring of 1st serial interface................................................................... 52 Table 14: DCE-DTE wiring of 2nd serial interface.................................................................. 53 Table 15: Signals of the SIM interface (board-to-board connector) ....................................... 58 Table 16: Pin assignment of Molex SIM card holder on DSB45 Support Box........................ 60 Table 17: Input control signals of the MC55/56 module ......................................................... 61 Table 18: Coding of the status LED ....................................................................................... 63 Table 19: ASC0 ring signal.....................................................................................................65 Table 20: Return loss ............................................................................................................. 66 Table 21: Product specifications of U.FL-R-SMT connector .................................................. 69 Table 22: Material and finish of U.FL-R-SMT connector and recommended plugs ............... 70 Table 23: Ordering information for Hirose U.FL Series .......................................................... 72 Table 24: Absolute maximum ratings ..................................................................................... 73 Table 25: Operating temperatures ......................................................................................... 73 Table 26: Electrical description of application interface ......................................................... 75 Table 27: Power supply ratings .............................................................................................. 79 Table 28: Audio parameters adjustable by AT command ...................................................... 85 Table 29: Voiceband characteristics (typical)......................................................................... 87 Table 30: Voiceband receive path.......................................................................................... 88 Table 31: Voiceband transmit path......................................................................................... 89 Table 32: Air Interface ............................................................................................................ 90 Table 33: Measured electrostatic values................................................................................ 91 Table 34: Summary of reliability test conditions ..................................................................... 92 Table 35: Ordering information DF12 series .......................................................................... 96 Table 36: Electrical and mechanical characteristics of the Hirose DF12C connector ............ 96 Table 37: List of parts and accessories................................................................................ 103 Table 38: Molex sales contacts (subject to change) ............................................................ 104 Table 39: Hirose sales contacts (subject to change)............................................................ 104 MC55/56_hd_v03.00 Page 6 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Document history Preceding document: "MC55/56 Hardware Interface Description" Version 02.90 New document: "MC55/56 Hardware Interface Description" Version 03.00 Chapter What is new 1.3 Deleted section “Compliance with international rules and regulations”. 3.3.1.1 Added further details of timing after power-up. 3.6.2, 3.6.6, 3.6.6.1 More detailed description of RTS wake-up. 3.12.2.2 Some text changes related to LED behavior in CYCLIC SLEEP mode. 7.2, 7.3 Deleted note on extra FCC certification for OEM products. Changed note on recommendations for mobile and fixed devices. Added FCC labeling requirements. Preceding document: "MC55/56 Hardware Interface Description" Version 02.06 New document: "MC55/56 Hardware Interface Description" Version 02.90 Chapter What is new Throughout document Updated module images. 1.3 Added European Directives related to RoHS and WEEE. 3.5.2 Described charging procedure if battery was deeply discharged. 3.12.2.3 Same description of RING line behavior for voice, data, fax. 6.2 Deleted screw and washer restrictions for mounting holes of MC55/56. 6.1 Updated figure “Mechanical dimensions of MC55/56” Siemens ordering numbers changed. Preceding document: "MC55/56 Hardware Interface Description" Version 01.95 New document: "MC55/56 Hardware Interface Description" Version 02.06 Chapter What is new 5.5.3 Table 29: Sidetone gain at default settings for audio mode 5 and 6 set to -∞ dB Added new Siemens ordering numbers Preceding document: "MC55/56 Hardware Interface Description" Version 01.05 New document: "MC55/56 Hardware Interface Description" Version 01.95 Chapter What is new Throughout document Maximum temperature has been changed from +65°C to +70°C. 1.3 Updated list of standards. 3.6, 3.12.2.2 More detailed description of status LED patterns. 3.5.1 Deleted vendor XWODA, battery pack can be obtained from various dealers. 3.11 Use CCGND line to shield CCIO line from CCCLK line. 5.2 Added footnote regarding heat sink. 5.4 Typical value for supply voltage has been changed from 4.1V to 4.2V MC55/56_hd_v03.00 Page 7 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Chapter What is new 7.2, 7.3 Added IC: 267W-MC55 and IC: IC: 267W-MC56 New chapter: Design example ---- Deleted chapter “Maximum number of turn-on / turn-off cycles” Preceding document: "MC55/56 Hardware Interface Description" Version 01.03a New document: "MC55/56 Hardware Interface Description" Version 01.05 Chapter What is new 1.3 Updated list of standards, MC55/56 now fully type approved and labeled with CE mark 2.2 New block diagram. 3.2.2, 5.3 All statements relating to typical peak current now 1.6 A. 3.2.3 More detailed description of measuring periods for BATT+. 3.1, 3.5.3 Removed remarks about charging during Alarm mode 3.3.1.4 Battery can be charged while module is in Alarm mode. 3.3.2.1 To keep /EMERGOFF pin and output pins of the serial interfaces from floating when in high impedance state use additional resistors. 3.3.3.5 Modified description of overvoltage conditions. 3.5 Improved Figure 7. 3.6 Added SLEEP mode 9, added information on RTS, revised Table 11. 3.12.2.3 Advantages of the /RING0 line usage explained in more detail. 4.1 Marked antenna pad and ground pad. 4.1.2 Rated frequency changed from 3 to 6 GHz 5.3 Table 26 - /EMERGOFF pin and output pins of serial interface: To keep output pins from floating when in high impedance state use additional resistors. 5.4 Added test conditions for TALK and DATA GPRS: 50 Ω 5.4.1 Revised introduction. 5.5.2 Improved Figure 37: Audio programming model 6.1 New drawing in Figure 40. Corrected height from 2.8 ±0.2 to 2.95 ±0.2 mm 6.2 Revised mounting instructions. Siemens ordering numbers added. --- Deleted chapter on cooling elements. Preceding document: "MC55/56 Hardware Interface Description" Version 01.03 New document: "MC55/56 Hardware Interface Description" Version 01.03a Chapter What is new 7.2, 7.3 Corrected MC55 and MC56 specific information on FFC compliance Preceding document: "MC55/56 Hardware Interface Description" Version 01.02 New document: "MC55/56 Hardware Interface Description" Version 01.03 Chapter What is new 1.3 Note on necessary FCC certification added. MC55/56_hd_v03.00 Page 8 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Introduction This document describes the hardware interface of the Siemens MC55/56 module that connects to the cellular device application and the air interface. As MC55/56 is intended to integrate with a wide range of application platforms, all functional components are described in great detail. This guide therefore covers all information needed to design and set up cellular applications incorporating the MC55/56 module. It aids rapid retrieval of interface specifications, electrical and mechanical details and information on the requirements to be considered for integration of further components. 1.1 [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] Related documents MC55 AT Command, Version 03.00 MC56 AT Command, Version 03.00 MC55/56 Release Notes, Version 03.00 GPRS Startup User's Guide Remote-SAT User's Guide DSB45 Support Box - Evaluation Kit for Siemens Cellular Engines Application Note 23: Installing MC55/56 on DSB45 Application Note 07: Li-Ion Batteries in GSM Applications Application Note 16: Upgrading MC5x Firmware, Version 06 Application Note 14: Audio and Battery Parameter Download Application Note 02: Audio Interface Design Multiplexer User's Guide Multiplex Driver Developer’s Guide for Windows 2000 and Windows XP Multiplex Driver Installation Guide for Windows 2000 and Windows XP Application Note 22: Using TTY / CTM equipment Application Note 24: Application Developer’s Guide Application Note 28: Customer SIM Lock Prior to using the MC55/56 engines or upgrading to a new firmware release, be sure to carefully read the latest product information. To visit the Siemens Website you can use the following link: http://www.siemens.com/wm MC55/56_hd_v03.00 Page 9 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 1.2 Terms and abbreviations Abbreviation Description ADC Analog-to-Digital Converter AFC Automatic Frequency Control AGC Automatic Gain Control ANSI American National Standards Institute ARFCN Absolute Radio Frequency Channel Number ARP Antenna Reference Point ASC0 / ASC1 Asynchronous Serial Controller. Abbreviations used for first and second serial interface of MC55/56 ASIC Application Specific Integrated Circuit Thermistor Constant B2B Board-to-board connector BER Bit Error Rate BTS Base Transceiver Station CB or CBM Cell Broadcast Message CE Conformité Européene (European Conformity) CHAP Challenge Handshake Authentication Protocol CPU Central Processing Unit CS Coding Scheme CSD Circuit Switched Data CTS Clear to Send DAC Digital-to-Analog Converter DAI Digital Audio Interface dBm0 Digital level, 3.14dBm0 corresponds to full scale, see ITU G.711, A-law DCE Data Communication Equipment (typically modems, e.g. Siemens GSM engine) DCS 1800 Digital Cellular System, also referred to as PCN DRX Discontinuous Reception DSB Development Support Box DSP Digital Signal Processor DSR Data Set Ready DTE Data Terminal Equipment (typically computer, terminal, printer or, for example, GSM application) DTR Data Terminal Ready DTX Discontinuous Transmission EFR Enhanced Full Rate EGSM Enhanced GSM MC55/56_hd_v03.00 Page 10 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Abbreviation Description EMC Electromagnetic Compatibility ESD Electrostatic Discharge ETS European Telecommunication Standard FCC Federal Communications Commission (U.S.) FDMA Frequency Division Multiple Access FR Full Rate GMSK Gaussian Minimum Shift Keying GPRS General Packet Radio Service GSM Global Standard for Mobile Communications HiZ High Impedance HR Half Rate I/O Input/Output IC Integrated Circuit IMEI International Mobile Equipment Identity ISO International Standards Organization ITU International Telecommunications Union kbps kbits per second LED Light Emitting Diode Li-Ion Lithium-Ion Mbps Mbits per second MMI Man Machine Interface MO Mobile Originated MS Mobile Station (GSM engine), also referred to as TE MSISDN Mobile Station International ISDN number MT Mobile Terminated NTC Negative Temperature Coefficient OEM Original Equipment Manufacturer PA Power Amplifier PAP Password Authentication Protocol PBCCH Packet Switched Broadcast Control Channel PCB Printed Circuit Board PCL Power Control Level PCM Pulse Code Modulation PCN Personal Communications Network, also referred to as DCS 1800 PCS Personal Communication System, also referred to as GSM 1900 PDU Protocol Data Unit PLL Phase Locked Loop MC55/56_hd_v03.00 Page 11 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Abbreviation Description PPP Point-to-point protocol PSU Power Supply Unit R&TTE Radio and Telecommunication Terminal Equipment RAM Random Access Memory RF Radio Frequency RMS Root Mean Square (value) ROM Read-only Memory RTC Real Time Clock Rx Receive Direction SAR Specific Absorption Rate SELV Safety Extra Low Voltage SIM Subscriber Identification Module SMS Short Message Service SRAM Static Random Access Memory TA Terminal adapter (e.g. GSM engine) TDMA Time Division Multiple Access TE Terminal Equipment, also referred to as DTE Tx Transmit Direction UART Universal asynchronous receiver-transmitter URC Unsolicited Result Code USSD Unstructured Supplementary Service Data VSWR Voltage Standing Wave Ratio Phonebook abbreviations FD SIM fixdialing phonebook LD SIM last dialling phonebook (list of numbers most recently dialled) MC Mobile Equipment list of unanswered MT calls (missed calls) ME Mobile Equipment phonebook ON Own numbers (MSISDNs) stored on SIM or ME RC Mobile Equipment list of received calls SM SIM phonebook MC55/56_hd_v03.00 Page 12 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 1.3 Type approval MC55/56 has been approved to comply with the directives and standards listed below and is labeled with the CE conformity mark. European directives 99/05/EC “Directive of the European Parliament and of the Council of 9 March 1999 on radio equipment and telecommunications terminal equipment and the mutual recognition of their conformity”, in short referred to as R&TTE Directive 1999/5/EC 89/336/EC Directive on electromagnetic compatibility 73/23/EC Directive on electrical equipment designed for use within certain voltage limits (Low Voltage Directive) 2002/95/EC Directive of the European Parliament and of the Council of 27 January 2003 on the restriction of the use of certain hazardous substances in electrical and electronic equipment (RoHS) 2002/96/EC Directive of the European Parliament and of the Council on waste electrical and electronic equipment (WEEE) 2003/108/EC Directive of the European Parliament and of the Council of 8 December 2003 amending directive 2002/96/ec on waste electrical and electronic equipment (WEEE) Standards of North American Type Approval CFR Title 47 “Code of Federal Regulations, Part 22 and Part 24 (Telecommunications, PCS)”; US Equipment Authorization FCC UL 60 950 “Product Safety Certification” (Safety requirements) NAPRD.03 “Overview of PCS Type certification review board Mobile Equipment Type Certification and IMEI control” PCS Type Certification Review board (PTCRB), Version 3.00 RSS133 (Issue2) Canadian Standard Standards of European Type Approval 3GPP TS 51.010-1 “Digital cellular telecommunications system (Phase 2); Mobile Station (MS) conformance specification” ETSI EN 301 511 “V7.0.1 (2000-12) Candidate Harmonized European Standard (Telecommunications series) Global System for Mobile communications (GSM); Harmonized standard for mobile stations in the GSM 900 and DCS 1800 bands covering essential requirements under article 3.2 of the R&TTE directive (1999/5/EC) (GSM 13.11 version 7.0.1 Release 1998)” GCF-CC “Global Certification Forum - Certification Criteria” V3.18.0 MC55/56_hd_v03.00 Page 13 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary ETSI EN 301 489-1 “V1.2.1 Candidate Harmonized European Standard (Telecommunications series) Electro Magnetic Compatibility and Radio spectrum Matters (ERM); Electro Magnetic Compatibility (EMC) standard for radio equipment and services; Part 1: Common Technical Requirements” ETSI EN 301 489-07 “V1.1.1 Electro Magnetic Compatibility and Radio spectrum Matters (ERM); Electro Magnetic Compatibility (EMC) standard for radio equipment and services; Part 7: Specific conditions for mobile and portable radio and ancillary equipment of digital cellular radio telecommunications systems (GSM and DCS)” EN 60 950 Safety of information technology equipment (2000) Requirements of quality IEC 60068 DIN EN 60529 Environmental testing IP codes SAR requirements specific to handheld mobiles Mobile phones, PDAs or other handheld transmitters and receivers incorporating a GSM module must be in accordance with the guidelines for human exposure to radio frequency energy. This requires the Specific Absorption Rate (SAR) of handheld MC55/56 based applications to be evaluated and approved for compliance with national and/or international regulations. Since the SAR value varies significantly with the individual product design manufacturers are advised to submit their product for approval if designed for handheld operation. For European and US markets the relevant directives are mentioned below. It is the responsibility of the manufacturer of the final product to verify whether or not further standards, recommendations or directives are in force outside these areas. Products intended for sale on US markets ES 59005/ANSI C95.1 Considerations for evaluation of human exposure to Electromagnetic Fields (EMFs) from Mobile Telecommunication Equipment (MTE) in the frequency range 30MHz-6GHz Products intended for sale on European markets EN 50360 Product standard to demonstrate the compliance of mobile phones with the basic restrictions related to human exposure to electromagnetic fields (300 MHz - 3 GHz) MC55/56_hd_v03.00 Page 14 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 1.4 Safety precautions The following safety precautions must be observed during all phases of the operation, usage, service or repair of any cellular terminal or mobile incorporating MC55/56. Manufacturers of the cellular terminal are advised to convey the following safety information to users and operating personnel and to incorporate these guidelines into all manuals supplied with the product. Failure to comply with these precautions violates safety standards of design, manufacture and intended use of the product. Siemens AG assumes no liability for customer failure to comply with these precautions. When in a hospital or other health care facility, observe the restrictions on the use of mobiles. Switch the cellular terminal or mobile off, if instructed to do so by the guidelines posted in sensitive areas. Medical equipment may be sensitive to RF energy. The operation of cardiac pacemakers, other implanted medical equipment and hearing aids can be affected by interference from cellular terminals or mobiles placed close to the device. If in doubt about potential danger, contact the physician or the manufacturer of the device to verify that the equipment is properly shielded. Pacemaker patients are advised to keep their hand-held mobile away from the pacemaker, while it is on. Switch off the cellular terminal or mobile before boarding an aircraft. Make sure it cannot be switched on inadvertently. The operation of wireless appliances in an aircraft is forbidden to prevent interference with communications systems. Failure to observe these instructions may lead to the suspension or denial of cellular services to the offender, legal action, or both. Do not operate the cellular terminal or mobile in the presence of flammable gases or fumes. Switch off the cellular terminal when you are near petrol stations, fuel depots, chemical plants or where blasting operations are in progress. Operation of any electrical equipment in potentially explosive atmospheres can constitute a safety hazard. Your cellular terminal or mobile receives and transmits radio frequency energy while switched on. Remember that interference can occur if it is used close to TV sets, radios, computers or inadequately shielded equipment. Follow any special regulations and always switch off the cellular terminal or mobile wherever forbidden, or when you suspect that it may cause interference or danger. Road safety comes first! Do not use a hand-held cellular terminal or mobile when driving a vehicle, unless it is securely mounted in a holder for handsfree operation. Before making a call with a hand-held terminal or mobile, park the vehicle. Handsfree devices must be installed by qualified personnel. Faulty installation or operation can constitute a safety hazard. MC55/56_hd_v03.00 Page 15 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary SOS IMPORTANT! Cellular terminals or mobiles operate using radio signals and cellular networks. Because of this connection cannot be guaranteed at all times under all conditions. Therefore, you should never rely solely upon any wireless device for essential communications, for example emergency calls. Remember, in order to make or receive calls, the cellular terminal or mobile must be switched on and in a service area with adequate cellular signal strength. Some networks do not allow for emergency calls if certain network services or phone features are in use (e.g. lock functions, fixed dialling etc.). You may need to deactivate those features before you can make an emergency call. Some networks require that a valid SIM card be properly inserted in the cellular terminal or mobile. MC55/56_hd_v03.00 Page 16 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Product concept Designed for use on any GSM network in the world, Siemens MC55 is a tri-band GSM/GPRS engine that works on the three frequencies GSM 900 MHz, GSM 1800 MHz and GSM 1900 MHz. MC56 is a tri-band GSM/GPRS engine that works on the three frequencies GSM 850MHz, GSM 1800 MHz and GSM 1900 MHz. MC55/56 features GPRS multislot class 10 and supports the GPRS coding schemes CS-1, CS-2, CS-3 and CS-4. To save space on the application platform, MC55/56 comes as an extremely slim and compact module. This makes it ideally suited for a broad range of mobile computing devices, and particularly offers easy integration with smart phones, PDAs, and other handhelds. The tiny MC55/56 module incorporates all you need to create high-performance GSM/GPRS solutions: baseband processor, power supply ASIC, complete radio frequency circuit including a power amplifier and antenna interface. The power amplifier is directly fed from the supply voltage BATT+. A compact “stacked FLASH / SRAM” device stores the MC55/56 software in the flash memory section, and static RAM section provides the additional storage capacity required by GPRS connectivity. The physical interface to the cellular application is made through a board-to-board connector. It consists of 50 pins, required for controlling the unit, transferring data and audio signals and providing power supply lines. MC55/56 comprises two serial interfaces (ASC0 and ASC1) giving you maximum flexibility for easy integration with the Man-Machine Interface (MMI). An extremely versatile audio concept offers various audio interfaces, each available on the board-to-board connector: a digital audio interface (DAI) and two analog audio interfaces. Using AT commands you can easily switch back and forth and select different audio modes. The external dual-band or triple-band antenna can be connected optionally to a connector on the top side or to a pad on the bottom side. The power saving technique minimizes current consumption to as low as 3mA. In SLEEP mode, MC55/56 is able to wake up on demand and to resume power saving automatically if no activity is required. For battery powered applications, MC55/56 features a charging control which can be used to charge a Li-Ion battery. The charging circuit must be implemented outside the module on the application platform. MC55/56_hd_v03.00 Page 17 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 2.1 MC55/56 key features at a glance Table 1: MC55/56 key features Feature Implementation Power supply Single supply voltage 3.3V – 4.8V Power saving Minimizes power consumption in SLEEP mode to 3mA Charging Supports charging control for Li-Ion battery Frequency bands • MC55 Tri-band: EGSM 900, GSM 1800, GSM 1900 • MC56 Tri-band: GSM 850, GSM 1800, GSM 1900 • Compliant to GSM Phase 2/2+ GSM class Small MS Transmit power • Class 4 (2W) at EGSM 900 and GSM 850 • Class 1 (1W) at GSM 1800 and GSM 1900 GPRS connectivity • GPRS multi-slot class 10 • GPRS mobile station class B Temperature range • Normal operation: • Restricted operation: Temperature control and auto switch-off DATA -20°C to +55°C -25°C to -20°C and +55°C to +70°C • Constant temperature control prevents damage to MC55/56 when the specified temperature is exceeded. When an emergency call is in progress the automatic temperature shutdown functionality is deactivated. GPRS: • GPRS data downlink transfer: max. 85.6 kbps (see Table 2) • GPRS data uplink transfer: max. 42.8 kbps (see Table 2) • Coding scheme: CS-1, CS-2, CS-3 and CS-4 • MC55/56 supports the two protocols PAP (Password Authentication Protocol) and CHAP (Challenge Handshake Authentication Protocol) commonly used for PPP connections. • Support of Packet Switched Broadcast Control Channel (PBCCH) allows you to benefit from enhanced GPRS performance when offered by the network operators. CSD: • CSD transmission rates: 2.4, 4.8, 9.6, 14.4 kbps, non-transparent, V.110 • Unstructured WAP: SMS Supplementary Services Data (USSD) support • WAP compliant • MT, MO, CB, Text and PDU mode • SMS storage: SIM card plus 25 SMS locations in the mobile equipment • Transmission of SMS alternatively over CSD or GPRS. Preferred mode can be user-defined. MMS MMS compliant FAX Group 3: Class 1, Class 2 SIM interface • Supported SIM card: 3V • External SIM card reader has to be connected via interface connector (note that card reader is not part of MC55/56) MC55/56_hd_v03.00 Page 18 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Feature Implementation External antenna Connected via 50 Ohm antenna connector or antenna pad Audio interfaces Two analog audio interfaces, one digital audio interface (DAI) Audio features Speech codec modes: • Half Rate (ETS 06.20) • Full Rate (ETS 06.10) • Enhanced Full Rate (ETS 06.50 / 06.60 / 06.80) • Adaptive Multi Rate (AMR) Handsfree operation • Echo cancellation • Noise reduction Two serial interfaces: ASC0, ASC1 • 2.65V level, bi-directional bus for AT commands and data • ASC0 – full-featured 8-wire serial interface. Supports RTS0/CTS0 hardware handshake and software XON/XOFF flow control. Multiplex ability according to GSM 07.10 Multiplexer Protocol. • ASC1 - 4-wire serial interface. Supports RTS1/CTS1 hardware handshake and software XON/XOFF flow control. • Baud rate: 300bps ... 230kbps on ASC0 and ASC1 • Autobauding (on ASC0 only) detects 1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200, 230400 bps Phonebook management Supported phonebook types: SM, FD, LD, MC, RC, ON, ME SIM Application Toolkit Supports SAT class 3, GSM 11.14 Release 98, support of letter class “c” Ringing tones Offers a choice of 7 different ringing tones / melodies, easily selectable with AT command Real time clock Implemented Timer function Programmable via AT command Support of TTY/CTM To benefit from TTY communication via GSM, CTM equipment can be connected to one of the three audio interfaces. Physical characteristics Size: 35+0.15 x 32.5+0.15 application connector) 3.1+0.3 mm (including 35+0.15 x 32.5+0.15 x 2.95+0.2 mm (excluding application connector) Weight: 5.5g RoHS, WEEE All hardware components are fully compliant with the EU RoHS and WEEE Directives Firmware upgrade Firmware upgradable over serial interface and SIM interface Evaluation kit The DSB45 Support Box is an evaluation kit designed to test and type approve Siemens cellular engines and provide a sample configuration for application engineering. See Chapter 9 for ordering information. MC55/56_hd_v03.00 Page 19 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Table 2: Coding schemes and maximum net data rates over air interface Coding scheme 1 Timeslot 2 Timeslots 4 Timeslots CS-1: 9.05 kbps 18.1 kbps 36.2 kbps CS-2: 13.4 kbps 26.8 kbps 53.6 kbps CS-3: 15.6 kbps 31.2 kbps 62.4 kbps CS-4: 21.4 kbps 42.8 kbps 85.6 kbps Please note that the values stated above are maximum ratings which, in practice, are influenced by a great variety of factors, primarily, for example, traffic variations and network coverage. MC55/56_hd_v03.00 Page 20 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 2.2 Circuit concept Figure 1 shows a block diagram of the MC55/56 module and illustrates the major functional components: GSM / GPRS baseband block: • Baseband controller operating at 26MHz • Power supply ASIC • Stacked Flash / SRAM • Application interface (board-to-board connector) GSM RF block: • Skyworks RF transceiver • Skyworks RF power amplifier / FEM • RF front end (antenna connector) RF Power Amplifier Data SRAM Adr Control Interface RF - Baseband Baseband Controller Send Data Flash Adr Control Receive Control DAI 2x Audio ASC0 CCRST CCCLK CCIO CCIN CCVCC (GND) ASC1 SYNC SIM Interface VDD Measuring Network VDDLP /EMERGOFF Power Supply ASIC /IGT POWER CHARGE BATT+ GND MC5x CCIN Application Interface (50 pins) RF Section CCVCC SIM Charger input Ext. Charging Circuit NTC BATT_TEMP Figure 1: MC55/56 block diagram MC55/56_hd_v03.00 Page 21 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Application Interface MC55/56 is equipped with a 50-pin 0.5mm pitch board-to-board connector that connects to the cellular application platform. The host interface incorporates several sub-interfaces described in the following chapters: • Power supply and charging control (see Chapters 3.2 and 3.3) • Dual serial interface (see Chapter 3.9) • Two analog audio interfaces and a digital audio interface (see Chapter 3.10) • SIM interface (see Chapter 3.11) Electrical and mechanical characteristics of the board-to-board connector are specified in Chapter 6.3. Ordering information for mating connectors and cables are included. MC55/56_hd_v03.00 Page 22 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.1 Operating modes The table below briefly summarizes the various operating modes referred to in the following chapters. Table 3: Overview of operating modes Mode Function Normal operation GSM / GPRS SLEEP Various powersave command. modes set with AT+CFUN Software is active to minimum extent. If the module was registered to the GSM network in IDLE mode, it is registered and paging with the BTS in SLEEP mode, too. Power saving can be chosen at different levels: The NON-CYCLIC SLEEP mode (AT+CFUN=0) disables the AT interface. The CYCLIC SLEEP modes AT+CFUN=5, 6, 7, 8 and 9 alternatively activate and deactivate the AT interfaces to allow permanent access to all AT commands. POWER DOWN GSM IDLE Software is active. Once registered to the GSM network, paging with BTS is carried out. The module is ready to send and receive. GSM TALK Connection between two subscribers is in progress. Power consumption depends on network coverage individual settings, such as DTX off/on, FR/EFR/HR, hopping sequences, antenna. GPRS IDLE Module is ready for GPRS data transfer, but no data is currently sent or received. Power consumption depends on network settings and GPRS configuration (e.g. multislot settings). GPRS DATA GPRS data transfer in progress. Power consumption depends on network settings (e.g. power control level), uplink / downlink data rates and GPRS configuration (e.g. used multislot settings). Normal shutdown after sending the AT^SMSO command. The Power Supply ASIC (PSU-ASIC) disconnects the supply voltage from the baseband part of the circuit. Only a voltage regulator in the PSU-ASIC is active for powering the RTC. Software is not active. The serial interfaces are not accessible. Operating voltage (connected to BATT+) remains applied. Alarm mode MC55/56_hd_v03.00 Restricted operation launched by RTC alert function while the module is in POWER DOWN mode. Module will not be registered to GSM network. Limited number of AT commands is accessible. Page 23 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Mode Function Charge-only mode Limited operation for battery powered applications. Enables charging while module is detached from GSM network. Limited number of AT commands is accessible. There are several ways to launch Charge-only mode: • From POWER DOWN mode: Connect charger to the charger input pin of the external charging circuit and the module’s POWER pin when MC55/56 was powered down by AT^SMSO. • From Normal mode: Connect charger to the charger input pin of the external charging circuit and the module’s POWER pin, then enter AT^SMSO. Charge mode during normal operation Normal operation (SLEEP, IDLE, TALK, GPRS IDLE, GPRS DATA) and charging running in parallel. Charge mode changes to Charge-only mode when the module is powered down before charging has been completed. See Table 11 and Table 12 for the various options of waking up MC55/56 and proceeding from one mode to another. MC55/56_hd_v03.00 Page 24 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.2 Power supply The power supply of MC55/56 has to be a single voltage source of VBATT+= 3.3V...4.8V. It must be able to provide sufficient current in a transmit burst which typically rises to 2A. Beyond that, the power supply must be able to account for increased current consumption if the module is exposed to inappropriate conditions, for example antenna mismatch. For further details see Chapters 3.2.2 and 5.4.1. All the key functions for supplying power to the device are handled by an ASIC power supply. The ASIC provides the following features: • Stabilizes the supply voltages for the GSM baseband using low drop linear voltage regulators. • Controls the module's power up and power down procedures. A watchdog logic implemented in the baseband processor periodically sends signals to the ASIC, allowing it to maintain the supply voltage for all digital MC55/56 components. Whenever the watchdog pulses fail to arrive constantly, the module is turned off. • Delivers, across the VDD pin, a regulated voltage of 2.9V. The output voltage VDD may be used to supply, for example, an external LED or a level shifter. However, the external circuitry must not cause any spikes or glitches on voltage VDD. This voltage is not available in POWER DOWN mode. Therefore, the VDD pin can be used to indicate whether or not MC55/56 is in POWER DOWN mode. • Provides power to the SIM interface. The RF power amplifier is driven directly from BATT+. 3.2.1 Power supply pins on the board-to-board connector Five BATT+ pins of the board-to-board connector are dedicated to connect the supply voltage, five GND pins are recommended for grounding. The values stated below must be measured directly at the reference points on the MC55/56 board (TP BATT+ and TP GND illustrated in Figure 39). The POWER and CHARGE pins serve as control signals for charging a Li-Ion battery. VDDLP can be used to back up the RTC. Table 4: Power supply pins of board-to-board connector Signal name I/O Description Parameter BATT+ I/O Positive operating voltage 3.3 V...4.8 V, Ityp ≤ 2 A during transmit burst Reference points are the test points The minimum operating voltage must not fall below 3.3 V, not even in case of voltage drop. 0V GND Ground POWER This line signals to the processor that the charger is connected. CHARGE Control signal for external charging transistor VDDLP I/O Can be used to back up the RTC when VBATT+ is not applied. See Chapter 3.8 MC55/56_hd_v03.00 UOUT,max < VBATT+ UIN = 2.0 V...5.5 V Ri = 1kΩ Iin,max = 30µA Page 25 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.2.2 Minimizing power losses When designing the power supply for your application please pay specific attention to power losses. Ensure that the input voltage VBATT+ never drops below 3.3V on the MC55/56 board, not even in a transmit burst where current consumption can rise to typical peaks of 1.6A. It should be noted that MC55/56 switches off when exceeding these limits. Any voltage drops that may occur in a transmit burst should not exceed 400mV. For further details see Chapter 5.4. The best approach to reducing voltage drops is to use a board-to-board connection as recommended, and a low impedance power source. The resistance of the power supply lines on the host board and of a battery pack should also be considered. Note: If the application design requires an adapter cable between both board-to-board connectors, use a cable as short as possible in order to minimize power losses. Example: If the length of the cable reaches the maximum length of 200mm, this connection may cause, for example, a resistance of 50mΩ in the BATT+ line and 50mΩ in the GND line. As a result, a 1.6A transmit burst would add up to a total voltage drop of 160mV. Plus, if a battery pack is involved, further losses may occur due to the resistance across the battery lines and the internal resistance of the battery including its protective circuit. Transmit burst 1.6A Transmit burst 1.6A BATT+ Drop min. 3.3V Ripple Figure 2: Power supply limits during transmit burst The input voltage VBATT+ must be measured directly at the test points on the MC55/56 board (TP BATT+ and TP GND illustrated in Figure 39). 3.2.3 Monitoring power supply To help you monitor the supply voltage you can use the AT^SBV command which returns the voltage measured at TP BATT+ and GND. The voltage is continuously measured at intervals depending on the operating mode on the RF interface. The duration of measuring ranges from 0.5s in TALK/DATA mode up to 50s when MC55/56 is in IDLE mode or Limited Service (deregistered). The displayed voltage (in mV) is averaged over the last measuring period before the AT^SBV command was executed. For details please refer to [1]. MC55/56_hd_v03.00 Page 26 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.3 Power up / down scenarios In general, be sure not to turn on MC55/56 while it is out of the operating range of voltage and temperature stated in Chapters 5.2 and 5.3. MC55/56 would immediately switch off after having started and detected these inappropriate conditions. 3.3.1 Turn on MC55/56 MC55/56 can be activated in a variety of ways, which are described in the following chapters: • via ignition line /IGT: starts normal operating state (see Chapters 3.3.1.1 and 3.3.1.2) • via POWER line: starts charging algorithm (see Chapters 3.5.3 and 0) • via RTC interrupt: starts Alarm mode (see Chapter 3.3.1.4) MC55/56_hd_v03.00 Page 27 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.3.1.1 Turn on MC55/56 using the ignition line /IGT (Power on) To switch on MC55/56 the /IGT (Ignition) signal needs to be driven to ground level for at least 100ms and not earlier than 10ms after the last falling edge of VDD. This can be accomplished using an open drain/collector driver in order to avoid current flowing into this pin. BATT+ min. 10ms HiZ min. 100ms HiZ /IGT ca. 60ms VDD /TXD0 /TXD1 /DSR0 /EMERGOFF Serial interfaces ASC0 and ASC1 Software controlled Undefined ca. 300ms Inactive Active ca. 900ms For details please see Chapter 3.3.1.2 Figure 3: Power-on by ignition signal In a battery operated MC55/56 application, the duration of the /IGT signal must be 1s minimum when the charger is connected and you may want to go from Charge only mode to Normal mode. MC55/56_hd_v03.00 Page 28 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Assertion of CTS indicates that the module is ready to receive data from the host application. In addition, if configured to a fixed bit rate (AT+IPR≠0), the module will send the URC “^SYSSTART” which notifies the host application that the first AT command can be sent to the module. The duration until this URC is output varies with the SIM card and may take a couple of seconds, particularly if the request for the SIM PIN is deactivated on the SIM card. Please note that no “^SYSSTART” URC will be generated if autobauding (AT+IPR=0) is enabled. To allow the application to detect the ready state of the module we recommend using hardware flow control which can be set with AT\Q or AT+ICF (see [1] for details). The default setting of MC55/56 is AT\Q0 (no flow control) which shall be altered to AT\Q3 (RTS/CTS handshake). If the application design does not integrate RTS/CTS lines the host application shall wait at least for the “^SYSSTART” URC. However, if the URCs are neither used (due to autobauding) then the only way of checking the module’s ready state is polling. To do so, try to send characters (e.g. “at”) until the module is responding. 3.3.1.2 Timing of the ignition process When designing your application platform take into account that powering up MC55/56 requires the following steps. • The ignition line cannot be operated until VBATT+ passes the level of 3.0V. • The ignition line shall not be operated earlier than 10ms after the last falling edge of VDD. • 10ms after VBATT+ has reached 3.0V the ignition line can be switched low. The duration of the falling edge must not exceed 1ms. • Another 100ms are required to power up the module. • Ensure that VBATT+ does not fall below 3.0V while the ignition line is driven. Otherwise the module cannot be activated. • If the VDDLP line is fed from an external power supply as explained in Chapter 3.8, the /IGT line is HiZ before the rising edge of BATT+. 3.0V BATT+ 0V HiZ HiZ /IGT 10ms min. 100ms max. 1ms Figure 4: Timing of power-on process if VDDLP is not used MC55/56_hd_v03.00 Page 29 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.0V BATT+ 0V HiZ HiZ /IGT 10ms min. 100ms max. 1ms Figure 5: Timing of power-on process if VDDLP is fed from external source 3.3.1.3 Turn on MC55/56 using the POWER signal As detailed in Chapter 3.5.3, the charging adapter can be connected regardless of the module’s operating mode. If the charger is connected to the charger input of the external charging circuit and the module’s POWER pin while MC55/56 is off, processor controlled fast charging starts (see Chapter 3.5.2). MC55/56 enters a restricted mode, referred to as Charge-only mode where only the charging algorithm will be launched. During the Charge-only mode MC55/56 is neither logged on to the GSM network nor are the serial interfaces fully accessible. To switch to normal operation and log on to the GSM network, the /IGT line needs to be activated. 3.3.1.4 Turn on MC55/56 using the RTC (Alarm mode) Another power-on approach is to use the RTC, which is constantly supplied with power from a separate voltage regulator in the power supply ASIC. The RTC provides an alert function, which allows the MC55/56 to wake up whilst the internal voltage regulators are off. To prevent the engine from unintentionally logging into the GSM network, this procedure only enables restricted operation, referred to as Alarm mode. It must not be confused with a wake-up or alarm call that can be activated by using the same AT command, but without switching off power. Use the AT+CALA command to set the alarm time. The RTC retains the alarm time if MC55/56 was powered down by AT^SMSO. Once the alarm is timed out and executed, MC55/56 enters the Alarm mode. This is indicated by an Unsolicited Result Code (URC) which reads: ^SYSSTART ALARM MODE Note that this URC is the only indication of the Alarm mode and will not appear when autobauding was activated (due to the missing synchronization between DTE and DCE upon start-up). Therefore, it is recommended to select a fixed baudrate before using the Alarm mode. MC55/56_hd_v03.00 Page 30 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary In Alarm mode only a limited number of AT commands is available. For further instructions refer to the AT Command Set. Table 5: AT commands available in Alarm mode AT command Use AT+CALA Set alarm time AT+CCLK Set date and time of RTC AT^SBC In Alarm mode, you can only query the present current consumption and check whether or not a charger is connected. The battery capacity is returned as 0, regardless of the actual voltage (since the values measured directly on the cell are not delivered to the module). AT^SCTM Query temperature range, enable/disable URCs to report critical temperature ranges AT^SMSO Power down GSM engine For the GSM engine to change from the Alarm mode to full operation (normal operating mode) it is necessary to drive the ignition line to ground. This must be implemented in your host application as described in Chapter 3.3.1.1. If the charger is connected to the POWER line when MC55/56 is in ALARM mode charging will start, while MC55/56 stays in ALARM mode. See also Chapter 3.7 which summarizes the various options of changing the mode of operation. If your host application uses the SYNC pin to control a status LED as described in Chapter 3.12.2.2, please note that the LED is off while the GSM engine is in Alarm mode. MC55/56_hd_v03.00 Page 31 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.3.2 Turn off MC55/56 To switch the module off the following procedures may be used: • • • Normal shutdown procedure: Software controlled by sending the AT^SMSO command over the serial application interface. See Chapter 3.3.2.1. Emergency shutdown: Hardware driven by switching the /EMERGOFF line of the boardto-board-connector to ground = immediate shutdown of supply voltages, only applicable if the software controlled procedure fails! See Chapter 3.3.2.2. Automatic shutdown: See Chapter 3.3.3 a) Takes effect if undervoltage is detected. b) Takes effect if MC55/56 board temperature exceeds critical limit. 3.3.2.1 Turn off MC55/56 using AT command The best and safest approach to powering down MC55/56 is to issue the AT^SMSO command. This procedure lets MC55/56 log off from the network and allows the software to enter into a secure state and safe data before disconnecting the power supply. The mode is referred to as POWER DOWN mode. In this mode, only the RTC stays active. Before switching off the device sends the following response: ^SMSO: MS OFF OK ^SHUTDOWN After sending AT^SMSO do not enter any other AT commands. There are two ways to verify when the module turns off: • Wait for the URC “^SHUTDOWN”. It indicates that data have been stored non-volatile and the module turns off in less than 1 second. • Also, you can monitor the VDD pin. The low state of VDD definitely indicates that the module is switched off. Be sure not to disconnect the operating voltage VBATT+ before the URC “^SHUTDOWN” has been issued and the VDD signal has gone low. Otherwise you run the risk of losing data. While MC55/56 is in POWER DOWN mode the application interface is switched off and must not be fed from any other source. Therefore, your application must be designed to avoid any current flow into any digital pins of the application interface. Note: In POWER DOWN mode, the /EMERGOFF pin, the output pins of the ASC0 interface /RXD0, /CTS0, /DCD0, /DSR0, /RING0 and the output pins of the ASC1 interface /RXD1 and /CTS1 are switched to high impedance state. If this causes the associated input pins of your application to float, you are advised to integrate an additional resistor (100 kΩ – 1 MΩ) at each line. In the case of the /EMERGOFF pin use a pull-down resistor tied to GND. In the case of the serial interface pins you can either connect pull-up resistors to the VDD line, or pull-down resistors to GND. MC55/56_hd_v03.00 Page 32 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.3.2.2 Emergency shutdown using /EMERGOFF pin Caution: Use the /EMERGOFF pin only when, due to serious problems, the software is not responding for more than 5 seconds. Pulling the /EMERGOFF pin causes the loss of all information stored in the volatile memory since power is cut off immediately. Therefore, this procedure is intended only for use in case of emergency, e.g. if MC55/56 fails to shut down properly. The /EMERGOFF signal is available on the board-to-board connector. To control the /EMERGOFF line it is recommended to use an open drain / collector driver. To turn the GSM engine off, the /EMERGOFF line has to be driven to ground for ≥ 3.2s. BATT+ /IGT VDD Internal reset max. 3.2s /EMERGOFF Controlled by MC55/56 software Controlled by external application Figure 6: Deactivating GSM engine by /EMERGOFF signal MC55/56_hd_v03.00 Page 33 of 104 How does it work: • Voltage VBATT+ is permanently applied to the module. • The module is active while the internal reset signal is kept at high level. During operation of MC55/56 the baseband controller generates watchdog pulses at regular intervals. Once the EMERGOFF pin is grounded these watchdog pulses are cut off from the power supply ASIC. The power supply ASIC shuts down the internal supply voltages of MC55/56 after max. 3.2s and the module turns off. Consequently, the output voltage at VDD is switched off. 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.3.3 Automatic shutdown Automatic shutdown takes effect if • the MC55/56 board is exceeding the critical limits of overtemperature undertemperature • the battery is exceeding the critical limits of overtemperature or undertemperature • undervoltage is detected or The automatic shutdown procedure is equivalent to the power-down initiated with the AT^SMSO command, i.e. MC55/56 logs off from the network and the software enters a secure state avoiding loss of data. NOTE: This does not apply if overvoltage conditions or unrecoverable hardware or software errors occur (see below for details). Alert messages transmitted before the device switches off are implemented as Unsolicited Result Codes (URCs). The presentation of these URCs can be enabled or disabled with the two AT commands AT^SBC and AT^SCTM. The URC presentation mode varies with the condition, please see Chapters 3.3.3.1 to 3.3.3.4 for details. For further instructions on AT commands refer to [1]. 3.3.3.1 Temperature dependent shutdown The board temperature is constantly monitored by an internal NTC resistor located on the PCB. The NTC that detects the battery temperature must be part of the battery pack circuit as described in Chapter 3.5. The values detected by either NTC resistor are measured directly on the board or the battery and therefore, are not fully identical with the ambient temperature. Each time the board or battery temperature goes out of range or back to normal, MC55/56 instantly displays an alert (if enabled). • URCs indicating the level "1" or "-1" allow the user to take appropriate precautions, such as protecting the module from exposure to extreme conditions. The presentation of the URCs depends on the settings selected with the AT^SCTM write command: AT^SCTM=1: Presentation of URCs is always enabled. AT^SCTM=0 (default): Presentation of URCs is enabled for 15 seconds time after start-up of MC55/56. After 15 seconds operation, the presentation will be disabled, i.e. no alert messages can be generated. • URCs indicating the level "2" or "-2" are instantly followed by an orderly shutdown. The presentation of these URCs is always enabled, i.e. they will be output even though the factory setting AT^SCTM=0 was never changed. The maximum temperature ratings are stated in Table 25. Refer to Table 6 for the associated URCs. All statements are based on test conditions according to IEC 60068-2-2 (still air). MC55/56_hd_v03.00 Page 34 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Table 6: Temperature dependent behaviour Sending temperature alert (15 s after start-up, otherwise only if URC presentation enabled) ^SCTM_A: 1 Caution: Tamb of battery close to over temperature limit. ^SCTM_B: 1 Caution: Tamb of board close to over temperature limit. ^SCTM_A: -1 Caution: Tamb of battery close to under temperature limit. ^SCTM_B: -1 Caution: Tamb of board close to under temperature limit. ^SCTM_A: 0 Battery back to uncritical temperature range. ^SCTM_B: 0 Board back to uncritical temperature range. Automatic shutdown (URC appears no matter whether or not presentation was enabled) ^SCTM_A: 2 Alert: Tamb of battery equal or beyond over temperature limit. MC55/56 switches off. ^SCTM_B: 2 Alert: Tamb of board equal or beyond over temperature limit. MC55/56 switches off. ^SCTM_A: -2 Alert: Tamb of battery equal or below under temperature limit. MC55/56 switches off. ^SCTM_B: -2 Alert: Tamb of board equal or below under temperature limit. MC55/56 switches off. 3.3.3.2 Temperature control during emergency call If the temperature limit is exceeded while an emergency call is in progress the engine continues to measure the temperature, but deactivates the shutdown functionality. If the temperature is still out of range when the call ends, the module switches off immediately (without another alert message). 3.3.3.3 Undervoltage shutdown if battery NTC is present In applications where the module’s charging technique is used and an NTC is connected to the BATT_TEMP terminal, the software constantly monitors the applied voltage. If the measured battery voltage is no more sufficient to set up a call the following URC will be presented: ^SBC: Undervoltage. The message will be reported, for example, when you attempt to make a call while the voltage is close to the critical limit and further power loss is caused during the transmit burst. To remind you that the battery needs to be charged soon, the URC appears several times before the module switches off. To enable or disable the URC use the AT^SBC command. The URC will be enabled when you enter the write command and specify the power consumption of your GSM application. Step by step instructions are provided in [1]. MC55/56_hd_v03.00 Page 35 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.3.3.4 Undervoltage shutdown if no battery NTC is present The undervoltage protection is also effective in applications, where no NTC connects to the BATT_TEMP terminal. Thus, you can take advantage of this feature even though the application handles the charging process or MC55/56 is fed by a fixed supply voltage. All you need to do is executing the write command AT^SBC=which automatically enables the presentation of URCs. You do not need to specify . Whenever the supply voltage falls below the specified value (see Table 27) the URC ^SBC: Undervoltage appears several times before the module switches off. 3.3.3.5 Overvoltage shutdown For overvoltage conditions, no software controlled shutdown is implemented. If the supply voltage exceeds the maximum value specified in Table 27, loss of data and even unrecoverable hardware damage can occur. Keep in mind that several MC55/56 components are directly linked to BATT+ and, therefore, the supply voltage remains applied at major parts of MC55/56. Especially the power amplifier is very sensitive to high voltage and might even be destroyed. MC55/56_hd_v03.00 Page 36 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.4 Automatic GPRS Multislot Class change Temperature control is also effective for operation in GPRS Multislot Class 10. If the board temperature increases to the limit specified for restricted operation1) while data are transmitted over GPRS, the module automatically reverts from GPRS Multislot Class 10 (2 Tx) to Class 8 (1Tx). This reduces the power consumption and, consequently, causes the board’s temperature to decrease. Once the temperature drops to a value of 5 degrees below the limit of restricted operation, MC55/56 returns to the higher Multislot Class. If the temperature stays at the critical level or even continues to rise, MC55/56 will not switch back to the higher class. After a transition from Multislot Class 10 to Multislot 8 a possible switchback to Multislot Class 10 is blocked for one minute. Please note that there is not one single cause of switching over to a lower GPRS Multislot Class. Rather it is the result of an interaction of several factors, such as the board temperature that depends largely on the ambient temperature, the operating mode and the transmit power. Furthermore, take into account that there is a delay until the network proceeds to a lower or, accordingly, higher Multislot Class. The delay time is network dependent. In extreme cases, if it takes too much time for the network and the temperature cannot drop due to this delay, the module may even switch off as described in chapter 3.3.3.1. 1) See Table 25 for temperature limits known as restricted operation. MC55/56_hd_v03.00 Page 37 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.5 Charging control MC55/56 integrates a charging management for Li-Ion batteries. You can skip this chapter if charging is not your concern, or if you are not using the implemented charging algorithm. MC55/56 has no on-board charging circuit. To benefit from the implemented charging management you are required to install a charging circuit within your application. In this case, MC55/56 needs to be powered from a Li-Ion battery pack, e.g. as specified in Table 8. The module only delivers, via its POWER line and CHARGE line, the control signals needed to start and stop the charging process. The charging circuit should include a transistor and should be designed as illustrated in Figure 7. A list of parts recommended for the external circuit is given in Table 7. to POWER Input from charger (5.5V - 8V) under load 1SS355 470R to BATT+ 4V3 Battery pack PCB spark gap /5 ESDA6V1-5W6 CRS04 SI3441DV NTC 100nF 10k 3k3 BATT_TEMP /5 ESDA6V1-5W6 CHARGE Figure 7: Schematic of approved charging transistor, trickle charging and ESD protection Table 7: Bill of material for external charging circuit Part Description SI3441DV p-chan 2.5V (G-S) MOSFET VISHAY: SI3441DV-T1 (TSOP-6) NEC: 1SS355 100mA Si-diode (UMD2) ROHM: Toshiba: 1SS352TPH3 CRS04 1A Schottky diode Toshiba: CRS04 4V3 250mW; 200mA; 4.3V Z-Diode (SOD323) Philips: ESDA6V1-5W6 ESD protection TRANSIL™ STM: array 470R, 3k3, 10k Resistor, e.g. 0805 or 0603 100nF Ceramic capacitor 50V PCB spark gap 0.2mm spark gap on PCB MC55/56_hd_v03.00 First supplier Page 38 of 104 1SS355TE-18 PDZ4.3B ESDA6V1-5W6 Second supplier UPA1911TE-T1 ROHM: UDZS4.3B UDZ4.3B 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.5.1 Battery pack characteristics The charging algorithm has been optimised for a Li-Ion battery pack that meets the characteristics listed below and in Table 8. It is recommended that the battery pack you want to integrate into your MC55/56 application is compliant with these specifications. This ensures reliable operation, proper charging and, particularly, allows you to monitor the battery capacity using the AT^SBC command (see [1] for details). Failure to comply with these specifications might cause AT^SBC to deliver incorrect battery capacity values. • • • • • • • Li-Ion battery pack specified for a maximum charging voltage of 4.2V and a capacity of 800mAh. Battery packs with a capacity down to 600mAh or more than 800mAh are allowed, too. Since charging and discharging largely depend on the battery temperature, the battery pack should include an NTC resistor. If the NTC is not inside the battery it must be in thermal contact with the battery. The NTC resistor must be connected between BATT_TEMP and GND. Required NTC characteristics are: 10kΩ +5% @ 25°C, B25/85 = 3435K +3% (alternatively acceptable: 10kΩ +2% @ 25°C, B25/50 = 3370K +3%). Please note that the NTC is indispensable for proper charging, i.e. the charging process will not start if no NTC is present. Ensure that the pack incorporates a protection circuit capable of detecting overvoltage (protection against overcharging), undervoltage (protection against deep discharging) and overcurrent. The circuit must be insensitive to pulsed current. On the MC55/56 module, a built-in measuring circuit constantly monitors the supply voltage. In the event of undervoltage, it causes MC55/56 to power down. Undervoltage thresholds are specific to the battery pack and must be evaluated for the intended model. When you evaluate undervoltage thresholds, consider both the current consumption of MC55/56 and of the application circuit. The internal resistance of the battery and the protection should be as low as possible. It is recommended not to exceed 150mΩ, even in extreme conditions at low temperature. The battery cell must be insensitive to rupture, fire and gassing under extreme conditions of temperature and charging (voltage, current). The battery pack must be protected from reverse pole connection. For example, the casing should be designed to prevent the user from mounting the battery in reverse orientation. The battery pack must be approved to satisfy the requirements of CE conformity. Figure 8 shows the circuit diagram of a typical to BATT+ battery pack design that includes the protection elements described above. to BATT_TEMP to GND ϑ NTC Protection Circuit + Battery cell Figure 8: Battery pack circuit diagram MC55/56_hd_v03.00 Page 39 of 104 Polyfuse 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Table 8: Specifications of recommended battery pack Battery type Li-Ion, 3.6V Nominal voltage 3.6V Capacity 800mAh NTC 10kΩ ± 5% @ 25°C, B (25/85)=3435K ± 3% Overcharge detection voltage 4.325 ± 0.025V Overcharge release voltage 4.075 ± 0.025V Overdischarge detection voltage 2.5 ± 0.05V Overdischarge release voltage 2.9 ± 0.5V Overcurrent detection 3 ± 0.5A Nominal working current <5µA Current of low voltage detection 0.5µA Overcurrent detection delay time 8~16ms Short detection delay time 50µs Overdischarge detection delay time 31~125ms Overcharge detection delay time 1s Internal resistance <130mΩ MC55/56_hd_v03.00 Page 40 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.5.2 Implemented charging technique If the external charging circuit follows the recommendation of Figure 7, the charging process consists of trickle charging and processor controlled fast charging. For this solution, the fast charging current provided by the charger or any other external source must be limited to 500mA. Trickle charging • Trickle charging starts when the charger is connected to the charger input of the external charging circuit and the module’s POWER pin. The charging current depends on the voltage difference between the charger input of the external charging circuit and BATT+ of the module. • Trickle charging stops when the battery voltage reaches 3.6V. Fast charging • After trickle charging has raised the battery voltage to 3.2V within 60 minutes +10% from connecting the charger, the power ASIC turns on and wakes up the baseband processor. Now, processor controlled fast charging begins. However, if the battery was deeply discharged (below 2.2V) the power ASIC does not wake up the baseband processor and fast charging does not begin after the battery voltage has reached 3.2V. In this case, disconnect and reconnect the charger once after the battery voltage has risen above 2.2V. If the battery voltage was already above 3.2V, processor controlled fast charging starts just after the charger was connected to the charger input of the external charging circuit and the module’s POWER pin. If MC55/56 was in POWER DOWN mode, it turns on and enters the Charge-only mode along with fast charging (see also Chapter 3.3.1.3). • Fast charging delivers a constant current until the battery voltage reaches 4.2V and then proceeds with varying charge pulses. As shown in Figure 5, the pulse duty cycle is reduced to adjust the charging procedure and prevent the voltage from overshooting beyond 4.2V. Once the pulse width reaches the minimum of 100ms and the duty cycle does not change for 2 minutes, fast charging is completed. • Fast charging can only be accomplished in a temperature range from 0°C to +45°C. Voltage 4.3 4.2 3.8 3.4 100ms 2 ... 0.1s 100ms 0.1 ... 2s 3.0 Constant current tOFF = 100 ms tON = 100 ms Time Figure 9: Charging process MC55/56_hd_v03.00 Page 41 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Note: Do not connect the charger to the BATT+ lines. Only the charger input of the external charging circuit is intended as input for charging current! The POWER pin of MC55/56 is the input only for indicating a connected charger! The battery manufacturer must guarantee that the battery complies with the described charging technique. What to do if software controlled charging does not start up? If trickle charging fails to raise the battery voltage to 3.2V within 60 minutes +10%, processor controlled charging does not begin. To start fast charging you can do one of the following: • Once the voltage has risen above its minimum of 3V, you can try to start software controlled charging by pulling the /IGT line to ground. • If the voltage is still below 3V, driving the /IGT line to ground switches the timer off. Without the timer running, MC55/56 will not proceed to software controlled charging. To restart the timer you are required to shortly disconnect and reconnect the charger. 3.5.3 Operating modes during charging Of course, the battery can be charged regardless of the engine's operating mode. When the GSM engine is in Normal mode (SLEEP, IDLE, TALK, GPRS IDLE or GPRS DATA mode), it remains operational while charging is in progress (provided that sufficient voltage is applied). The charging process during the Normal mode is referred to as Charge mode. If the charger is connected to the charger input of the external charging circuit and the module’s POWER pin while MC55/56 is in POWER DOWN mode, MC55/56 goes into Charge-only mode. Table 9: Comparison Charge-only and Charge mode Charge-only mode Charge mode How to activate mode Features Connect charger to charger input of • Battery can be charged while GSM engine external charging circuit and module’s remains operational and registered to the POWER pin while MC55/56 is GSM network. • operating, e.g. in IDLE or TALK mode • In IDLE and TALK mode, the serial interfaces are accessible. AT command set can be used • in SLEEP mode to full extent. • In the NON-CYCLIC SLEEP mode, the serial interfaces are not accessible at all. During the CYCLIC SLEEP mode it can be used as described in Chapter 3.6.3. Connect charger to charger input of • Battery can be charged while GSM engine is external charging circuit and module’s deregistered from GSM network. POWER pin while MC55/56 is • Charging runs smoothly due to constant current consumption. • in POWER DOWN mode • in Normal mode: Connect charger to • The AT interface is accessible and allows to use the commands listed below. the POWER pin, then enter AT^SMSO. IMPORTANT: While trickle charging is in progress, be sure that the application is switched off. If the application is fed from the trickle charge current the module might be prevented from proceeding to software controlled charging since the current would not be sufficient. MC55/56_hd_v03.00 Page 42 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Features of Charge-only mode Once the GSM engine enters the Charge-only mode, the AT command interface presents an Unsolicited Result Code (URC) which reads: ^SYSSTART CHARGE-ONLY MODE Note that this URC will not appear when autobauding was activated (due to the missing synchronization between DTE and DCE upon start-up). Therefore, it is recommended to select a fixed baud rate before using the Charge-only mode. While the Charge-only mode is in progress, you can only use the AT commands listed in Table 10. For further instructions refer to the AT Command Set supplied with your GSM engine. Table 10: AT commands available in Charge-only mode AT command Use AT+CALA Set alarm time AT+CCLK Set date and time of RTC AT^SBC Monitor charging process AT^SCTM AT^SMSO Note: While charging is in progress, no battery capacity value is available. To query the battery capacity disconnect the charger. If the charger connects externally to the host device no charging parameters are transferred to the module. In this case, the command cannot be used. Query temperature range, enable/disable URCs to report critical temperature ranges Power down GSM engine To proceed from Charge-only mode to normal operation, it is necessary to drive the ignition line to ground. This must be implemented in your host application as described in Chapter 3.3.1.1. See also Chapter 3.7 which summarizes the various options of changing the mode of operation. If your host application uses the SYNC pin to control a status LED as described in Chapter 3.12.2.2, please note that the LED is off while the GSM engine is in Charge-only mode. 3.5.4 Charger requirements If you are using the implemented charging technique and the charging circuit recommended in Figure 7, the charger must be designed to meet the following requirements: a) Simple transformer power plug - Output voltage: 5.5V...8V (under load) - The charge current must be limited to 500mA - Voltage spikes that may occur while you connect or disconnect the charger must be limited. - There must not be any capacitor on the secondary side of the power plug (avoidance of current spikes at the beginning of charging) b) Supplementary requirements for a) to ensure a regulated power supply - When current is switched off a voltage peak of 10V is allowed for a maximum 1ms - When current is switched on a spike of 1.6A for 1ms is allowed MC55/56_hd_v03.00 Page 43 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.6 Power saving SLEEP mode reduces the functionality of the MC55/56 module to a minimum and, thus, minimizes the current consumption to the lowest level. Settings can be made using the AT+CFUN command. For details see below and [1]. SLEEP mode falls into two categories: • NON-CYCLIC SLEEP mode AT+CFUN=0 • CYCLIC SLEEP modes, selectable with AT+CFUN=5, 6, 7, 8 or 9. IMPORTANT: Please keep in mind that power saving works properly only when PIN authentication has been done. If you attempt to activate power saving while the SIM card is not inserted or the PIN not correctly entered (Limited Service), the selected level will be set, though power saving does not take effect. For the same reason, power saving cannot be used if MC55/56 operates in Alarm mode. To check whether power saving is on, you can query the status of AT+CFUN if you have chosen CYCLIC SLEEP mode. If available, you can take advantage of the status LED controlled by the SYNC pin (see Chapter 3.12.2.2). The LED is off in all SLEEP modes when no activity occurs, but resumes flashing to indicate temporary wake-up states during CYLCIC SLEEP modes. The LED patterns are shown in Table 18. The wake-up procedures are quite different depending on the selected SLEEP mode. Table 11 compares the wake-up events that can occur in NON-CYCLIC and CYCLIC SLEEP modes. 3.6.1 No power saving (AT+CFUN=1) The functionality level =1 is where power saving is switched off. This is the default after startup. 3.6.2 NON-CYCLIC SLEEP mode (AT+CFUN=0) If level 0 has been selected (AT+CFUN=0), the serial interface is blocked. The module shortly deactivates power saving to listen to a paging message sent from the base station and then immediately resumes power saving. Level 0 is called NON-CYCLIC SLEEP mode, since the serial interface is not alternatingly made accessible as in CYCLIC SLEEP mode. The first wake-up event fully activates the module, enables the serial interface and terminates the power saving mode. In short, it takes MC55/56 back to the highest level of functionality =1. In NON-CYCLIC mode, the falling edge of the /RTS0 or /RTS1 lines wakes up the module to =1. To efficiently use this feature it is recommended to enable hardware flow control (RTS/CTS handshake) as in this case the CTS line notifies the application when the module is ready to send or receive characters. See section 3.6.6.1 for details. MC55/56_hd_v03.00 Page 44 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.6.3 CYCLIC SLEEP mode (AT+CFUN=5, 6, 7, 8) The major benefit over the NON-CYCLIC SLEEP mode is that the serial interface is not permanently blocked and that packet switched calls may go on without terminating the selected CYCLIC SLEEP mode. This allows MC55/56 to become active, for example to perform a GPRS data transfer, and to resume power saving after the GPRS data transfer is completed. The CYCLIC SLEEP modes give you greater flexibility regarding the wake-up procedures: For example, in all CYCLIC SLEEP modes, you can enter AT+CFUN=1 to permanently wake up the module. In modes CFUN=7 and 8, MC55/56 automatically resumes power saving, after you have sent or received a short message or made a call. CFUN=5 and 6 do not offer this feature, and therefore, are only supported for compatibility with earlier releases. Please refer to Table 11 for a summary of all modes. The CYCLIC SLEEP mode is a dynamic process which alternatingly enables and disables the serial interface. By setting/resetting the /CTS signal, the module indicates to the application whether or not the UART is active. The timing of /CTS is described below. Both the application and the module must be configured to use hardware flow control (RTS/CTS handshake). The default setting of MC55/56 is AT\Q0 (no flow control) which must be altered to AT\Q3. See [1] for details. Note: If both serial interfaces ASC0 and ASC1 are connected, both are synchronized. This means that SLEEP mode takes effect on both, no matter on which interface the AT command was issued. Although not explicitly stated, all explanations given in this chapter refer equally to ASC0 and ASC1, and accordingly to /CTS0 and /CTS1. 3.6.4 CYCLIC SLEEP mode AT+CFUN=9 Mode AT+CFUN=9 is similar to AT+CFUN=7 or 8, but provides two additional features: • The time the module stays active after RTS was asserted or after the last character was sent or received, can be configured individually using the command AT^SCFG. Default setting is 2 seconds like in AT+CFUN=7. The entire range is from 0.5 seconds to 1 hour, selectable in tenths of seconds. For details see [1]. • /RTS0 and /RTS1 are not only used for flow control (as in modes AT+CFUN=5, 6, 7 or 8), but also cause the module to wake up temporarily. See section 3.6.6.1 for details. 3.6.5 Timing of the /CTS signal in CYCLIC SLEEP modes The /CTS signal is enabled in synchrony with the module’s paging cycle. It goes active low each time when the module starts listening to a paging message block from the base station. The timing of the paging cycle varies with the base station. The duration of a paging interval can be calculated from the following formula: 4.615 ms (TDMA frame duration) * 51 (number of frames) * DRX value. DRX (Discontinuous Reception) is a value from 2 to 9, resulting in paging intervals from 0.47 to 2.12 seconds. The DRX value of the base station is assigned by the network operator. Each listening period causes the /CTS signal to go active low: If DRX is 2, the /CTS signal is activated every 0.47 seconds, if DRX is 3, the /CTS signal is activated every 0.71 seconds and if DRX is 9, the /CTS signal is activated every 2.1 seconds. MC55/56_hd_v03.00 Page 45 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary The /CTS signal is active low for 4.6 ms. This is followed by another 4.6 ms UART activity. If the start bit of a received character is detected within these 9.2 ms, /CTS will be activated and the proper reception of the character will be guaranteed. /CTS will also be activated if any character is to be sent. After the last character was sent or received the interface will remain active for • another 2 seconds, if AT+CFUN=5 or 7, • another 10 minutes, if AT+CFUN=6 or 8, • or for an individual time defined with AT^SCFG, if AT+CFUN=9. Assertion of RTS has the same effect. In the pauses between listening to paging messages, while /CTS is high, the module resumes power saving and the AT interface is not accessible. See Figure 10 and Figure 11. Paging message Paging message 2.12 s /CTS Paging message 4.6 ms 4.6 ms 4.6 ms 4.6 ms 4.6 ms 4.6 ms AT interface disabled Paging message 2.12 s 2.12 s 4.6 ms 4.6 ms AT interface enabled Figure 10: Timing of /CTS signal (example for a 2.12 s paging cycle) Figure 11 illustrates the CFUN=5 and CFUN=7 modes, which reset the /CTS signal 2 seconds after the last character was sent or received. Paging message 2.12 s Paging message 2.12 s Paging message 2.12 s Paging message Beginning of power saving 4.6 ms /CTS 2s 1st character 4.6 ms 4.6 ms 4.6 ms 4.6 ms Last character AT interface disabled AT interface enabled Figure 11: Beginning of power saving if CFUN=5 or 7 MC55/56_hd_v03.00 Page 46 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.6.6 Wake up MC55/56 from SLEEP mode A wake-up event is any event that causes the module to draw current. Depending on the selected mode the wake-up event either switches SLEEP mode off and takes MC55/56 back to AT+CFUN=1, or activates MC55/56 temporarily without leaving the current SLEEP mode. Definitions of the state transitions described in Table 11: Quit = MC55/56 exits SLEEP mode and returns to AT+CFUN=1. Temporary = MC55/56 becomes active temporarily for the duration of the event and the mode-specific follow-up time after the last character was sent or received on the serial interface. No effect: = Event is not relevant in the selected SLEEP mode. MC55/56 does not wake up. Table 11: Wake-up events in NON-CYCLIC and CYCLIC SLEEP modes Event Ignition line /RTS0 or /RTS1 (falling edge) 1) Selected mode AT+CFUN=0 Selected mode AT+CFUN=5 or 6 Selected mode AT+CFUN=7, 8, 9 No effect No effect No effect Quit + flow control No effect, RTS is only Mode 7 and 8: No used for flow control effect, RTS is only used for flow control Mode 9: Temporary + flow control Unsolicited Result Code (URC) Quit Quit Temporary Incoming voice or data call Quit Quit Temporary Any AT command (incl. outgoing voice or data call, outgoing SMS) Not possible (UART disabled) Temporary Temporary AT+CNMI=0,0 (= default, no indication of received SMS) No effect No effect No effect AT+CNMI=1,1 (= displays URC upon receipt of SMS) Quit Quit Temporary GPRS data transfer Not possible (UART disabled) Temporary Temporary RTC alarm2) Quit Quit Temporary AT+CFUN=1 Not possible (UART disabled) Quit Quit Incoming SMS depending on mode selected by AT+CNMI: 1) 2) See section 3.6.6.1 on wake-up via RTS. Recommendation: In NON-CYCLIC SLEEP mode, you can set an RTC alarm to wake up MC55/56 and return to full functionality. This is a useful approach because, in this mode, the AT interface is not accessible. MC55/56_hd_v03.00 Page 47 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.6.6.1 Wake-up via /RTS0 and RTS1 (if AT+CFUN=0 or AT+CFUN=9) During the CYCLIC SLEEP modes 5, 6, 7, and 8, the /RTS0 and /RTS1 lines are conventionally used for flow control: The assertion of /RTS0 or /RTS1 indicates that the application is ready to receive data - without waking up the module. If the module is in CFUN=0 mode the assertion of /RTS0 and /RTS1 serves as a wake-up event, giving the application the possibility to intentionally terminate power saving. If the module is in CFUN=9 mode, the assertion of /RTS0 or /RTS1 can be used to temporarily wake up MC55/56 for the time specified with the AT^SCFG command (default = 2s). In both cases, if /RTS0 or /RTS1 is asserted while AT+CFUN=0 or AT+CFUN=9 is set, there may be a short delay until the module is able to receive data again. This delay depends on the current module activities (e.g. paging cycle) and may be up to 60ms. The ability to receive data is signalized by /CTS0 and /CTS1. It is therefore recommended to enable RTS/CTS flow control, not only in CYCLIC SLEEP mode, but also in NON-CYCLIC SLEEP mode. MC55/56_hd_v03.00 Page 48 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.7 Summary of state transitions (except SLEEP mode) Table 12: State transitions of MC55/56 (except SLEEP mode) The table shows how to proceed from one mode to another (grey column = present mode, white columns = intended modes) Normal mode**) Charge-only mode*) Charging in normal mode*)**) Alarm mode POWER DOWN --mode without charger /IGT >100 ms at low level Connect charger to input of ext. charging circuit and POWER pin (high level at POWER) No direct transition, but via “Charge-only mode” or “Normal mode” Wake-up from POWER DOWN mode (if activated with AT+CALA) POWER DOWN --mode with charger (high level at POWER pins of MC55/56) /IGT >1 s at low level, if battery is fully charged 100ms < /IGT < 500ms at low level /IGT >1 s at low level Wake-up from POWER DOWN mode (if activated with AT+CALA) Further mode ÎÎÎ POWER DOWN Present mode Normal mode**) AT^SMSO --or exceptionally /EMERGOFF pin > 3.2s at low level No automatic transition, Connect charger to but via “POWER POWER pin at MC55/56 DOWN” (high level at POWER) AT+CALA followed by AT^SMSO. MC55/56 enters Alarm mode when specified time is reached. Charge-only mode *) Disconnect charger (MC55/56 POWER pin at low level) or AT^SMSO or exceptionally /EMERGOFF pin >3.2s at low level No automatic transition, but via “Charge in Normal mode” --- /IGT >1s at low level AT+CALA followed by AT^SMSO. MC55/56 enters Alarm mode when specified time is reached and VBATT+>3.2V Charging in normal mode*) **) AT^SMSO Î “Chargeonly mode”, again AT^SMSO; or exceptionally /EMERGOFF pin >3.2s at low level Disconnect charger from input of ext. charging circuit and module’s POWER pin AT^SMSO --- No direct transition Alarm mode AT^SMSO or /IGT >100ms at low exceptionally /EMERGOFF level pin >3.2s at low level AT^SMSO if charger is connected /IGT >100ms at low level --- *) See Chapter 3.5.3 for details on the charging mode MC55/56_hd_v03.00 **) Normal mode covers TALK, DATA, GPRS, IDLE and SLEEP modes Page 49 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.8 RTC backup The internal Real Time Clock of MC55/56 is supplied from a separate voltage regulator in the power supply ASIC which is also active when MC55/56 is in POWER DOWN status. An alarm function is provided that allows to wake up MC55/56 without logging on to the GSM network. In addition, you can use the VDDLP pin on the board-to-board connector to backup the RTC from an external capacitor or a battery (rechargeable or non-chargeable). The capacitor is charged by the BATT+ line of MC55/56. If the voltage supply at BATT+ is disconnected the RTC can be powered by the capacitor. The size of the capacitor determines the duration of buffering when no voltage is applied to MC55/56, i.e. the greater capacitor the longer MC55/56 will save the date and time. The following figures show various sample configurations. The voltage applied at VDDLP can be in the range from 2 to 5.5V. Please refer to Table 26 for the parameters required. BATT+ Baseband processor B2B PSU 1k RTC VDDLP Figure 12: RTC supply from capacitor BATT+ Baseband processor B2B PSU 1k RTC VDDLP Figure 13: RTC supply from rechargeable battery BATT+ Baseband processor B2B PSU 1k RTC VDDLP Figure 14: RTC supply from non-chargeable battery MC55/56_hd_v03.00 Page 50 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.9 Serial interfaces MC55/56 offers two unbalanced, asynchronous serial interfaces conforming to ITU-T V.24 protocol DCE signalling. The electrical characteristics do not comply with ITU-T V.28. The significant levels are 0V (for low data bit or ON condition) and 2.65V (for high data bit or OFF condition). For electrical characteristics please refer to Table 26. The GSM engine is designed for use as a DCE. Based on the conventions for DCE-DTE connections it communicates with the customer application (DTE) using the following signals: ASC0 • Port /TXD @ application sends data to the module’s /TXD0 signal line • Port /RXD @ application receives data from the module’s /RXD0 signal line ASC1 • Port /TXD @ application sends data to module’s /TXD1 signal line • Port /RXD @ application receives data from the module’s /RXD1 signal line GSM module Application /TXD /RXD0 /RXD /RTS0 /RTS /CTS0 /CTS /DTR0 /DTR /DSR0 /DSR /DCD0 /DCD /RING0 /RING /TXD1 /TXD /RXD1 /RXD /RTS1 /RTS /CTS1 /CTS 2nd serial interface ASC0 interface ASC1 interface /TXD0 1st serial interface (DTE) (DCE) Figure 15: Serial interfaces MC55/56_hd_v03.00 Page 51 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.9.1 Features supported on first and second serial interface ASC0 • 8-wire serial interface • Includes the data lines /TXD0 and /RXD0, the status lines /RTS0 and /CTS0 and, in addition, the modem control lines /DTR0, /DSR0, /DCD0 and /RING0. • It is primarily designed for voice calls, CSD calls, fax calls and GPRS services and for controlling the GSM engine with AT commands. Full Multiplex capability allows the interface to be partitioned into three virtual channels, yet with CSD and fax services only available on the first logical channel. Please note that when the ASC0 interface runs in Multiplex mode, ASC1 cannot be used. For more detailed characteristics see [11]. • The /DTR0 signal will only be polled once per second from the internal firmware of MC55/56. • The /RING0 signal serves to indicate incoming calls and other types of URCs (Unsolicited Result Code). It can also be used to send pulses to the host application, for example to wake up the application from power saving state. For further details see Chapter 3.12.2.3. • Autobauding is only selectable on ASC0 and supports the following bit rates: 1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200, 230400 bps. • Autobauding is not compatible with multiplex mode, see [11]. ASC1 • 4-wire serial interface • Includes only the data lines /TXD1 and /RXD1 plus /RTS1 and /CTS1 for hardware handshake. This interface is intended for voice calls, GPRS services and for controlling the GSM engine with AT commands. It is not suited for CSD calls, fax calls and Multiplex mode. • On ASC1 no RING line is available. The indication of URCs on the second interface depends on the settings made with the AT^SCFG command. For details refer to [1]. ASC0 and ASC1 • Both interfaces are configured for 8 data bits, no parity and 1 stop bit, and can be operated at bit rates from 300bps to 230400 bps. • XON/XOFF software flow control can be used on both interfaces (except if power saving is active). Table 13: DCE-DTE wiring of 1st serial interface V.24 circuit DCE DTE Pin function Signal direction Pin function Signal direction 103 /TXD0 Input /TXD Output 104 /RXD0 Output /RXD Input 105 /RTS0 Input /RTS Output 106 /CTS0 Output /CTS Input 108/2 /DTR0 Input /DTR Output 107 /DSR0 Output /DSR Input 109 /DCD0 Output /DCD Input 125 /RING0 Output /RING Input MC55/56_hd_v03.00 Page 52 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Table 14: DCE-DTE wiring of 2nd serial interface V.24 circuit DCE DTE Pin function Signal direction Pin function Signal direction 103 /TXD1 Input /TXD Output 104 /RXD1 Output /RXD Input 105 /RTS1 Input /RTS Output 106 /CTS1 Output /CTS Input MC55/56_hd_v03.00 Page 53 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.10 Audio interfaces MC55/56 comprises three audio interfaces available on the board-to-board connector: • Two analog audio interfaces, each with a balanced analog microphone input and a balanced analog earpiece output. The second analog interface provides a supply circuit to feed an active microphone. • Serial digital audio interface (DAI) using PCM (Pulse Code Modulation) to encode analog voice signals into digital bit streams. This means you can connect up to three audio devices in any combination, although analog and digital audio cannot be operated at the same time. Using the AT^SAIC command you can easily switch back and forth. MICP1 MICN1 MICP2 ADC MICN2 EPP1 EPN1 DAC EPP2 DSP Air Interface EPN2 SCLK RXDDAI RFSDAI TXDDAI TFSDAI Digital Audio Interface (DAI) Figure 16: Audio block diagram MC55/56 offers six audio modes which can be selected with the AT^SNFS command, no matter which of the three interfaces is currently active. The electrical characteristics of the voiceband part vary with the audio mode. For example, sending and receiving amplification, sidetone paths, noise suppression etc. depend on the selected mode and can be altered with AT commands (except for mode 1). On each audio interface you can use all audio AT commands specified in [1] to alter parameters. The only exception are the DAC and ADC gain amplifier attenuation and which cannot be modified when the digital audio interface is used, since in this case the DAC and ADC are switched off. Please refer to Chapter 3.10 for specifications of the audio interface and an overview of the audio parameters. Detailed instructions on using AT commands are presented in [1]. Table 29 on page 87 summarizes the characteristics of the various audio modes and shows what parameters are supported in each mode. MC55/56_hd_v03.00 Page 54 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary When shipped from factory, all audio parameters of MC55/56 are set to interface 1 and audio mode 1. This is the default configuration optimised for the Votronic HH-SI-30.3/V1.1/0 handset and used for type approving the Siemens reference configuration. Audio mode 1 has fix parameters which cannot be modified. To adjust the settings of the Votronic handset simply change to another audio mode. In transmit direction, all audio modes contain internal scaling factors (digital amplification) that are not accessible by the user. To avoid saturation with a full scale digital input signal on the DAI, and to obtain a one-to-one digital access to the speech coder in audio mode 5 and 6, it is recommended to set the parameter of the selected audio mode as follows: Audio mode 1 and 4: 23196 Audio mode 2: 17396 Audio mode 3: 21901 Audio mode 5 and 6: 21402 3.10.1 Microphone circuit Interface 1 This interface has no microphone supply circuit and therefore, has an impedance of 50kΩ. When connecting a microphone or another signal source to interface 1 you are required to add two 100 nF capacitors, one to each line. Interface 2 This interface comes with a microphone supply circuit and can be used to feed an active microphone. It has an impedance of 2kΩ. If you do not use it or if you want to connect another type of signal source, for example, an op amp or a dynamic microphone, it needs to be decoupled with capacitors. The power supply can be switched off and on by using the command AT^SNFM. For details see [1]. Figure 17 shows the microphone inputs at both analog interfaces of MC55/56. 2.65 V Power down MICP1 MICN1 Ri=50kΩ to ADC 1 kΩ 1 kΩ MICP2 33 µF MICN2 1 kΩ 1 kΩ Ri=2kΩ Figure 17: Schematic of microphone inputs MC55/56_hd_v03.00 Page 55 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.10.2 Speech processing The speech samples from the ADC or DAI are handled by the DSP of the baseband controller to calculate e.g. amplifications, sidetone, echo cancellation or noise suppression depending on the configuration of the active audio mode. These processed samples are passed to the speech encoder. Received samples from the speech decoder are passed to the DAC or DAI after post processing (frequency response correction, adding sidetone etc.). Full rate, half rate, enhanced full rate, adaptive multi rate (AMR), speech and channel encoding including voice activity detection (VAD) and discontinuous transmission (DTX) and digital GMSK modulation are also performed on the GSM baseband processor. Customer specific audio parameters can be evaluated and supplied by Siemens on request. These parameters can be downloaded to MC55/56 using an AT command. For further information refer to [9] or contact your Siemens distributor. 3.10.3 DAI timing To support the DAI function, MC55/56 integrates a simple five-line serial interface with one input data clock line (SCLK) and input / output data and frame lines (TXDDAI, TFSDAI, RXDDAI, RFSDAI). The serial interface is always active if the external input data clock SLCK is present, i.e. the serial interface is not clocked by the DSP of the MC55/56 baseband processor. SLCK must be supplied from the application and can be in a frequency range between 0.2 and 10 MHz. Serial transfer of 16-bit words is done in both directions. Data transfer to the application is initiated by the module via a short pulse of TFSDAI. The duration of the TFSDAI pulse is one SCLK period, starting at the rising edge of SLCK. During the following 16 SLCK cycles, the 16-bit sample will be transferred on the TXDDAI line. The next outgoing sample will be transferred after the next TFSDAI pulse which occurs every 125 µs. The TFSDAI pulse is the master clock of the sample transfer. From the rising edge of the TFSDAI pulse, the application has 100 µs to transfer the 16-bit input sample on the RXDDAI line. The rising edge of the RFSDAI pulse (supplied by the application) may coincide with the falling edge of TFSDAI or occur slightly later - it is only significant that, in any case, the transfer of the LSB input sample will be completed within the specified duration of 100 µs. Audio samples are transferred from the module to the application in an average of 125µs. This is determined by the 8kHz sampling rate, which is derived from and synchronized to the GSM network. As SLCK is independent of the GSM network, the distance between two succeeding sample transfers may vary about + 1 SLCK period. The application is required to adapt its sampling rate to the TFSDAI rate. Failure to synchronize the timing between the module and the application may cause audible pops and clicks in a conversation. The timing characteristics of both data transfer directions are shown in Figure 18 and Figure 19. MC55/56_hd_v03.00 Page 56 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Note: Before starting the data transfer the clock SCLK should be available for at least three cycles. After the transfer of the LSB0 the clock SCLK should be still available for at least three cycles. SLCK (input) Internal signal T = 100ns to 5,000 ns RFSDAI (input) RXDDAI (input) Flag Figure 18: DAI timing on transmit path SLCK (input) T = 100ns to 5,000 ns Internal signal TFSDAI (output) TXDDAI (output) Flag Figure 19: DAI timing on receive path MC55/56_hd_v03.00 Page 57 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.11 SIM interface The baseband processor has an integrated SIM interface compatible with the ISO 7816 IC Card standard. This is wired to the host interface (board-to-board connector) in order to be connected to an external SIM card holder. Six pins on the board-to-board connector are reserved for the SIM interface. The CCIN pin serves to detect whether a tray (with SIM card) is present in the card holder. Using the CCIN pin is mandatory for compliance with the GSM 11.11 recommendation if the mechanical design of the host application allows the user to remove the SIM card during operation. See Chapter 3.11.1 for details. Table 15: Signals of the SIM interface (board-to-board connector) Signal Description CCGND Separate ground connection for SIM card to improve EMC. CCCLK Chipcard clock, various clock rates can be set in the baseband processor. CCVCC SIM supply voltage from PSU-ASIC CCIO Serial data line, input and output. CCRST Chipcard reset, provided by baseband processor. CCIN Input on the baseband processor for detecting a SIM card tray in the holder. The CCIN pin is mandatory for applications that allow the user to remove the SIM card during operation. The CCIN pin is solely intended for use with a SIM card. It must not be used for any other purposes. Failure to comply with this requirement may invalidate the type approval of MC55/56. It is recommended that the total cable length between the board-to-board connector pins on MC55/56 and the pins of the SIM card holder does not exceed 200 mm in order to meet the specifications of 3GPP TS 51.010-1 and to satisfy the requirements of EMC compliance. To avoid possible cross-talk from the CCCLK signal to the CCIO signal be careful that both lines are not placed closely next to each other. A useful approach is using the CCGND line to shield the CCIO line from the CCCLK line. MC55/56_hd_v03.00 Page 58 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.11.1 Requirements for using the CCIN pin According to ISO/IEC 7816-3 the SIM interface must be immediately shut down once the SIM card is removed during operation. Therefore, the signal at the CCIN pin must go low before the SIM card contacts are mechanically detached from the SIM interface contacts. This shutdown procedure is particularly required to protect the SIM card as well as the SIM interface of MC55/56 from damage. An appropriate SIM card detect switch is required on the card holder. For example, this is true for the model supplied by Molex, which has been tested to operate with MC55/56 and is part of the Siemens reference equipment submitted for type approval. Molex ordering number is 91228-0001, see also Chapter 9. The module’s startup procedure involves a SIM card initialisation performed within 1 second after getting started. An important issue is whether the initialisation procedure ends up with a high or low level of the CCIN signal: a) If, during startup of MC55/56, the CCIN signal on the SIM interface is high, then the status of the SIM card holder can be recognized each time the card is inserted or ejected. A low level of CCIN indicates that no SIM card tray is inserted into the holder. In this case, the module keeps searching, at regular intervals, for the SIM card. Once the SIM card tray with a SIM card is inserted, CCIN is taken high again. b) If, during startup of MC55/56, the CCIN signal is low, the module will also attempt to initialise the SIM card. In this case, the initialisation will only be successful when the card is present. If the SIM card initialisation has been done, but the card is no more operational or removed, then the module will never search again for a SIM card and only emergency calls can be made. Removing and inserting the SIM card during operation requires the software to be reinitialised. Therefore, after reinserting the SIM card it is necessary to restart MC55/56. It is strongly recommended to connect the contacts of the SIM card detect switch to the CCIN input and to the CCVCC output of the module as illustrated in the sample diagram in Figure 20. Note: No guarantee can be given, nor any liability accepted, if loss of data is encountered after removing the SIM card during operation. Also, no guarantee can be given for properly initialising any SIM card that the user inserts after having removed a SIM card during operation. In this case, the application must restart MC55/56. MC55/56_hd_v03.00 Page 59 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.11.2 Design considerations for SIM card holder The schematic below is a sample configuration that illustrates the Molex SIM card holder located on the DSB45 Support Box (evaluation kit used for type approval of the Siemens MC55/56 reference setup, see [5]). X503 is the designation used for the SIM card holder in [5]. Molex card holder GSM module Figure 20: SIM card holder of DSB45 Support Box Table 16: Pin assignment of Molex SIM card holder on DSB45 Support Box Pin no. Signal name I/O Function CCVCC Supply voltage for SIM card, generated by the GSM engine CCRST Chip card reset, prompted by the GSM engine CCCLK Chip card clock CCGND Individual ground line for the SIM card to improve EMC CCVPP Not connected CCIO I/O Serial data line, bi-directional CCDET1 Connect to CCVCC CCDET2 Connects to the CCIN input of the GSM engine. Serves to recognize whether a SIM card is in the holder. Pins 1 through 8 (except for 5) are the minimum requirement according to the GSM Recommendations, where pins 7 and 8 are needed for SIM card tray detection through the CCIN pin. Figure 21: Pin numbers of Molex SIM card holder on DSB45 Support Box Place the capacitors C1205 and C1206 (or instead one capacitor of 200nF) as close as possible to the pins 1 (CCVCC) and 4 (GND) of the card holder. Connect the capacitors to the pins via low resistance tracks. MC55/56_hd_v03.00 Page 60 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.12 Control signals 3.12.1 Inputs Table 17: Input control signals of the MC55/56 module Signal Pin Pin status Function Remarks Ignition /IGT Falling edge Power up MC55/56 Left open or HiZ No operation Active low ≥ 100ms (Open drain/collector driver to GND required in cellular device application). Note: If a charger and a battery is connected to the customer application the /IGT signal must be 1s minimum. Emergency shutdown /EMERGOFF Low Power MC55/56 Left open or HiZ No operation down Active low ≥ 3.2s (Open drain/collector driver required in cellular device application). At the /EMERGOFF signal the watchdog signal of the GSM engine can be traced (see description in Table 26). (HiZ = high impedance) MC55/56_hd_v03.00 Page 61 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.12.2 Outputs 3.12.2.1 Synchronization signal The synchronization signal serves to indicate growing power consumption during the transmit burst. The signal is generated by the SYNC pin. Please note that this pin can adopt two different operating modes which you can select by using the AT^SSYNC command (mode 0 and 1). For details refer to the following chapter and to [1]. To generate the synchronization signal the pin needs to be configured to mode 0 (= default). This setting is recommended if you want your application to use the synchronization signal for better power supply control. Your platform design must be such that the incoming signal accommodates sufficient power supply to the MC55/56 module if required. This can be achieved by lowering the current drawn from other components installed in your application. The timing of the synchronization signal is shown below. High level of the SYNC pin indicates increased power consumption during transmission. 1 Tx 577 µs every 4.616 ms 2 Tx 1154 µs every 4.616 ms Transmit burst SYNC signal*) 300 µs Figure 22: SYNC signal during transmit burst *) The duration of the SYNC signal is always equal, no matter whether the traffic or the access burst are active. MC55/56_hd_v03.00 Page 62 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 3.12.2.2 Using the SYNC pin to control a status LED As an alternative to generating the synchronization signal, the SYNC pin can be used to control a status LED on your application platform. Especially in the development and test phase of an application, system integrators are advised to use the LED mode of the SYNC pin in order to evaluate their product design and identify the source of errors. To avail of this feature you need to set the SYNC pin to mode 1 by using the AT^SSYNC command. For details see [1]. Table 18: Coding of the status LED LED mode Operating status of MC55/56 Permanently off MC55/56 is in one of the following modes: • POWER DOWN mode • ALARM mode • CHARGE-ONLY mode • NON-CYCLIC SLEEP mode • CYCLIC SLEEP mode with no temporary wake-up event in progress. 600 ms on / 600 ms off Limited Network Service: No SIM card inserted or no PIN entered, or network search in progress, or ongoing user authentication, or network login in progress. 75 ms on / 3 s off IDLE mode: The mobile is logged to the network (monitoring control channels and user interactions). No call in progress. 75 ms on / 75 ms off / 75 ms on / 3 s off One or more GPRS contexts activated. 0.5 s on / off depending on Packet switched data transfer in progress. LED goes on within transmission activity 1 second after data packets were exchanged. Flash duration is approximately 0.5 s. 75 ms URC Permanently on Depending on type of call: Voice call: Connected to remote party. CSD call: Connected to remote party or exchange of parameters while setting up or disconnecting a call. LED Off = SYNC pin low. LED On = SYNC pin high (if LED is connected as illustrated in Figure 23) Note: When a temporary wake-up event (URC, call, packet switched transfer) occurs in CYCLIC SLEEP mode the LED flashes. See Table 11 for details on the various SLEEP modes and wake-up events. MC55/56_hd_v03.00 Page 63 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary To operate the LED a buffer, e.g. a transistor or gate, must be included in your application. A sample configuration can be gathered from Figure 23. Power consumption in the LED mode is the same as for the synchronization signal mode. For details see Table 26, SYNC pin. Figure 23: LED Circuit (Example) MC55/56_hd_v03.00 Page 64 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 3.12.2.3 Behavior of the /RING0 line (ASC0 interface only) The /RING0 line is available on the first serial interface (ASC0). The signal serves to indicate incoming calls and other types of URCs (Unsolicited Result Code). Although not mandatory for use in a host application, it is strongly suggested that you connect the /RING0 line to an interrupt line of your application. In this case, the application can be designed to receive an interrupt when a falling edge on /RING0 occurs. This solution is most effective, particularly, for waking up an application from power saving. Note that if the /RING0 line is not wired, the application would be required to permanently poll the data and status lines of the serial interface at the expense of a higher current consumption. Therefore, utilizing the /RING0 line provides an option to significantly reduce the overall current consumption of your application. The behavior of the /RING0 line varies with the type of event: • When a voice/fax/data call comes in the /RING0 line goes low for 1s and high for another 4s. Every 5 seconds the ring string is generated and sent over the /RXD0 line. If there is a call in progress and call waiting is activated for a connected handset or handsfree device, the /RING0 line switches to ground in order to generate acoustic signals that indicate the waiting call. 4s 4s /RING0 1s Ring string 1s Ring string 1s Ring string Figure 24: Incoming voice call • All other types of Unsolicited Result Codes (URCs) also cause the /RING0 line to go low, however for 1 second only. Figure 25: URC transmission /RING0 1s URC Table 19: ASC0 ring signal Function Pin Status Description Ring indication GSM_RING0 Indicates an incoming call or URC. If in NON-CYCLIC SLEEP mode CFUN=0 or CYCLIC SLEEP mode CFUN=5 or 6, the module is caused to wake up to full functionality. If CFUN=7 or 8, power saving is resumed after URC transmission or end of call. No operation MC55/56_hd_v03.00 Page 65 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Antenna interface The RF interface has an impedance of 50Ω. MC55/56 is capable of sustaining a total mismatch at the antenna connector or pad without any damage, even when transmitting at maximum RF power. The external antenna must be matched properly to achieve best performance regarding radiated power, DC-power consumption and harmonic suppression. Matching networks are not included on the MC55/56 PCB and should be placed in the host application. Regarding the return loss MC55/56 provides the following values: Table 20: Return loss State of module Return loss of module Recommended return loss of application Receive > 8dB > 12dB Transmit not applicable > 12dB Idle < 5dB not applicable The connection of the antenna or other equipment must be decoupled from DC voltage. 4.1 Antenna installation To suit the physical design of individual applications MC55/56 offers two alternative approaches to connecting the antenna: • Recommended approach: U.FL-R-SMT antenna connector from Hirose assembled on the component side of the PCB (top view on MC55/56). See Chapter 4.1.2 for details. • Antenna pad and grounding plane placed on the bottom side. See Chapter 4.1.1. Antenna ground Antenna pad Figure 26: U.FL-R-SMT connector Figure 27: Antenna pad and GND plane MC55/56_hd_v03.00 Page 66 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary The U.FL-R-SMT connector has been chosen as antenna reference point (ARP) for the Siemens reference equipment submitted to type approve MC55/56. All RF data specified throughout this manual are related to the ARP. For compliance with the test results of the Siemens type approval you are advised to give priority to the connector, rather than using the antenna pad. IMPORTANT: Both solutions can only be applied alternatively. This means, whenever an antenna is plugged to the Hirose connector, the pad must not be used. Vice versa, if the antenna is connected to the pad, then the Hirose connector must be left empty. Antenna connected to Hirose connector: Module PAD U.FL Antenna connected to pad: Antenna or measurement equipment PAD U.FL 50Ohm 50Ohm 50Ohm Module Antenna or measurement equipment 50Ohm Figure 28: Never use antenna connector and antenna pad at the same time No matter which option you choose, ensure that the antenna pad does not come into contact with the holding device or any other components of the host application. It needs to be surrounded by a restricted area filled with air, which must also be reserved 0.8 mm in height. U.FL antenna connector RF section PCB Antenna pad Restricted area Figure 29: Restricted area around antenna pad MC55/56_hd_v03.00 Page 67 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 4.1.1 Antenna pad The antenna can be soldered to the pad, or attached via contact springs. To help you ground the antenna, MC55/56 comes with a grounding plane located close to the antenna pad. The positions of both pads can be seen from Figure 39. When you decide to use the antenna pad take into account that the pad has not been intended as antenna reference point (ARP) for the Siemens MC55/56 type approval. The antenna pad is provided only as an alternative option which can be used, for example, if the recommended Hirose connection does not fit into your antenna design. Also, consider that according to the GSM recommendations TS 45.005 and TS 51.010-01 a 50Ω connector is mandatory for type approval measurements. This requires GSM devices with an integral antenna to be temporarily equipped with a suitable connector or a low loss RF cable with adapter. To prevent damage to the module and to obtain long-term solder joint properties you are advised to maintain the standards of good engineering practice for soldering. MC55/56 material properties: MC55/56 PCB: FR4 Antenna pad: Gold plated pad 4.1.1.1 Suitable cable types For direct solder attachment, we suggest to use the following cable types: • RG316/U 50 Ohm coaxial cable • 1671A 50 Ohm coaxial cable Suitable cables are offered, for example, by IMS Connector Systems. For further details and other cable types please contact http://www.imscs.com. MC55/56_hd_v03.00 Page 68 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 4.1.2 Hirose antenna connector MC55/56 uses an ultra-miniature SMT antenna connector supplied from Hirose Ltd. The product name is: U.FL-R-SMT The position of the antenna connector on the MC55/56 board can be seen in Figure 40. Figure 30: Mechanical dimensions of U.FL-R-SMT connector Table 21: Product specifications of U.FL-R-SMT connector Item Specification Conditions Nominal impedance 50 Ω Rated frequency DC to 6 GHz Operating temp: -40°C to +90°C Operating humidity: max. 90% Ratings Mechanical characteristics Female contact holding force 0.15 N min Measured with a ∅ 0.475 pin gauge Repetitive operation Contact resistance: Centre 25 mΩ Outside 15mΩ 30 cycles of insertion and disengagement Vibration No momentary disconnections of 1 µs; No damage, cracks and looseness of parts Frequency of 10 to 100 Hz, single amplitude of 1.5 mm, acceleration of 59 m/s2, for 5 cycles in the direction of each of the 3 axes Shock No momentary disconnections of Acceleration of 735 m/s2, 11 ms 1 µs. duration for 6 cycles in the No damage, cracks and looseness direction of each of the 3 axes of parts. Environmental characteristics Humidity resistance No damage, cracks and looseness Exposure to 40°C, humidity of of parts. 95% for a total of 96 hours Insulation resistance: 100 MΩ min. at high humidity 500 MΩ min when dry Temperature cycle No damage, cracks and looseness of parts. Contact resistance: Centre 25 mΩ Outside 15mΩ Temperature: +40°C → 5 to 35°C → +90°C → 5 to 35°C Time: 30 min. → within 5 min. → 30 min. → within 5 min Salt spray test No excessive corrosion 48 hours continuous exposure to 5% salt water MC55/56_hd_v03.00 Page 69 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Table 22: Material and finish of U.FL-R-SMT connector and recommended plugs Part Material Finish Shell Phosphor bronze Silver plating Male centre contact Brass Gold plating Female centre contact Phosphor bronze Gold plating Insulator Plug: Receptacle: PBT LCP Black Beige Mating plugs and cables can be chosen from the Hirose U.FL Series. Examples are shown below and listed in Table 23. For latest product information please contact your Hirose dealer or visit the Hirose home page, for example http://www.hirose.com. Figure 31: U.FL-R-SMT connector with U.FL-LP-040 plug Figure 32: U.FL-R-SMT connector with U.FL-LP-066 plug MC55/56_hd_v03.00 Page 70 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary In addition to the connectors illustrated above, the U.FL-LP-(V)-040(01) version is offered as an extremely space saving solution. This plug is intended for use with extra fine cable (up to ∅ 0.81 mm) and minimizes the mating height to 2 mm. See Figure 33 which shows the Hirose datasheet. Figure 33: Specifications of U.FL-LP-(V)-040(01) plug MC55/56_hd_v03.00 Page 71 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Table 23: Ordering information for Hirose U.FL Series Item Part number HRS number Connector on MC55/56 U.FL-R-SMT CL331-0471-0-10 Right-angle plug shell for ∅ 0.81 mm cable U.FL-LP-040 CL331-0451-2 Right-angle plug for ∅ 0.81 mm cable U.FL-LP(V)-040 (01) CL331-053-8-01 Right-angle plug for ∅ 1.13 mm cable U.FL-LP-066 CL331-0452-5 Right-angle plug for ∅ 1.32 mm cable U.FL-LP-066 CL331-0452-5 Extraction jig E.FL-LP-N CL331-0441-9 MC55/56_hd_v03.00 Page 72 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Electrical, reliability and radio characteristics 5.1 Absolute maximum ratings Absolute maximum ratings for supply voltage and voltages on digital and analog pins of MC55/56 are listed in Table 24. Exceeding these values will cause permanent damage to MC55/56. Table 24: Absolute maximum ratings Parameter Min Max Unit Voltage BATT+ -0.3 4.8 Voltage at digital pins -0.3 3.3 Voltage at analog pins -0.3 3.0 Voltage at digital / analog pins in POWER DOWN mode -0.25 +0.25 Voltage at POWER pin 15 Voltage at CHARGE pin 15 Differential load resistance between EPNx and EPPx 5.2 Ω 15 Operating temperatures Test conditions were specified in accordance with IEC 60068-2 (still air). The values stated below are in compliance with GSM recommendation TS 51.010-01. Table 25: Operating temperatures Parameter Min Typ Max Unit Ambient temperature (according to GSM 11.10) -20 25 55 °C Restricted operation *) -25 to -20 55 to 70***) °C -29 -18 >70**) >60 °C °C +45 °C Automatic shutdown MC55/56 board temperature Battery temperature Charging temperature (software controlled fast charging) *) MC55/56 works, but deviations from the GSM specification may occur. **) MC55/56 has the automatic shutdown set to 70°C at PCL5 (GSM 900 / GSM 850) GPRS Class 8. This prevents permanent damage to components on the board. Consider the ratio of output power, supply voltage and operating temperature: To achieve Tamb max = 70°C and, for example, GSM 900 / GSM 850 PCL5 the supply voltage must not be higher than 4.2V. ***) To achieve Tamb max = 70°C at permanent GPRS class 8 operation (4Tx, 1Rx, GSM 900 / GSM 850 at PCL5 with a supply voltage 4.2V) it is recommended to integrate MC55/56 in such a way that a minor heat exchange with the environment can take place. A solution might be the usage of a small heat sink. MC55/56_hd_v03.00 Page 73 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 5.3 Electrical specifications of the application interface Please note that the reference voltages listed in Table 26 are the values measured directly on the MC55/56 module. They do not apply to the accessories connected. If an input pin is specified for Vi,h,max = 3.3V, be sure never to exceed the stated voltage. The value 3.3V is an absolute maximum rating. The Hirose DF12C board-to-board connector on MC55/56 is a 50-pin double-row receptacle. The names and the positions of the pins can be seen from Figure 34 which shows the top view of MC55/56. 26 50 BATT+ GND BATT+ GND BATT+ GND BATT+ GND BATT+ GND VDD CHARGE /RING0 POWER /DSR0 VDDLP /RTS0 /TXD0 /DTR0 /TXD1 /RTS1 /RXD0 /CTS0 /RXD1 /CTS1 SYNC /DCD0 BATT_TEMP /EMERGOFF RFSDAI /IGT TXDDAI GND SCLK MICN1 TFSDAI MICP1 RXDDAI MICP2 CCGND MICN2 CCIN EPN1 CCRST EPP1 CCIO EPP2 CCVCC EPN2 CCCLK 25 Figure 34: Pin assignment (top view on MC55/56) MC55/56_hd_v03.00 Page 74 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Table 26: Electrical description of application interface Function Signal name IO Signal form and level Comments Power supply BATT+ VI = 3.3V to 4.8V VInorm = 4.2V Inorm ≈ 1.6A during Tx burst 1 Tx, peak current 577µs every 4.616ms 2 Tx, peak current 1154µs every 4.616ms Power supply input. 5 BATT+ pins to be connected in parallel. 5 GND pins to be connected in parallel. The power supply must be able to meet the requirements of current consumption in a Tx burst (up to 2A). Sending with two timeslots doubles the duration of current pulses to 1154µs (every 4.616ms)! VImin = 3.0V VImax = 15V This line signalises to the processor that the charger is connected. If unused keep pin open. GND Charge interface POWER BATT_TEMP Input to measure the Connect NTC with RNTC ≈ 10kΩ @ 25°C to battery temperature over ground. NTC resistor. NTC should be installed inside or near battery pack to enable the charging algorithm and deliver temperature values. If unused keep pin open. CHARGE ICHARGE = -300µA ... -600µA @ 3V < VCHARGE < VLOAD This line is a current source for the charge FET with a 10kΩ resistance between gate and source. If unused keep pin open. External supply voltage VDD VDDmin = 2.84V, VDDmax = 2.96V Imax = -10mA CLmax = 1µF Supply voltage, e.g. for an external LED or level shifter. The external digital logic must not cause any spikes or glitches on voltage VDD. Not available in POWER DOWN mode. VDD signalises the “ON” state of the module. If unused VDD keep pin open. VDD Low Power VDDLP I/O RI =1kΩ VOmax ≈ 4.0V (output) Supplies the RTC with power via an external capacitor or buffer battery if no VBATT+ is applied. If unused keep pin open. VImin = 2.2V, VImax = 5.5V (input) IItyp = 10µA at BATT+ = 0V Mobile in POWER DOWN mode: VImin = 1.2V MC55/56_hd_v03.00 Page 75 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Function Signal name IO Signal form and level Comments Ignition /IGT RI ≈ 100kΩ, CI ≈ 1nF VILmax = 0.5V at Imax = -20µA VOpenmax = 2.3V Input to switch the mobile ON. The line must be driven low by an Open Drain or Open Collector driver. ON Emergency shutdown (Watchdog) /EMERGOFF I/O ~~~ |____|~~~ Active Low ≥ 100ms RI ≈22kΩ VILmax = 0.5V at Imax = -100µA VOpenmax = 2.73V Signal ~~~ |______|~~~ Active Low ≥ 3.2s Watchdog: VOLmax = 0.35V at I = 10µA VOHmin= 2.25V at I = -10µA fOmin = 0.16Hz fOmax = 1.55Hz This line must be driven by an Open Drain or Open Collector driver. Emergency shutdown deactivates the power supply to the module. The module can be reset if /IGT is activated after emergency shutdown. To switch the mobile off use the AT^SMSO command. To avoid floating if pin is high impedance, use pulldown resistor tied to GND. See Chapter 3.3.2.1. /EMERGOFF also indicates the internal watchdog function. If unused keep pin open. Synchronization SYNC VOLmax = 0.2V at I = 1mA VOHmin = 2.35V at I = -1mA VOHmax = 2.73V 1 Tx, 877µs impulse each 4.616ms and 2 Tx, 1454µs impulse each 4.616ms, with 300µs forward time. MC55/56_hd_v03.00 Page 76 of 104 Indicates increased current consumption during uplink transmission burst. Note that timing is different during handover. Alternatively used to control status LED (see Chapter 3.12.2.2). If unused keep pin open. 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Function Signal name IO Signal form and level Comments RI ≈ 100kΩ VILmax = 0.5V VIHmin = 2.15V at I = 20µA, VIHmax=3.3V at I = 30µA CCIN = high, SIM card holder closed (no card recognition) CCRST RO ≈47Ω VOLmax = 0.25V at I = 1mA VOHmin = 2.3V at I = -1mA VOHmax = 2.73V CCIO I/O RI ≈10kΩ VILmax = 0.5V VIHmin = 1.95V, VIHmax=3.3V Maximum cable length 200mm to SIM card holder. All signals of SIM interface are protected against ESD with a special diode array. Usage of CCGND is mandatory. SIM interface CCIN RO ≈220Ω VOLmax = 0.4V at I = 1mA VOHmin = 2.15V at I = -1mA VOHmin = 2.55V at I = -20µA VOHmax = 2.96V CCCLK RO ≈220Ω VOLmax = 0.4V at I = 1mA VOHmin = 2.15V at I = -1mA VOHmax = 2.73V CCVCC ROmax = 5Ω CCVCCmin = 2.84V, CCVCCmax = 2.96V Imax = -20mA CCGND ASC0 interface ASC1 interface Ground /RXD0 /TXD0 /CTS0 /RTS0 /DTR0 /DCD0 /DSR0 /RING0 /RXD1 /TXD1 /CTS1 /RTS1 VOLmax = 0.2V at I = 1mA VOHmin = 2.35V at I = -1mA VOHmax = 2.73V VILmax = 0.5V VIHmin = 1.95V, VIHmax=3.3V /DTR0, RTS0: Imax = -90µA at VIN = 0V /TXD0: Imax = -30µA at VIN = 0V VOLmax = 0.2V at I = 1mA VOHmin = 2.35V at I = -1mA VOHmax = 2.73V VILmax = 0.5V VIHmin = 1.95V, VIHmax=3.3V IImax = -90µA at VIN = 0V First serial interface for AT commands or data stream. To avoid floating if output pins are high-impedance, use pull-up resistors tied to VDD or pull-down resistors tied to GND. See Chapter 3.3.2.1. If unused keep pins open. Second serial interface for AT commands. To avoid floating if output pins are high-impedance, use pull-up resistors tied to VDD or pull-down resistors tied to GND. See Chapter 3.3.2.1. If unused keep pins open. Digital audio interface RFSDAI RXDDAI SCLK TFSDAI TXDDAI MC55/56_hd_v03.00 VOLmax = 0.2V at I = 1mA VOHmin = 2.35V at I = -1mA VOHmax = 2.73V If unused keep pins open. VILmax = 0.5V VIHmin = 1.95V, VIHmax=3.3V IImax = 330µA at VIN = 3.3V Page 77 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Function Signal name IO Signal form and level Comments VOmax = 3.7Vpp See also Table 30. The audio output is balanced and can directly operate an earpiece. If unused keep pins open. VOmax = 3.7Vpp See also Table 30. Balanced audio output. Can be used to directly operate an earpiece. If unused keep pins open. RI ≈ 50kΩ differential VImax = 1.03Vpp See also Table 31. Balanced microphone input. To be decoupled with 2 capacitors (CK = 100nF), if connected to a microphone or another device. If unused keep pins open. RI = 2kΩ differential VImax = 1.03Vpp See also Table 31. Balanced microphone input. Can be used to directly feed an active microphone. If used for another signal source, e.g. op amp, to be decoupled with capacitors. If unused keep pins open. EPP1 EPN1 MICP1 MICN1 MICP2 MICN2 Explanation of signal names: P = positive, N = negative Analog audio EPP2 interfaces EPN2 AGND MC55/56_hd_v03.00 Separate ground connection for external audio circuits. Page 78 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.4 Power supply ratings Table 27: Power supply ratings Parameter Description Conditions Min BATT+ Supply voltage Reference points on MC55/56: TP BATT+ and TP GND (see Figure 39). Voltage must stay within the min/max values, including voltage drop, ripple, spikes. Voltage drop during transmit burst Normal condition, power control level for Pout max Voltage ripple Normal condition, power control level for Pout max 3.3 Typ Max 4.2 50 SLEEP mode @ DRX = 6 TALK mode mV 100 µA mA GSM 850 15 mA EGSM 900 15 GSM 1800/1900 15 GSM850 1) 4) EGSM 900 260 1) 4) GSM 1800/1900 IDLE GPRS 400 POWER DOWN mode IDLE mode 50 @ f>200kHz Average supply current3) 4.8 mV @ f<200kHz IBATT+ Unit 260 2) 4) 180 GSM 850 15 EGSM 900 15 GSM 1800/1900 15 DATA mode GPRS, (4 Rx, 1 Tx) GSM 850 1) 4) EGSM 900 300 1) 4) GSM 1800/1900 Peak supply current Power control level (during transmission slot every 4.6ms) 1) mA 230 450 1) 4) GSM 1800/1900 mA 300 2) 4) DATA mode GPRS, (3 Rx, 2 Tx) GSM 850 1) 4) EGSM 900 mA mA 450 2) 4) 330 1.6 1) Power control level PCL 5 Power control level PCL 0 3) All average supply current values @ IVDD = 0mA 4) Test conditions: 50 Ω 2) MC55/56_hd_v03.00 Page 79 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.4.1 Current consumption during transmit burst The diagrams provided in Figure 35 and Figure 36 illustrate the typical current consumption of the application caused during a transmit burst. The typical peak current is shown vs. the power control level for 900 MHz, 1800 MHz and 1900 MHz and vs. the return loss of the antenna. Test conditions: All measurements have been performed at Tamb= 25°C, VBATT+ nom = 4.1V. Reference points for measuring the voltage are the BATT+ and GND test points on the back side of the module. The curves are for one TX slot (for example a voice call, CSD call or Class 8 GPRS). Curves for Class 10 GPRS activities (2 TX slots) are shown too. Changing the conditions, e.g. in terms of temperature or voltage, will cause different results. Average Current GSM900 (VBATT+=4.1V) 0.5 0.45 0.4 0.43 1 TX - Average Current 2 TX - Average Current Current (Amps) 0.35 0.33 0.3 0.25 0.25 0.23 0.2 0.21 0.15 0.16 0.15 0.1 0.11 0.14 0.13 0.10 0.10 0.05 11 13 15 17 19 Power Control Level MC55/56_hd_v03.00 Page 80 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Average Current DCS1800 (VBATT+=4.1V) 0.3 0.25 0.26 1 TX - Average Current 2 TX - Average Current Current (Amps) 0.2 0.19 0.18 0.15 0.16 0.14 0.13 0.13 0.1 0.12 0.10 0.10 0.05 10 11 12 13 14 15 Power Control Level Average Current PCS1900 (VBATT+=4.1V) 0.3 0.29 0.25 1 TX - Average Current 2 TX - Average Current Current (Amps) 0.2 0.15 0.21 0.17 0.17 0.14 0.13 0.13 0.12 0.1 0.11 0.10 0.05 10 11 12 13 14 15 Power Control Level MC55/56_hd_v03.00 Page 81 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Burst Current GSM900 (VBATT+=4.1V) 1.8 1.6 1.6 1.4 1 TX - Peak current 1.2 Current (Amps) 1.24 0.8 0.6 0.68 0.4 0.4 0.3 0.2 0.28 11 13 15 17 19 Power Control Level Burst Current DCS1800 (VBATT+=4.1V) 0.9 0.8 1 TX - Peak current 0.84 Current (Amps) 0.7 0.6 0.5 0.52 0.4 0.38 0.3 0.27 0.2 0.24 0.1 10 11 12 13 14 15 Power Control Level MC55/56_hd_v03.00 Page 82 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Burst Current PCS1900 (VBATT+=4.1V) 0.92 0.9 0.8 1 TX - Peak current Current (Amps) 0.7 0.6 0.6 0.5 0.4 0.42 0.3 0.3 0.24 0.2 0.1 10 11 12 13 14 15 Power Control Level Test conditions: Tamb= 25°C, VBATT+ nom = 4.1V Figure 35: Typical current consumption vs. power control level MC55/56_hd_v03.00 Page 83 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 1600 Service mode GSM900 ch.124 Variations in current with 0.4dB return loss (all phases) 1400 1200 Current (mA) 1000 ch.124 PCL5 800 600 400 200 Burst (max) Burst (min) Average Current (Max) Average Current (Min) 1000 Service mode PCS1900 ch.661 Variations in current with 0.6dB return loss (all phases) 900 800 700 Current (mA) 600 ch.661 PCL0 500 400 300 200 100 Burst (max) Burst (min) Average Current (Max) Average Current (Min) Test conditions: Tamb= 25°C, VBATT+ nom = 4.1V measured at TP BATT+ and GND, 1 TX slot Figure 36: Typical current consumption vs. return loss MC55/56_hd_v03.00 Page 84 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.5 Electrical characteristics of the voiceband part 5.5.1 Setting audio parameters by AT commands The audio modes 2 to 6 can be adjusted according to the parameters listed below. Each audio mode is assigned a separate set of parameters. Table 28: Audio parameters adjustable by AT command Parameter Influence to Range Gain range Calculation inBbcGain MICP/MICN analog amplifier gain of baseband controller before ADC 0...7 0...42dB 6dB steps inCalibrate digital attenuation of input signal after ADC 0...32767 -∞...0dB 20 * log (inCalibrate/ 32768) outBbcGain EPP/EPN analog output gain of baseband controller after DAC 0...3 6dB steps outCalibrate[n] n = 0...4 digital attenuation of output signal after speech decoder, before summation of sidetone and DAC 0...32767 -∞...+6dB 20 * log (2 * outCalibrate[n]/ 32768) 0...32767 -∞...0dB 20 * log (sideTone/ 32768) 0...-18dB present for each volume step[n] sideTone digital attenuation of sidetone is corrected internally by outBbcGain to obtain a constant sidetone independent of output volume Note: The parameters inCalibrate, outCalibrate and sideTone accept also values from 32768 to 65535. These values are internally truncated to 32767. MC55/56_hd_v03.00 Page 85 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.5.2 Audio programming model The audio programming model shows how the signal path can be influenced by varying the AT command parameters. The model is the same for all three interfaces, except for the parameters and which cannot be modified if the digital audio interface is being used, since in this case the DAC is switched off. The parameters inBbcGain and inCalibrate can be set with AT^SNFI. All the other parameters are adjusted with AT^SNFO. MIC1 2.65V 1k 1k MIC2 -∞...0dB 10uF 1k Speech coder +0...42dB in 6dB steps 1k RFSDAI, RXDDAI TFSDAI, TXDDAI Speech decoder neg. gain (attenuation) 0dB; -6db, -12dB; -18dB n = 0...4 AT parameters are given in brackets <…> and marked red and italic. Figure 37: Audio programming model MC55/56_hd_v03.00 Page 86 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.5.3 Characteristics of audio modes The electrical characteristics of the voiceband part depend on the current audio mode set with the AT^SNFS command. Table 29: Voiceband characteristics (typical) Audio mode no. AT^SNFS= 1 (Default settings, not adjustable) Name Default Handset Basic Handsfree Headset User Handset Plain Codec 1 Plain Codec 2 Purpose DSB with Votronic handset Siemens Car Kit Portable Siemens Headset DSB with individual handset Direct access to speech coder Direct access to speech coder Gain setting via AT command. Defaults: inBbcGain outBbcGain Fix Adjustable Adjustable Adjustable Adjustable Adjustable 4 (24dB) 1 (-6dB) 2 (12dB) 1 (-6dB) 5 (30dB) 2 (-12dB) 4 (24dB) 1 (-6dB) 0 (0dB) 0 (0dB) 0 (0dB) 0 (0dB) Default audio interface 2 3) Power supply ON (2.65V) ON (2.65V) ON (2.65V) ON (2.65V) OFF (GND) OFF (GND) Sidetone ON --- Adjustable Adjustable Adjustable Adjustable Volume control OFF Adjustable Adjustable Adjustable Adjustable Adjustable Limiter (receive) ON ON ON ON --- --- Compressor (receive) --- OFF1) --- --- --- --- AGC (send) --- --- ON --- --- --- Echo control (send) Suppression Cancellation + --suppression Suppression --- --- Noise suppression2) --- up to 10dB 10dB --- --- --- MIC input signal for 0dBm0 @ 1024 Hz (default gain) 23mV 58mV 7.5mV @ 23mV -3dBm0 due to AGC 315mV 315mV EP output signal in mV rms. @ 0dBm0, 1024 Hz, no load (default gain); @ 3.14 dBm0 284mV 120mV default @ max volume 300mV 284mV default @ default @ max volume max volume 895mV 895mV 3.7Vpp 3.7Vpp Sidetone gain at default settings 22.8dB -∞ dB -∞ dB 1) 2) 3) -∞ dB Affected by AGC, 13dB @ 7.5mV (MIC) 22.8dB Adaptive, receive volume increases with higher ambient noise level. The compressor can be activated by loading an application specific audio parameter set (see [9]). In audio modes with noise reduction, the microphone input signal for 0dBm0 shall be measured with a sine burst signal for a tone duration of 5 seconds and a pause of 2 sec. The sine signal appears as noise and, after approx. 12 sec, is attenuated by the noise reduction by up to 10dB. Audio mode 5 and 6 are identical. With AT^SAIC, you can easily switch mode 5 to the second interface. Therefore, audio mode 6 is only kept for compatibility to earlier Siemens GSM products. MC55/56_hd_v03.00 Page 87 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Note: With regard to acoustic shock, the cellular application must be designed to avoid sending false AT commands that might increase amplification, e.g. for a high sensitive earpiece. A protection circuit should be implemented in the cellular application. 5.5.4 Voiceband receive path Test conditions: • The values specified below were tested to 1kHz and 0dB gain stage, unless otherwise stated. • Parameter setup: gs = 0dB means audio mode = 5 for EPP1 to EPN1 and 6 for EPP2 to EPN2, inBbcGain= 0, inCalibrate = 32767, outBbcGain = 0, OutCalibrate = 16384, sideTone = 0. Table 30: Voiceband receive path Parameter Min Typ Max Unit Test condition / remark Differential output voltage (peak to peak) 3.33 3.7 4.07 from EPPx to EPNx gs = 0dB @ 3.14 dBm0 no load Differential output gain settings (gs) at 6dB stages (outBbcGain) -18 dB Set with AT^SNFO Fine scaling by DSP (outCalibrate) -∞ dB Set with AT^SNFO 100 mV gs = 0dB, outBbcGain = 0 and -6dB Ω from EPPx to EPNx Output differential DC offset Differential output resistance Differential load capacitance 1000 pF from EPPx to EPNx Absolute gain accuracy 0.8 dB Variation due to change in temperature and life time Attenuation distortion dB for 300...3900Hz, @ EPPx/EPNx (333Hz) / @ EPPx/EPNx (3.66kHz) Out-of-band discrimination 60 dB for f > 4kHz with in-band test signal@ 1kHz and 1kHz RBW gs = gain setting MC55/56_hd_v03.00 Page 88 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.5.5 Voiceband transmit path Test conditions: • The values specified below were tested to 1kHz and 0dB gain stage, unless otherwise stated. • Parameter setup: Audio mode = 5 for MICP1 to MICN1 and 6 for MICP2 to MICN2, inBbcGain= 0, inCalibrate = 32767, outBbcGain = 0, OutCalibrate = 16384, sideTone = 0 Table 31: Voiceband transmit path Parameter Min Typ Input voltage (peak to peak) Max Unit 1.03 Test condition/Remark MICP1 to MICN1, MICP2 to MICN2 Input amplifier gain in 6dB steps (inBbcGain) 42 dB Set with AT^SNFI Fine scaling by DSP (inCalibrate) -∞ dB Set with AT^SNFI Input impedance MIC1 50 kΩ Input impedance MIC2 2.0 kΩ Microphone supply voltage ON Ri = 4kΩ (MIC2 only) Microphone supply voltage OFF; Ri = 4kΩ (MIC2 only) 2.57 2.17 1.77 2.65 2.25 1.85 2.73 2.33 1.93 Microphone supply in POWER DOWN mode MC55/56_hd_v03.00 no supply current @ 100µA @ 200µA See Figure 17 Page 89 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.6 Air interface Test conditions: All measurements have been performed at Tamb= 25°C, VBATT+ nom = 4.1V. The reference points used on MC55/56 are the BATT+ and GND contacts (test points are shown in Figure 39). Table 32: Air Interface Parameter Min Typ Max Unit Frequency range GSM 850 3) 824 849 MHz Uplink (MS → BTS) E-GSM 900 4) 880 915 MHz GSM 1800 1710 1785 MHz GSM 1900 1850 1910 MHz 869 894 MHz 3) Frequency range GSM 850 Downlink (BTS → MS) E-GSM 900 4) 925 960 MHz GSM 1800 1805 1880 MHz GSM 1900 1930 1990 MHz RF power @ ARP with 50Ω load GSM 850 3) E-GSM 900 4) 1) GSM 1800 2) GSM 1900 Number of carriers GSM 850 Duplex spacing 31 33 35 dBm 31 33 35 dBm 28 30 32 dBm 28 30 32 dBm 3) 124 E-GSM 900 4) 174 GSM 1800 374 GSM 1900 299 GSM 850 3) 45 MHz E-GSM 900 4) 45 MHz GSM 1800 95 MHz GSM 1900 80 MHz 200 kHz Carrier spacing Multiplex, Duplex TDMA / FDMA, FDD Time slots per TDMA frame Frame duration 4.615 ms Time slot duration 577 µs -102 -107 dBm Modulation GMSK 3) Receiver input sensitivity @ ARP GSM 850 BER Class II < 2.4% (static input level) E-GSM 900 4) -102 -107 dBm GSM 1800 -102 -106 dBm GSM 1900 -102 -105.5 dBm 1) Power control level PCL 5 MC55/56_hd_v03.00 2) Power control level PCL 0 Page 90 of 104 3) MC56 only 4) MC55 only 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 5.7 Electrostatic discharge The GSM engine is not protected against Electrostatic Discharge (ESD) in general. Consequently, it is subject to ESD handling precautions that typically apply to ESD sensitive components. Proper ESD handling and packaging procedures must be applied throughout the processing, handling and operation of any application that incorporates a MC55/56 module. Special ESD protection provided on MC55/56: Antenna interface: one spark discharge line (spark gap) SIM interface: clamp diodes for protection against overvoltage. The remaining ports of MC55/56 are not accessible to the user of the final product (since they are installed within the device) and therefore, are only protected according to the “Human Body Model” requirements. MC55/56 has been tested according to the EN 61000-4-2 standard. The measured values can be gathered from the following table. Table 33: Measured electrostatic values Specification / Requirements Contact discharge Air discharge ESD at SIM port ± 4kV ± 8kV ESD at antenna port ± 4kV ± 8kV ETSI EN 301 489-7 Human Body Model (Test conditions: 1.5 kΩ, 100 pF) ESD at the module Note: ± 1kV Please note that the values may vary with the individual application design. For example, it matters whether or not the application platform is grounded over external devices like a computer or other equipment, such as the Siemens reference application described in Chapter 7. MC55/56_hd_v03.00 Page 91 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 5.8 Reliability characteristics The test conditions stated below are an extract of the complete test specifications. Table 34: Summary of reliability test conditions Type of test Conditions Standard Vibration Frequency range: 10-20 Hz; acceleration: 3.1mm DIN IEC 68-2-6 amplitude Frequency range: 20-500 Hz; acceleration: 5g Duration: 2h per axis = 10 cycles; 3 axes Shock half-sinus Acceleration: 500g DIN IEC 68-2-27 Shock duration: 1msec 1 shock per axis 6 positions (± x, y and z) Dry heat Temperature: +70 ±2°C Test duration: 16 h EN 60068-2-2 Bb ETS 300019-2-7 Humidity in the test chamber: < 50% Temperature change (shock) Low temperature: -40°C ±2°C DIN IEC 68-2-14 Na High temperature: +85°C ±2°C Changeover time: < 30s (dual chamber system) ETS 300019-2-7 Test duration: 1 h Number of repetitions: 100 Damp heat cyclic High temperature: +55°C ±2°C DIN IEC 68-2-30 Db Low temperature: +25°C ±2°C Humidity: 93% ±3% ETS 300019-2-5 Number of repetitions: 6 Test duration: 12h + 12h Cold (constant exposure) MC55/56_hd_v03.00 Temperature: -40 ±2°C DIN IEC 68-2-1 Test duration: 16 h Page 92 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Mechanics The following chapters describe the mechanical dimensions of MC55/56 and give recommendations for integrating MC55/56 into the host application. 6.1 Mechanical dimensions of MC55/56 Figure 38 shows the top view on MC55/56 and provides an overview of the mechanical dimensions of the board. For further details see Figure 40. Size: Weight: 35±0.15 x 32.5±0.15 x 3.1±0.3 mm (including application connector) 35±0.15 x 32.5±0.15 x 2.95±0.2 mm (excluding application connector) 5.5g Figure 38: MC55/56 – top view Figure 39 shows the bottom view of MC55/56 and marks the test points and pads for antenna connection. Antenna ground TP BATT+ TP Ground Antenna pad Figure 39: MC55/56 bottom view MC55/56_hd_v03.00 Page 93 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary All dimensions in millimetres Figure 40: Mechanical dimensions of MC55/56 MC55/56_hd_v03.00 Page 94 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 6.2 Mounting MC55/56 onto the application platform There are many ways to properly install MC55/56 in the host device. An efficient approach is to mount the MC55/56 PCB to a frame, plate, rack or chassis. Fasteners can be M1.6 or M1.8 screws plus suitable washers, circuit board spacers, or customized screws, clamps, or brackets. Screws must be inserted with the screw head on the bottom of the MC55/56 PCB. In addition, the board-to-board connection can also be utilized to achieve better support. For proper grounding it is strongly recommended to use the ground plane on the back side in addition to the five GND pins of the board-to-board connector. To avoid short circuits ensure that the remaining sections of the MC55/56 PCB do not come into contact with the host device since there are a number of test points. Figure 39 shows the positions of all test points. To prevent mechanical damage, be careful not to force, bend or twist the module. Be sure it is positioned flat against the host device. All the information you need to install an antenna is summarized in Chapter 4.1. Note that the antenna pad on the bottom of the MC55/56 PCB must not be influenced by any other PCBs, components or by the housing of the host device. It needs to be surrounded by a restricted space as described in Chapter 4.1. MC55/56_hd_v03.00 Page 95 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary 6.3 Board-to-board connector This chapter provides specifications for the 50-pin board-to-board connector which serves as physical interface to the host application. The receptacle assembled on the MC55/56 PCB is type Hirose DF12C. Mating headers from Hirose are available in different stacking heights. Figure 41: Hirose DF12C receptacle on MC55/56 Figure 42: Header Hirose DF12 series Table 35: Ordering information DF12 series Item Part number Stacking height (mm) HRS number Receptacle on MC55/56 DF12C(3.0)-50DS-0.5V(81) 3-5 537-0694-9-81 Headers DF12 series DF12E(3.0)-50DP-0.5V(81) 3.0 537-0834-6-** DF12E(3.5)-50DP-0.5V(81) 3.5 537-0534-2-** DF12E(4.0)-50DP-0.5V(81) 4.0 537-0559-3-** DF12E(5.0)-50DP-0.5V(81) 5.0 537-0584-0-** Notes: The headers listed above are without boss and metal fitting. Please contact Hirose for details on other types of mating headers. Asterixed HRS numbers denote different types of packaging. Table 36: Electrical and mechanical characteristics of the Hirose DF12C connector Parameter Specification (50 pin board-to-board connector) Number of contacts 50 Quantity delivered 2000 connectors per tape & reel Voltage 50V Rated current 0.3A max per contact Resistance 0.05 Ohm per contact Dielectric withstanding voltage 500V RMS min Operating temperature -45°C...+125°C Contact material phosphor bronze (surface: gold plated) Insulator material PA , beige natural Stacking height 3.0 mm ; 3.5 mm ; 4.0 mm ; 5.0 mm Insertion force Withdrawal force 1 21.8N st 10N Withdrawal force 50th 10N Maximum connection cycles 50 MC55/56_hd_v03.00 Page 96 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 6.3.1 Mechanical dimensions of the Hirose DF12 connector Figure 43: Mechanical dimensions of Hirose DF12 connector 6.3.2 Adapter cabling The board-to-board connection is primarily intended for direct contact between both connectors. If this assembly solution does not fit into your application design ensure that the used adapter cable meets the following requirements: • • Maximum length: 200 mm It is recommended that the total cable length between the board-to-board connector pins on MC55/56 and the pins of the card holder does not exceed 200 mm in order to meet the specifications of 3GPP TS 51.010-1 and to satisfy the requirements of EMC compliance. Type of cable: Flexible cable or flexible printed circuit board designed to mate with the Hirose receptacle and headers specified above. The equipment submitted for type approving the Siemens reference setup of MC55/56 includes a 160mm adapter cable. See Chapter 7.1. MC55/56_hd_v03.00 Page 97 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary Reference Approval 7.1 Reference Equipment for Type Approval The Siemens reference setup submitted to type approve MC55/56 consists of the following components: • Siemens MC55/56 cellular engine • Development Support Box (DSB45) • Flex cable (160 mm) from Hirose DF12C receptacle on MC55/56 to Hirose DF12 connector on DSB45. Please note that this cable is not included in the scope of delivery of DSB45. • SIM card reader integrated on DSB45 • Handset type Votronic HH-SI-30.3/V1.1/0 • PC as MMI Antenna or 50 Ω cable to system simulator Antenna PC RS-232 GSM engine DSB45 Flex cable 160mm DAI cable for acoustic measuring SIM DAI Box Power supply Handset Acoustic tester Figure 44: Reference equipment for approval MC55/56_hd_v03.00 Page 98 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 7.2 Compliance with FCC Rules and Regulations (MC55 only) The FCC Equipment Authorization Certification for the MC55 reference application described in Chapter 7.1 is listed under the FCC identifier QIPMC55 IC: 267W-MC55 granted to Siemens AG. The MC55 reference application registered under the above identifier is certified to be in accordance with the following Rules and Regulations of the Federal Communications Commission (FCC). “This device contains GSM 900 MHz and GSM 1800MHz functions that are not operational in U.S. Territories. This device is to be used only for mobile and fixed applications. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter. Users and installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance. Antennas used for this OEM module must not exceed 7dBi gain for mobile and fixed operating configurations. This device is approved as a module to be installed in other devices.” The FCC label of the module must be visible from the outside. If not, the host device is required to bear a second label stating, “Contains FCC ID QIPMC55”. Manufacturers of mobile or fixed devices incorporating MC55 modules are advised to include instructions according to above mentioned RF exposure statements in their end product user manual. Please note that changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. MC55/56_hd_v03.00 Page 99 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 7.3 Compliance with FCC Rules and Regulations (MC56 only) The FCC Equipment Authorization Certification for the MC56 reference application described in Chapter 7.1 is listed under the FCC identifier QIPMC56 IC: 267W-MC56 granted to Siemens AG. The MC56 reference application registered under the above identifier is certified to be in accordance with the following Rules and Regulations of the Federal Communications Commission (FCC). “This device contains GSM 1800MHz function that is not operational in U.S. Territories. This device is to be used only for mobile and fixed applications. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter. Users and installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance. Antennas used for this OEM module must not exceed 7dBi gain (GSM 1900) and 1.4dBi (GSM 850) for mobile and fixed operating configurations. This device is approved as a module to be installed in other devices.” The FCC label of the module must be visible from the outside. If not, the host device is required to bear a second label stating, “Contains FCC ID QIPMC56”. Manufacturers of mobile or fixed devices incorporating MC56 modules are advised to include instructions according to above mentioned RF exposure statements in their end product user manual. Please note that changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. MC55/56_hd_v03.00 Page 100 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary 8 Design example Figure 45 shows a sample application that incorporates an MC55/56 module and an external µController. This solution is typical of devices designed for audio and GSM capability, such as mobile phones, PDAs, Tablet PCs etc. The audio part is made of internal transducers (earpiece and microphone) and integrates an additional interface for connecting an external headset. This interface detects the presence of a plugged headset and verifies whether the headset key (push-to-talk key) is pressed. The charging circuit is designed to ensure trickle charging that takes effect when the battery is deeply discharged. Used components: 100Ω series resistance, Z diode 4V3, 1SS355 diode. If the charger supplies a voltage from 5.5V to 8V this arrangement will deliver an overall current of approx. 15mA (5.5V) to 37mA (8V) for trickle charging and for the application. If the application circuit draws a greater current another LDO (Low Dropout Regulator) can be added to allow for an additional parallel power supply dedicated to the application. This LDO can be connected between the positive charger input and the 3V power supply source. Caution: Trickle charging is done when the voltage of the Li-Ion battery is below 3.2V. High level of the VDD line indicates that the MC55/56 module is active. While MC55/56 is in POWER DOWN mode the application interface is switched off and must not be fed from any other source. Therefore, the application must be designed to avoid any current flow into any digital pins of the application interface. The RING0 line notifies, primarily, incoming calls. Therefore, if connected with an interrupt of the application µController, the RING0 line can be effectively used to wake up the application µController from power saving. The test points (referred to as “TPx”) can be used for downloading firmware to the MC55/56 module. TP0: GND TP1: Data transfer from MC55/56 TP2: Data transfer to MC55/56 TP3: Starts up MC55/56 (high active) The EMC measures are best practice recommendations. In fact, an adequate EMC strategy for an individual application is very much determined by the overall layout and, especially, the position of components. For example, mounting the internal acoustic transducers directly on the PCB eliminates the need to use the ferrite beads shown in the sample schematic. Disclaimer No warranty, either stated or implied, is provided on the sample schematic diagram shown in Figure 45 and the information detailed in this section. As functionality and compliance with national regulations depend to a great amount on the used electronic components and the individual application layout manufacturers are required to ensure adequate design and operating safeguards for their products using MC55/56 modules. MC55/56_hd_v03.00 Page 101 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary LDO 33pF 2.2µF 1SS355 GSM antenna BATT+ 3V Li-Ion battery pack 2.2uF 100R 4V3 CRS04 5.5V - 8V 500mA SI3441DV 33pF 3k3 NTC TP1 TP2 µC Keypad Oscillator RESET RESET Headset plug in Push to talk GPI GPI INT RING0 GPI VDD GND 47k 3V 100k BC 847 GSM M o du le BC847 TP3 BC 847 100nF 100nF CCVCC Note: CCCLK CCIO RXD0, CTS0, DSR0, CCRST DCD0, RING0 CCIN CCGND can float if module is in POWER DOWN state. Use pull down resistors (>100k) if necessary. SIM 1nF 200nF 27pF 27pF 47pF 0R not mounted BLM 18HG 601 MICN2 EPP2 EPN2 IGT VDDLP EMERG MICN1 MICP1 EPN1 EPP1 OFF BC847 47k 3V *) CHARGE POWER MICP2 GPI 47k 100k TXD0 RXD0 CTS0 RTS0 DSR0 DTR0 DCD0 GPO GPO *) ESD protection e.g. 1/5 ESDA6V1-5W6 BATT_TEMP TXD RXD CTS RTS DSR DTR DCD 10k BATT+ GND V+ LCD Charger *) 33pF TP0 2k 6R8 6R8 2x BLM 18HG 601 6R8 ESD 2x47nF >100µF Backup 6R8 of RTC 3V 3V 2x4.7nF ESD internal If internal transducers internal BLM 18HG 601 are placed on BAV99 PCB ferrite beads are not necessary 10pF ESD 470k Phone jack 4x BLM 18HG 601 100nF 2x47nF ESD 1M 100nF 470k 470k 100nF 2.7k 2.2k 3V 22µF Figure 45: Schematic diagram of MC55/56 sample application MC55/56_hd_v03.00 Page 102 of 104 16.08.2005 s MC55/56 Hardware Interface Description Confidential / Preliminary List of parts and accessories Table 37: List of parts and accessories Description Supplier Ordering information Siemens Siemens ordering number: Standard module: MC55 L36880-N8372-A100 Customer IMEI SIM Lock mode: L36880-N8373-A100 Standard module: MC56 L36880-N8375-A100 Customer IMEI SIM Lock mode: L36880-N8376-A100 Siemens Car Kit Portable Siemens Siemens ordering number: L36880-N3015-A117 DSB45 Support Box Siemens Siemens ordering number: L36880-N8301-A100 BB35 Bootbox Siemens Siemens ordering number: L36880-N8102-A100-1 Votronic Handset VOTRONIC Votronic HH-SI-30.3/V1.1/0 VOTRONIC Entwicklungs- und Produktionsgesellschaft für elektronische Geräte mbH Saarbrücker Str. 8 66386 St. Ingbert Germany Phone: Fax: e-mail: SIM card holder incl. push button ejector and slide-in tray Molex DF12C board-to-board connector Hirose +49-(0)6 89 4 / 92 55-0 +49-(0)6 89 4 / 92 55-88 contact@votronic.com Ordering numbers: 91228 91236 Sales contacts are listed in Table 38. See Chapter 6.3 for details on receptacle on MC55/56 and mating headers. Sales contacts are listed in Table 39. U.FL-R-SMT antenna connector MC55/56_hd_v03.00 Hirose See Chapter 4.1.2 for details on U.FL-R-SMT connector, mating plugs and cables. Sales contacts are listed in Table 39. Page 103 of 104 16.08.2005 MC55/56 Hardware Interface Description Confidential / Preliminary Table 38: Molex sales contacts (subject to change) Molex Molex Deutschland GmbH American Headquarters For further information please click: Felix-Wankel-Str. 11 4078 Heilbronn-Biberach Germany Lisle, Illinois 60532 U.S.A. http://www.molex.com/ Phone: +49-7066-9555 0 Fax: +49-7066-9555 29 Email: mxgermany@molex.com Molex China Distributors Beijing, Room 1319, Tower B, COFCO Plaza No. 8, Jian Guo Men Nei Street, 100005 Beijing P.R. China Phone: +86-10-6526-9628 Phone: +86-10-6526-9728 Phone: +86-10-6526-9731 Fax: +86-10-6526-9730 Molex Singapore Pte. Ltd. Jurong, Singapore Phone: +65-268-6868 Fax: +65-265-6044 Phone: +1-800-78MOLEX Fax: +1-630-969-1352 Molex Japan Co. Ltd. Yamato, Kanagawa, Japan Phone: +81-462-65-2324 Fax: +81-462-65-2366 Table 39: Hirose sales contacts (subject to change) Hirose Ltd. For further information please click: http://www.hirose.com Hirose Electric UK, Ltd Crownhill Business Centre 22 Vincent Avenue, Crownhill Milton Keynes, MK8 OAB Great Britain Phone:+44-1908-305400 Fax: +44-1908-305401 MC55/56_hd_v03.00 Hirose Electric (U.S.A.) Inc 2688 Westhills Court Simi Valley, CA 93065 U.S.A. Phone: +1-805-522-7958 Fax: +1-805-522-3217 Hirose Electric GmbH Zeppelinstrasse 42 73760 Ostfildern Kemnat 4 Germany Phone: +49-711-4560-021 Fax +49-711-4560-729 E-mail info@hirose.de Hirose Electric Co., Ltd. 5-23, Osaki 5 Chome, Shinagawa-Ku Tokyo 141 Japan Phone: +81-03-3491-9741 Fax: +81-03-3493-2933 Hirose Electric Co., Ltd. European Branche First class Building 4F Beechavenue 46 1119PV Schiphol-Rijk Netherlands Phone: +31-20-6557-460 Fax: +31-20-6557-469 Page 104 of 104 16.08.2005
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