Sony 6220511 Transmitter module for mobile applications User Manual
Sony Mobile Communications Inc Transmitter module for mobile applications
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Integrators Manual
GR47/GR48 Integrator’s Manual Product Photo/Illustration The GR47 described in this manual conforms to the Radio and Telecommunications Terminal Equipment (R&TTE) directive 99/5/EC with requirements covering EMC directive 89/336/EEC and Low Voltage directive 73/23/EEC. The product fulfils the requirements according to 3GPP TS 51.010-1, EN 301 489-7 and EN60950. SAR statement: This product is intended to be used with the antenna or other radiating element at least 20 cm away from any part of the human body. The information contained in this document is the proprietary information of Sony Ericsson Mobile Communications International.The contents are confidential and any disclosure to persons other than the officers, employees, agents or subcontractors of the owner or licensee of this document, without the prior written consent of SonyEricsson Mobile Communications International, is strictly prohibited. Further, no portion of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, without the prior written consent of Sony Ericsson Mobile Communications International, the copyright holder. First edition (May 2003) Sony Ericsson Mobile Communications International publishes this manual without making any warranty as to the content contained herein. Further Sony Ericsson Mobile Communications International reserves the right to make modifications, additions and deletions to this manual due to typographical errors, inaccurate information, or improvements to programs and/or equipment at any time and without notice. Such changes will, nevertheless be incorporated into new editions of this manual. All rights reserved. © Sony Ericsson Mobile Communications International, 2003 Publication number: LZT 123 7589 R1A Printed in UK Contents Overview ................................................................................................................... 5 1. Introduction .............................................................................................................. 6 Target Users ................................................................................................................ 6 Prerequisites................................................................................................................ 6 Manual Structure......................................................................................................... 6 2. GR47/GR48 Radio Devices ...................................................................................... 7 About the GR47/GR48 Family ................................................................................... 7 Radio Devices in a Communication System ................................................................. 7 Features ....................................................................................................................... 9 Service and Support ................................................................................................... 12 Precautions................................................................................................................ 13 3. Abbreviations.......................................................................................................... 14 Integrating the Radio Device ................................................................................ 16 4. Mechanical Description .......................................................................................... 17 Interface Description ................................................................................................. 17 Physical Dimensions.................................................................................................. 18 5. System Connector Interface ................................................................................... 19 Overview ................................................................................................................... 19 General Electrical and Logical Characteristics ............................................................ 22 Grounds .................................................................................................................... 23 VCC - Regulated Power Supply Input ....................................................................... 23 Battery Charging Input (CHG_IN) ........................................................................... 24 Turning the Radio Device ON/OFF and the External Power Signal........................... 25 Analogue Audio ........................................................................................................ 29 PCM Digital Audio ................................................................................................... 33 Serial Data Interfaces ................................................................................................. 36 SIM Card Related Signals .......................................................................................... 40 Service/Programming ................................................................................................ 41 Buzzer ....................................................................................................................... 42 LED .......................................................................................................................... 42 General Purpose Digital I/O Ports ............................................................................. 43 Extended I/O capabilities .......................................................................................... 44 General Purpose Analogue I/O Ports ......................................................................... 45 External I 2C Serial Control Bus................................................................................. 48 TX_ON - Burst Transmission ................................................................................... 49 LZT 123 7589 R1A Real Time Clock........................................................................................................ 49 6. Antenna Connector................................................................................................. 51 7. Keyboard Interface ................................................................................................. 52 IO#/KEYROW# ....................................................................................................... 52 KEYCOL# ................................................................................................................ 52 8. Hints for Integrating the Radio Device................................................................. 54 Safety Advice and Precautions ................................................................................... 54 Installation of the Radio Device................................................................................. 56 Antenna .................................................................................................................... 58 9. Embedded Applications ......................................................................................... 60 Features ..................................................................................................................... 60 Implementation......................................................................................................... 60 10. TCP/IP Stack........................................................................................................... 62 Implementation......................................................................................................... 62 11. Technical Data ........................................................................................................ 63 12. Declaration of Conformity...................................................................................... 65 Developer’s Kit ....................................................................................................... 66 13. Introduction to the Developer’s Kit ...................................................................... 67 Contents of the Kit.................................................................................................... 67 General Functioning of the Kit.................................................................................. 68 14. Using the Developer’s Kit...................................................................................... 71 Start up Check List .................................................................................................... 72 Developer’s Board Overlay......................................................................................... 73 Jumpers..................................................................................................................... 74 Switches .................................................................................................................... 78 Headers ..................................................................................................................... 79 Connectors ................................................................................................................ 80 LED Indicators .......................................................................................................... 82 System Connector Pin Assignments........................................................................... 83 LZT 123 7589 R1A Overview Product Photo/Illustration 1. Introduction 1.1 Target Users The GR47 and GR48 radio devices are designed to be integrated into machine-to-machine or man-to-machine communications applications. They are intended to be used by manufacturers, system integrators, applications developers and developers of wireless communications equipment. 1.2 Prerequisites It is assumed that the person integrating the radio device into an application has a basic understanding of the following: • GSM networking; • Wireless communication and antennas (aerials); • AT commands; • ITU-T standard V.24/V.28; • Micro controllers and programming; • Electronic hardware design. 1.3 Manual Structure The manual is composed of three parts: Part 1- Overview This section provides a broad overview of the GR47/GR48 family and includes a list of abbreviations used in the manual. Part 2 - Integrating the Radio Device This section describes each of the signals available on the GR47/GR48 radio devices, along with mechanical information. The section also provides you with design guidelines and explains what is needed to commercialise an application from a regulatory point of view. Part 3 - Developer’s Kit This section lists the contents of the Developer’s Kit and provides the information to setup and use the equipment. LZT 123 7589 R1A 2. GR47/GR48 RADIO DEVICES 2. GR47/GR48 Radio Devices 2.1 About the GR47/GR48 Family Two radio devices make up the family; GR47 and GR48, for use in the E-GSM900/GSM1800 and GSM850/GSM1900 bands respectively. 1RWH This manual refers to the GR47 and GR48 as radio devices. If there is a difference in the functionality of the radio devices the GR47 and GR48 information will be listed separately. The products belong to a new generation of Sony Ericsson radio devices, and are intended to be used in machine-to-machine applications and manto-machine applications. They are used when there is a need to send and receive data (by SMS, CSD, HSCSD, or GPRS), and make voice calls over the GSM network. The radio devices can either have applications embedded onto them or they can be used as the engine in an application created by the customer. The radio device can send and receive data when a script is executed, the script can be run internally from the radio device itself or from a micro-controller. A typical application, involves a micro-controller and a radio device, in which the micro-controller sends AT commands to the radio device via an RS232 communications link. 2.2 Radio Devices in a Communication System Figures 2.1 and 2.2 illustrate the main blocks of a wireless communication system using the radio device. Figure 2.1 shows the communication system when the script is embedded on the radio device and figure 2.2 shows the communication system when a micro-controller is used. They also show the communication principles of the system and the interface between the radio device and the application. The definitions in the figures, as used elsewhere in this manual, are in accordance with the recommendations of GSM 07.07. • The MS (mobile station) represents the radio device and SIM card. The radio device excluding SIM card, is known as the ME (mobile equipment). • The DTE (data terminal equipment) is the controlling application. This can be either an external host or an internal embedded application. • The DCE (data circuit terminating equipment) is the serial communication interface of the MS. LZT 123 7589 R1A 2. GR47/GR48 RADIO DEVICES GSM NETWORK MS GR47 / GR48 SIM SYSTEM CONNECTOR POWER SUPPLY GSM ENGINE STATUS & RESPONSE DCE EMBEDDED APPLICATION DTE ‘AT’ COMMAND CONTROL Figure 2.1 Main Blocks in a Wireless System (embedded application) GSM NETWORK MS GR47 / GR48 SIM EXTERNAL APPLICATION MS STATUS & RESPONSE SYSTEM CONNECTOR POWER SUPPLY GSM ENGINE DCE DTE DTE ‘AT’ COMMAND CONTROL M Figure 2.2 Main Blocks in a Wireless System (external micro-controller) In accordance with the recommendations of ITU-T (International Telecommunication Union - Telecommunications Standardisation Sector) V.24, the TE communicates with the MS over a serial interface. LZT 123 7589 R1A 2. GR47/GR48 RADIO DEVICES The functions of the radio device follow the recommendations provided by ETSI (European Telecommunications Standards Institute) and ITU-T. ETSI specifies a set of AT commands for controlling the GSM element of the radio device; these commands are supplemented by Sony Ericsson specific commands. To find out how to work with AT commands, see the AT Commands Manual. 2.3 Features The radio device performs a set of telecom services (TS) according to GSM standard phase 2+, ETSI and ITU-T. The functions of the radio device are implemented by issuing AT commands over a serial interface. 2.3.1 Types of Mobile Station GR47 and GR48 are dual band mobile stations with the characteristics shown in the tables below. GR47 E-GSM 900 GSM 1800 Frequency Range (MHz) TX: 880-915 RX: 925-960 TX: 1710-1785 RX: 1805-1880 Channel spacing 200 kHz 200 kHz Number of channels 174 carriers *8 time slots 374 carriers *8 time slots Modulation GMSK GMSK TX phase accuracy < 5º RMS phase error (burst) < 5º RMS phase error (burst) Duplex spacing 45 MHz 95 MHz Receiver sensitivity at antenna connector < –102 dBm < –102 dBm Transmitter output power at antenna connector Class 4 2 W (33 dBm) Class 1 1 W (30 dBm) Automatic hand-over between E-GSM 900 and GSM 1800 GR48 GSM 850 GSM 1900 Frequency Range (MHz) TX: 824-849 RX: 869-894 TX: 1850-1910 RX: 1930-1990 Channel spacing 200 kHz 200 kHz Number of channels 124 carriers *8 time slots 299 carriers *8 time slots Modulation GMSK GMSK TX Phase Accuracy < 5º RMS phase error (burst) < 5º RMS phase error (burst) LZT 123 7589 R1A 2. GR47/GR48 RADIO DEVICES GR48 GSM 850 GSM 1900 Duplex spacing 45 MHz 80 MHz Receiver sensitivity at antenna connector < –102 dBm < –102 dBm Transmitter output power at antenna connector Class 4 2W (33 dBm) Class 1 1 W (30 dBm) Automatic hand-over between GSM 850 and GSM 1900 2.3.2 Short Message Service The radio device supports the following SMS services: • Sending; MO (mobile-originated) with both PDU (protocol data unit) and text mode supported. • Receiving; MT (mobile-terminated) with both PDU and text mode supported. • CBM (cell broadcast message); a service in which a message is sent to all subscribers located in one or more specific cells in the GSM network (for example, traffic reports). • SMS STATUS REPORT according to GSM 03.40. The maximum length of an SMS message is 160 characters when using 7-bit encoding. For 8-bit data, the maximum length is 140 characters. The radio device supports up to six concatenated messages to extend this function. Concatenation is disabled if CNMI 3,2 is set (See the AT Commands Manual for further details). 2.3.3 Voice Calls The radio device offers the capability of MO (mobile originated) and MT (mobile terminated) voice calls, as well as supporting emergency calls. Multi-party, call waiting and call divert features are available. Some of these features are network-operator specific. For the inter-connection of audio, the radio device offers both single ended and balanced analogue input and output lines. Direct interface to the digital PCM (pulse code modulation) bus used within the radio device is available, thus by-passing the internal analogue circuitry. The radio devices support HR, FR and EFR vocoders.The GR48 also supports the Adaptive Multi Rate (AMR) type of vocoder. 10 LZT 123 7589 R1A 2. GR47/GR48 RADIO DEVICES 2.3.4 Data The radio device supports the following data protocols: • *356 *HQHUDO3DFNHW5DGLR6HUYLFH The radio devices are Class B terminals. The radio devices are GPRS 4+1 enabled, which are capable of receiving at a maximum of four timeslots per frame (down link), and transmitting in one timeslot per frame (up link). • &6' &LUFXLW6ZLWFKHG'DWD The radio devices are capable of establishing a CSD communication at 9.6 kbps. • +6&6' +LJK6SHHG&LUFXLW6ZLWFKHG'DWD The radio devices support HSCSD communication, with one timeslot per frame capacity in the up link and two timeslots per frame capacity in the down link (2+1). 2.3.5 SIM Card An external SIM card with 3 V or 5 V technology, can be connected to the radio device via its 60-pin system connector. 2.3.6 Power Consumption GSM 850 and E-GSM 900 GSM 1800 and GSM 1900 1RWH Idle Mode Transmit/Operation Voice/CSD < 5 mA < 250 mA (< 2 A peak) Data (GPRS 4+1) < 5 mA < 350 mA (< 2 A peak) Voice/CSD < 5 mA < 250 mA (<1.75 A peak) Data (GPRS 4+1) < 5 mA < 350 mA (<1.75 A peak) The power consumption during transmission is measured at maximum transmitted power. 2.3.7 Other Features These include: • 07.10 multiplexing. • GPS interoperability. • SIM application tool kit, class 2 release 96 compliant. • Embedded application • On board TCP/IP stack • E-OTD (Supported by GR48) 11 LZT 123 7589 R1A 2. GR47/GR48 RADIO DEVICES 2.4 Service and Support 2.4.1 Web Pages Visit our web site for the following information: • where to buy radio devices or for recommendations concerning accessories and components; • the telephone number for customer support in your region; • FAQs (frequently asked questions). The web site address is: http://www.SonyEricsson.com/M2M 2.4.2 Integrator’s Manual This manual provides you with all of the information you need to integrate the radio device into your application. 2.4.3 AT Commands Manual The AT Commands Manual provides you with all the AT commands you can use with your radio device. AT commands are in logical groups and contain the command, a description of its functionality and an example of use. 2.4.4 M2mpower Application Guide The M2mpower Application Guide provides you with all the information you need to build an application using the M2mpower support environment. This manual is supplied as part of the M2mpower package. 2.4.5 Developer’s Kit Sony Ericsson provides the developer’s kit to get you started quickly. The kit includes the necessary hardware required to begin the development of an application. It includes the following: • GSM radio device, GR47 or GR48; • This Integrator’s Manual; • Developer’s kit hardware; • Developer’s kit accessories; – Power supply – RS232 cable – Headset – Antenna. 12 LZT 123 7589 R1A 2. GR47/GR48 RADIO DEVICES All the user needs to provide, is a computer or micro-controller and the expertise to use AT commands. 2.5 Precautions The radio devices are ESD protected up to 4K V contact and 8K V air discharge. It is recommended that you follow electronic device handling precautions when working with any electronic device system to ensure no damage occurs to the host or the radio device. In “Integrating the Radio Device”, page 16 you will find more information about safety and product care. Do not exceed the environmental and electrical limits as specified in “Technical Data”, page 63. 13 LZT 123 7589 R1A 3. ABBREVIATIONS 3. Abbreviations Abbreviation Explanations AMR Adaptive Multi Rate ATMS Audio to Mobile Station AFMS Audio from Mobile Station CBM Cell Broadcast Message CBS Cell Broadcast Service CSD Circuit Switched Data DCE Data Circuit Terminating Equipment DK Developer’s Kit DTE Data Terminal Equipment DTMF Dual Tone Multi Frequency EA Embedded Application EFR Enhanced Full Rate EMC Electro-Magnetic Compatibility E-OTD Enhanced Observed Time Difference ETSI European Telecommunication Standards Institute FR Full Rate GPRS General Packet Radio Service GPS Global Positioning System GSM Global System for Mobile Communication HR Half Rate HSCSD High Speed Circuit Switched Data IDE Integrated Development Environment IP Internet Protocol ITU-T International Telecommunication Union - Telecommunications Standardisation Sector M2mpower Sony Ericssons powerful support environment ME Mobile Equipment MMCX Micro Miniature Coax MO Mobile Originated MS Mobile Station MT Mobile Terminated PCM Pulse Code Modulation 14 LZT 123 7589 R1A 3. ABBREVIATIONS Abbreviation Explanations PDU Protocol Data Unit RF Radio Frequency RFU Reserved for Future Use RLP Radio Link Protocol RTC Real Time Clock SDP Service Discovery Protocol SIM Subscriber Identity Module SMS Short Message Service TCP Transport Control Protocol UDP User Datagram Protocol 15 LZT 123 7589 R1A Integrating the Radio Device Product Photo/Illustration 4. Mechanical Description 4.1 Interface Description The pictures below show the mechanical design of the radio device along with the positions of the different connectors and mounting holes. The radio device is protected with AISI 304 stainless steel covers that meet the environmental and EMC requirements. Mounting hole/ground connection System connector Antenna connector Figure 4.1 Radio Device viewed from below Figure 4.2 Radio Device, viewed from above Please note the following: • Mounting holes positioned at the corners make it possible to securely bolt the radio device into your application. 17 LZT 123 7589 R1A 4. MECHANICAL DESCRIPTION • Keypad, display, microphone, speaker and battery are not part of the radio device. • The SIM card is mounted in your application, external to the radio device. • The System Connector is a 60-pin, standard 0.05 in (1.27 mm) pitch type. The pins and their electrical characteristics are described in 5. System Connector Interface, page 19. • Information about the Antenna Connector is found in 6. Antenna Connector, page 51. 4.2 Physical Dimensions 2.20 (4x) 2.86 4.78 3.80 2.05 7.15 2.90 4.60 3.00 2.80 50.00 33.00 30.20 2.30 9.00 46.40 1.80 Figure 4.3 Dimensions of the Radio Device Measurements are given in millimetres. See also Technical Data, page 63. 18 LZT 123 7589 R1A 5. System Connector Interface 5.1 Overview Electrical connections to the radio device (except the antenna), are made through the System Connector Interface. The system connector is a 60-pin, standard 0.05 in (1.27 mm) pitch device. The system connector allows both board-to-board and board-to-cable connections to be made. Use a board-board connector to connect the radio device directly to a PCB, and a board-cable connector to connect the radio device via a cable. Figure 5.1 below shows the numbering of the connector pins. A ground connection is provided at the mounting hole next to the RF connector on the radio device as shown below. Connect this ground point to the DGND pins of the radio device by the shortest, low-impedance path possible. The purpose of this connection is to allow any antenna ESD strikes to bypass the radio device’s internal ground path. Ground connection Pin 59 Pin 1 Pin 60 Pin 2 Figure 5.1 Radio Device, viewed from underneath The following table gives the pin assignments for the system connector interface and a short description for each signal. 19 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 1RWH Under the heading “Dir” in the table, radio device input and output signals are indicated by the letters I and O respectively. Pin Signal Name Dir Signal Type Description VCC Supply Power supply DGND Digital ground VCC Supply Power supply DGND Digital ground VCC Supply Power supply DGND Digital ground VCC Supply Power supply DGND Digital ground VCC Supply Power supply 10 DGND Digital ground 11 CHG_IN Battery charge power Battery charging 12 DGND Digital ground 13 IO5 ADC4 I/0 Digital 2.75V Analogue General purpose input/output 5 Analogue to digital converter 4 14 ON/OFF Internal pull up, open drain Turns the radio device on and off. 15 SIMVCC Digital 3 V/5 V SIM card power supply. Power output from radio device for SIM Card 16 SIMPRESENCE Internal pull up, open drain SIM Presence A “1” indicates that the SIM is missing; a “0” that it is inserted 17 SIMRST Digital 3 V/5 V SIM card reset 18 SIMDATA I/O Digital 3 V/5 V SIM card data 19 SIMCLK Digital 3 V/5 V SIM card clock 20 DAC Analogue Digital to analogue converter 21 IO1 KEYROW2 I/O Digital 2.75V General purpose input/output 1 Keyboard row 2 22 IO2 ADC5 I/O Digital 2.75V Analogue General purpose input/output 2 Analogue to digital converter 5 23 IO3 KEYROW3 I/O Digital 2.75V General purpose input/output 3 Keyboard row 3 24 IO4 KEYROW4 I/O Digital 2.75V General purpose input/output 4 Keyboard row 4 25 VRTC Supply 1.8V Supply for real time clock 26 ADC1 Analogue Analogue to digital converter 1 27 ADC2 Analogue Analogue to digital converter 2 20 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Pin Signal Name Dir Signal Type Description 28 ADC3 Analogue Analogue to digital converter 3 29 SDA I/O 2.75V, internal pull up I 2 C data 30 SCL 2.75V, internal pull up I 2 C clock 31 BUZZER Digital 2.75V Buzzer output from radio device 32 OUT3 KEYCOL3 DSR Digital 2.75V General purpose output 3 Keyboard column 3 Data set ready (UART1) 33 LED IO6 I/O Digital 2.75V Flashing LED General purpose I/O 6 34 VIO Power Out 2.75 V Radio device power indication. VIO is a 2.75 V at 75 mA output supply that can be used to power external circuitry that interfaces to the radio device 35 TX_ON Digital 2.75V This output indicates when the GSM radio device is going to transmit the burst 36 RI KEYCOL2 O2 Digital 2.75V Ring Indicator (UART1) Keyboard column 2 General purpose output 2 37 DTR KEYROW1 IN1 Digital 2.75V Data Terminal Ready (UART1) Keyboard row 1 General purpose input 1 38 DCD KEYCOL1 O1 Digital 2.75V Data Carrier Detect (UART1) Keyboard column 1 General purpose output 1 39 RTS IO9 I/O Digital 2.75V Request To Send (UART1) General purpose I/O 9 40 CTS KEYCOL4 O4 Digital 2.75V Clear To Send (UART1) Keyboard column 4 General purpose output 4 41 TD Digital 2.75V Transmitted Data (UART1). Data from DTE (host) to DCE (radio device). 42 RD Digital 2.75V Received Data (UART1). Data from DCE (radio device) to DTE (host). 43 TD3 I/O7 I/O Digital 2.75V Transmitted data (UART3) General purpose I/O 7 44 RD3 I/O8 I/O Digital 2.75V Received data (UART3) General purpose I/O 8 45 TD2 Digital 2.75V Transmitted data (UART2). Used for flashing the memory. 46 RD2 Digital 2.75V Received data (UART2). Used for flashing the memory. 47 PCMULD Digital 2.75V DSP PCM digital audio input 48 PCMDLD Digital 2.75V DSP PCM digital audio output 21 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Pin Signal Name Dir Signal Type Description 49 PCMO Digital 2.75V Codec PCM digital audio output 50 PCMI Digital 2.75V Codec PCM digital audio input 51 PCMSYNC Digital 2.75V DSP PCM frame sync 52 PCMCLK Digital 2.75V DSP PCM clock output 53 MICP Analogue Microphone Input positive 54 MICN Analogue Microphone Input negative 55 BEARP Analogue Speaker output positive 56 BEARN Analogue Speaker output negative 57 AFMS Analogue Audio output from radio device 58 SERVICE 2.7V Flash programming voltage for the MS. Enable logger information if not flashing. 59 ATMS Analogue Audio input to radio device 60 AGND Analogue Analogue ground 5.2 General Electrical and Logical Characteristics Many of the signals, as indicated in the table above, are high-speed CMOS logic inputs or outputs powered from a 2.75 V ± 5 % internal voltage regulator, and are defined as Digital 2.75 V. Whenever a signal is defined as Digital 2.75 V, the following electrical characteristics apply. 1RWH Parameter Min. Max. Units High Level Output Voltage (VOH), Io = –2mA 2.2 2.75 Low Level Output Voltage (VOL), Io = 2mA 0.6 High Level Input Voltage (VIH) 1.93 2.75 Low Level Input voltage (VIL) 0.5 Unused pins can be left floating. 5.2.1 General Protection Requirements • All 2.75 V digital inputs will continuously withstand and suffer no damage in the power-on or power-off condition when subjected to any voltage from - 0.5 V to 3.47 V (3.3 V + 5 %). • All 2.75 V digital outputs will continuously withstand a short circuit to any other voltage within the range 0 V to 3 V. • All analogue outputs will continuously withstand a short circuit to any voltage within the range 0 V to 3 V. 22 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE • The SIM output signals and the SIMVCC supply will continuously withstand a short circuit to any voltage within the range 0 V to 4.1V. 5.3 Grounds Pin Signal Description 2, 4, 6, 8, 10, 12 DGND Digital ground 60 AGND Analogue ground There are two ground connections in the radio device, AGND (analogue ground) and DGND (digital ground). Pin assignments are shown in the table above. 1RWH AGND and DGND are connected at a single point inside the radio device. They must not be joined together in your application. 5.3.1 Analogue Ground - AGND AGND is the return signal, or analogue audio reference, for ATMS (Audio To Mobile Station) and AFMS (Audio From Mobile Station). It is connected to the DGND inside the radio device only. The application must not connect DGND and AGND. Parameter Limit Imax ≅12.5 mA 5.3.2 Digital Ground - DGND DGND is the reference or return signal for all system interface digital signals and is also the d.c. return for SERVICE and the power supply, VCC. Connect all DGND pins together in your application in order to carry the current drawn by the radio device. Parameter Per Pin Total (5 Pins) Imax < 6.0A < 3.0A Iavg < 100mA < 600mA 5.4 VCC - Regulated Power Supply Input Pins Signal Description 1, 3, 5, 7, 9 VCC regulated power supply input Power is supplied to the radio device VCC pins, from an external source. 23 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Connect all VCC pins together in your application in order to carry the current drawn by the radio device. The electrical characteristics for VCC are shown in the table below. Parameter Mode Limit Vcc supply voltage Nominal 3.6 V Tolerance including ripple a 3.4 V - 4.0 V Over-voltage limit 5.5 V Maximum ripple < 100 mV @ <200 kHz; < 20 mV @ > 200 kHz Burst transmission 200 mV Maximum allowable voltage drop Current drawn, at full TX power < 500 mA (average) < 2 A (peak) a. Measured at system connector pins. 1RWH The radio device has no internal capacitance to supply the large current peaks during GSM burst transmission. We recommend you follow these general guidelines: • Fit a low ESR electrolytic capacitor close to the radio device: > 1,000 µF; < 100 mΩ ESR. • Make sure power supply to radio device line resistance is < 200 mΩ. 5.5 Battery Charging Input (CHG_IN) For battery powered applications, the radio device has a connection to aid and support battery charging. The typical design where this may be applicable is to power the radio device directly from a battery source connected to VCC (pins 1, 3, 5, 7, 9) and to provide a 5V dc power source (600mA max) to the CHG_IN connection (pin 11). The radio device can control an internal switching FET which creates a charging pathway to the battery. While power is provided at CHG_IN, the battery charge can be maintained. If the power should fail or be removed at CHG_IN, the application will be supported by the battery alone. When CHG_IN voltage returns, the battery charging and maintenance will commence once more. &DXWLRQ Battery charging algorithms are unique to different battery types. Sony Ericsson Mobile Communications will not accept any responsibility or liability for damage, product failures, even death or injury occurring as a result of incompatible battery and charging algorithms being applied without their prior knowledge and consent. 24 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Safety considerations should be taken into account. For example, monitoring the temperature of the battery. If the temperature of the battery exceeds its specification limits, battery charging must be stopped immediately. If the battery temperature continues to rise the application should be suspended or the battery disconnected. 1RWH When charging Lithium batteries, the battery pack must have an internal protection circuit in accordance with the manufacturer’s instructions. 5.6 Turning the Radio Device ON/OFF and the External Power Signal Turning the Radio Device On tO VCC tON tPULSE ON/OFF ON/OFF pulled up internally through 39kΩ tPRST tVIO VIO Software running… tCTS CTS Figure 5.2 On timings and VIO performance Symbol Parameters Conditions Min. Typ Max Unit t Reference time when VCC is within working limits (1) VCC > 3.2V ON/OFF = VCC t21 Time after t0 when the ON/ OFF pulse can begin VCC > 3.2V ms 25 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE t9,2 Time after start of ON/OFF pulse when VIO is active VCC > 3.2V 45.0 ms t38/6( Application ON/ OFF pulse width ON/OFF held low until detected by software 400 500 ms t3567 Internal Poweron reset signal initiates software 100 200 ms t&76 Time when software controlled CTS signal indicates module READY 0.35 3.0(2) CTS signal configured for RS232 hardware flow control, not GPIO pin (1) The GR47 measures the voltage at VCC during the power-up sequence. It is important that both VCC and ON/OFF reach a minimum of 3.2V before the ON/OFF low pulse is initiated. (2) In SERVICE mode. 26 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Turning the Radio Device Off VCC tOFF tPULSE ON/OFF tSCSD VIO tSPD Software controlled shutdown. (Performs GSM Network detach and SIM power management) Figure 5.3 Off timings and VIO performance Symbol Parameters t63' Conditions Min. Typ Max Unit Time for software pulse detection which initiates a software shutdown 800 ms t38/6( Application ON/ OFF pulse width 1000 ms t6&6' Software controlled shutdown deactivates VIO -) 2.5) 10(3) s) ms (2) t2)) Time when VCC power supply can be disabled VIO is DISABLED (2) It is a requirement from most GSM network providers that GSM products properly detach from the network during a power-down sequence. In order to achieve this it is important that the VCC supply is not removed or turned off before VIO has been deactivated by the module. 27 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Hard Shutdown Sequence tPULSE ON/OFF tHSD VIO Figure 5.4 Hard Shutdown Sequence Symbol Parameters t+6' Time to complete hardware shutdown t38/6( Application ON/ OFF pulse width Conditions ON/OFF low until VIO is disabled Min. Typ Max Unit 11 t+6' 10 (4) To implement the Hard Shutdown of the GR47, the ON/OFF pulse must be held low until the sequence is complete. Ensure that ON/OFF is not released before VIO has been deactivated by the module. 5.6.1 VIO - 2.75V Supply VIO provides an output voltage derived from an internal 2.75V regulator. Its electrical characteristics are shown below. Parameter Min. Typ. Max. Units Output Voltage (Iload = 50 mA) 2.70 2.75 2.85 75 mA Load current You can use this output for the following: • to indicate that the radio device is powered; • to power interface circuits, external to the radio device. 28 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.7 Analogue Audio Pin Signal Dir Description 57 AFMS Audio from mobile station 59 ATMS Audio to mobile station 60 AGND Ground (return) for analogue audio ATMS is the audio input, and AFMS is the audio output, of the radio device. These signals can be used in car kit mode. There are three factory-set audio profiles: • portable handsfree • handset • car kit Portable handsfree is the factory-set default profile. The modification, configuration, manipulation and storage of audio profiles is achieved with the AT*E2EAMS (Audio Profile Modification) and AT*E2APR (Audio Profile). 5.7.1 Audio To Mobile Station - ATMS ATMS is the analogue audio input to the radio device. Internally, the signal is sent to the CODEC (COder/DECoder), where it is converted to digital audio in PCM (Pulse Code Modulation) format. The encoded audio is sent to PCMOUT via the internal PCM bus. ATMS provides a DC bias when it is used as the microphone input in Portable Hands-free applications. All other sources must be a.c.-coupled to avoid attenuation of low frequencies, and to prevent incorrect biasing or damage to the ATMS input. Use a capacitor greater than the value shown in the table below. The ATMS input is a passive network followed by the transmit part of the CODEC. Parameter Limit Application driving impedance (0.3 - 3.5 kHz) ≤ 300 Ω AC coupling capacitance ≥ 1 µF Radio device input impedance (0.3 - 3.5 kHz) > 50 kΩ Low frequency cut-off (- 3 dB) 300 Hz ± 50 Hz High frequency cut-off (– 3 dB) > 3500 Hz ± 50 Hz Output d.c. bias level 0V car kit mode Additional Gain in car kit mode 28.5 dB 29 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE The following tables show the nominal PGA (programming gain settings). For more information see the relevant AT commands. Maximum input voltage limit: 245 mVrms Input Input (mVrms) TXAGC (dB) AUX AMP gain PCMOUT (dBm0) ATMS 245 13 Maximum input level at MICI, 61.4 mVrms output at PCMOUT = 3 dBm0 Input Differential input (mVrms) TXAGC (dB) AUX AMP gain PCMOUT (dBm0) MICN MICP 61.4 25 Output at AFMS for 3 dBm0 at PCMIN Input dBm0 RXPGA Volume control (dB) AFMS (mVrms) PCMIN 436 Output at BEARN/BEARP for 3 dBm0 at PCMIN Input dBm0 RXPGA Volume control (dB) BEAR (mVrms) PCMIN 388 5.7.2 Audio From Mobile Station - AFMS AFMS is the analogue audio output from the radio device and may be used to drive a speaker or the ear-piece in a car kit. PCM digital audio signals, entering the radio device through the PCMIN pin, are translated to analogue signals by the CODEC. See 5.8 PCM Digital Audio, page 33 for further information. The table below shows the audio signal levels for AFMS. Parameter Limit Speaker impedance 64 Ω to 1 kΩ 30 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Parameter Limit Output Capacitance 2.2 µF ±10 % Levels (THD < 5 %) Drive capability into 5 kΩ (0.3 - 3.5 kHz) > 2.4 Vp-p Drive capability into 1.5 kΩ (0.3 - 3.5 kHz) > 2.2 Vp-p Drive capability into 150 Ω (at 1 kHz) > 1.3 Vp-p 5.7.3 Microphone Signals Pin Speaker signals Dir Function 53 MICP Microphone positive input 54 MICN Microphone negative input MICP and MICN are balanced differential microphone input pins. These inputs are compatible with an electret microphone. The microphone contains an FET buffer with an open drain output, which is supplied with at least +2 V relative to ground by the radio device as shown below. 2 - 2.5V @ 1mA CODEC 1k MICP 68nF 68nF MICN GR47 1k AGND Figure 5.5 Microphone connections to the radio device 31 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.7.4 Speaker Signals Pin Speaker signals Dir Function 55 BEARP Speaker positive output 56 BEARN Speaker negative output BEARP and BEARN are the speaker output pins. These are differential-mode outputs. The electrical characteristics are given in the table below. Parameter Limit Output level (differential) ≥ 4.0 VSS Output level (dynamic load = 32 Ω) ≥ 2.8 VSS Gain PCMIN(5) to BEARP/BEARN (differential) – 9 dB ± 1 Distortion at 1 kHz and maximum output level ≤5% Offset, BEARP to BEARN ± 30 mV Ear-piece mute-switch attenuation ≥ 40 dB (5) See PCMIN signal in 5.8 PCM Digital Audio, page 33. The following table shows the ear piece impedances that can be connected to BEARP and BEARN. Ear piece model Impedance Tolerance Dynamic ear piece [32 Ω + 800 µH] // 100 pF ± 20 % Dynamic ear piece [150 Ω + 800 µH] // 100 pF ± 20 % Piezo ear piece 1 kΩ + 60 nF ± 20 % 32 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.8 PCM Digital Audio Pin Signal Dir Function 52 PCMCLK PCM clock 51 PCMSYNC PCM frame sync 47 PCMULD PCM audio input to DSP 48 PCMDLD PCM audio output from DSP 50 PCMIN PCM audio input to Codec 49 PCMOUT PCM audio output to Codec Figure 5.6 shows the PCM (Pulse Code Modulation) digital audio connection for external devices. These connections can be used to process PCM digital audio signals, bypassing the radio device’s internal analogue audio CODEC. GR47 PCMSYNC & PCMCLK DSP PCMDLD PCMIN PCMULD PCMOUT CODEC System connector Link for internal digital-audio processing Analogue audio signals Figure 5.6 Pin connections to digital audio 1RWH When no external audio processing is performed, the following pins must be connected together: • PCMDLD to PCMIN • PCMULD to PCMOUT Electrical characteristics Digital 2.75 V CMOS input/output electrical characteristics apply. 33 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.8.1 PCM Data Format All of the radio device’s PCM signals, including signals between its CODEC and DSP conform to the PCM data I/O format of the industry standard DSP from Texas Instruments. PCMCLK (bit clock) and PCMSYNC (frame synchronisation) are both generated by the DSP within the radio device. The DSP within the radio device is the master therefore all external PCM clocks and data from external devices must be synchronized to it 13-Bit PCM Mode Bit Contents D15 to D14 Equal to D13 D13 to D1 Two’s complement of the 13-bit PCM D0 LSB, not used The radio device implements 13-bit PCM with the 13-bit data embedded in a 16-bit word within a 24-bit frame (see Figure 5.8). Each PCM word contains 16-bits: D0 to D15. D13 to D1 is the two’s complement value of the 13-bit PCM, with D13 as the sign bit. D14 and D15 are always set to be equivalent with D13. D0, the LSB, is not used as shown in Figure 5.7 below. = D13 13 bit PCM MSB D14 D13 D12 D11 D10 D9 D8 D7 D6 D0 D5 D4 D3 D2 D1 LSB 16 bit data word Figure 5.7 16-bit data word format 16-Bit PCM Mode Bit Contents D15 - D0 Two’s complement The frame format is equal to the one shown in Figure 5.7, but with D15, D14 and D0 filled with significant bits. D15 to D0 is the two’s complement value of the 16-bit PCM with bit 15 as the sign bit. 34 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE PCM Timing Diagrams The PCM timing is shown in Figure 5.8 below and it is seen that the CPU has 45 µs to serve an interrupt and setup data channels. Data is sent on the falling edge of the sync pulse. The data bits in PCMULD and PCMDLD are aligned so that the MSB in each word occurs on the same clock edge as shown in Figure 5.9. 125 µs Clk Sync 45 µs Data Figure 5.8 16-bit word within 24-bit frame PCM signal timing is shown in Figure 5.9. The signals characteristics are described in the tables following Figure 5.9. PCMCLK tPSS PCMSYN PCMIN tPSH tDSH tDSL MSB D14 D13 tPDLP PCMOUT MSB D14 D13 Figure 5.9 PCM Timing Diagram Name Description Typ. Unit tPSS PCMSYN (setup) to PCMCLK (fall) 2.5 µs tPSH PCMSYN pulse length µs tDSL PCMI (setup) to PCMCLK (fall) 2.5 µs tDSH PCMI (hold) from PCMCLK (fall) 2.5 µs tPDLP PCMO valid from PCMCLK (rise) 2.5 µs Name Description Typ. Unit FPCMCLK PCM clock frequency 200 kHz TPCMCLK PCM clock period with 50/50 mark space ratio µs FPCMSYN PCM sync frequency kHz 35 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Typical Rise/Fall times Rise Time Fall Time Unit PCMCLK 19 18 ns PCMSYN 19 15 ns PCMOUT 900 900 ns PCMDLD 20 19 ns 5.9 Serial Data Interfaces Pin Signal Dir Description RS232 CCITT Nº 41 TD Serial data to radio device (UART1) 103 42 RD Serial data from radio device (UART1) 104 39 RTS IO9 I/O Request To Send (UART1) General purpose input/output 9 105 40 CTS KeyCOL4 O4 Clear To Send (UART1) Key column 4 General purpose output 4 106 37 DTR KeyROW1 IN1 Data Terminal Ready (UART1) Keyboard row 1 General purpose input 1 108.2 32 DSR KeyCOL3 O3 Data Set Ready (UART) Key column 3 General purpose output 3 107 38 DCD KeyCOL 1 O1 Data Carrier Detect (UART1) Key column 1 General purpose output 1 109 36 RI KeyCOL 2 O2 Ring Indicator (UART1) Key Column 2 General output 2 125 45 TD2 Transmitted Data (UART2) 46 RD2 Received Data (UART2) 43 TD3 Transmitted Data (UART3) 44 RD3 Received Data (UART3) The serial channels, consisting of three UARTs, are asynchronous communication links to the application or accessory units. • UART1 has RS-232 functionality and is used for all on- and off -line communication. • UART2 behaves as a general-purpose serial data link. For example, it can be used for GPS, downloading software and receiving logging information. • UART3 behaves as a general-purpose serial data link. It can be used by an embedded application. 36 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Digital 2.75 V CMOS input/output electrical characteristics apply. The standard character format consists of 1 start bit, 8 bit data, no parity and 1 stop bit. In all, there are 10 bits per character. 5.9.1 UART1 (RS232) - RD, TD, RTS, CTS, DTR, DSR, DCD and RI UART1 signals conform to a 9-pin RS232 (V.24) serial port. 1RWH UART1 signal levels do not match standard RS232 (V.28) levels. The relationship between the levels is shown in the table below. RS232 level RD, TD RTS, CTS, DTR, DSR, DCD, RI CMOS level <– 3V OFF > 1.93 V >+3V ON < 0.80 V Conversion between the radio device CMOS levels and RS232 levels can be achieved using a standard interface IC, such as the Maxim Integrated Products MAX3237. 5.9.2 Serial Data Signals - RD, TD The default baud rate is 9.6 kbits/s, however higher bit rates of up to 460 kbits/s are supported, set by an AT command. UART1 starts at a rate of 9.6 kbits/s in standard AT command mode. The radio device also supports GSM 07.10 multiplexing protocol and starts when the appropriate command is sent. Serial Data From Radio Device (RD) RD is an output signal that the radio device uses to send data via UART1 to the application. Parameter Limit Application load resistance < 100 kΩ Application load capacitance < 100 pF Serial Data To Radio Device (TD) TD is an input signal, used by the application to send data via UART1 to the radio device. Parameter Limit Application driving impedance < 100 Ω Input capacitance 1nF Input resistance 100 kΩ to 2.75 V 37 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.9.3 Control Signals - RTS, CTS, DTR, DSR, DCD, RI UART1 control signals are active low and need a standard interface IC, such as the MAX3237, to generate standard RS232 levels. UART1 converted signals, together with DGND, RD and TD form a 9-pin RS232 data port. RTS and CTS are capable of transmitting at 1/10th of the data transmission speed for data rates up to 460 kbit/s (byte-oriented flow control mechanism). 1RWH When hardware flow control is not used in communications between the application and the radio device, RTS and CTS must be connected to each other at the radio device. Switching times for RTS and CTS The table below shows the switching times. Parameter Limit Time from Low to High level < 2 µs Time from High to Low level < 2 µs Request to Send (RTS) Used to condition the DCE for data transmission. The default level is high by internal pull up. The application must pull RTS low to enable data transmission from the radio device. Similarly, the radio device asserts CTS low, indicating it is ready to receive data transmission from the host. Parameter Limit Application driving impedance < 100 Ω Input capacitance < 2 nF Input resistance (pull-up) 100 kΩ to DGND Clear To Send (CTS) CTS is asserted by the DCE to indicate that the host (DTE) may transmit data. When CTS is high, the host (DTE) is not permitted to transmit data. The table below shows the load characteristics for this signal. Parameter Limit Application load capacitance < 500 pF Application load resistance ≥ 1 MΩ 38 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Data Terminal Ready (DTR) DTR indicates that the DTE is ready to receive data. It also acts as a hardware ‘hang-up’, terminating calls when switched high. The signal is active low. You can define the exact behaviour of DTR with an AT command. Data Set Ready (DSR) DSR indicates that the DCE is ready to receive data. The signal is active low. Data Carrier Detect (DCD) DCD indicates that the DCE is receiving a valid carrier (data signal) when low. Ring Indicator (RI) RI indicates that a ringing signal is being received by the DCE when low. You can define the exact behaviour of RI with an AT command. 5.9.4 UART2 - TD2, RD2 UART 2 consists of a full duplex serial communication port with transmission and reception lines. This communication port works in a mode called Operation and Maintenance. Operation and Maintenance mode works in combination with the SERVICE signal. Two events are possible if the SERVICE signal is active when the radio device is turned on. These are: • the radio device is reprogrammed if UART2 is connected to a computer running Sony Ericsson update software; • the radio device enters logging mode and sends data to UART2 if no reprogramming information is received. Timing and electrical signals characteristics are the same as for UART1, TD and RD, except for maximum baud rate which could increase to 921 kbps. Transmitted Data 2 (TD2) TD2 is used by the application to send data to the radio device via UART2. It has the same electrical characteristics as TD. Received Data 2 (RD2) RD2 is used to send data to the application via UART2. It has the same electrical characteristics as RD. 39 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.9.5 UART3 - TD3, RD3 UART3 is a full duplex serial communication port with transmission and reception lines. It has the same timing and electrical signal characteristics as UART1, TD and RD. Transmitted Data 3 (TD3) TD3 is used by your application to send data to the radio device via UART3. Received Data 3 (RD3) RD3 is used to send data to your application via UART3. 5.10 SIM Card Related Signals Pin Signal Dir Description 15 SIMVCC SIM card power supply 16 SIMPRESENCE SIM card presence 17 SIMRST SIM card reset 19 SIMCLK SIM card clock 18 SIMDATA I/O SIM card data These connections allow you to communicate with the SIM card holder in your application. 1RWH The distance between the SIM card holder and the radio device can be up to 25cm. This SIM interface allows the use of 3 V and 5 V SIM cards. By default it works on 3 V levels but will automatically switch to 5 V, if a 5 V SIM card is fitted. SIM voltage levels, as shown in the following table, are dependent on the type of SIM card detected by the radio device. Signal Parameter Mode Min. Typ. Max. Unit SIMVCC SIM supply voltage 3V 2.7 3.0 3.3 5V 4.5 5.0 5.5 3V 2.1 3.0 5V 3.5 5.0 3V 0.9 5V 1.5 SIMDAT High Level Input voltage (V ) ,+ SIMDAT Low Level Input voltage (V ) ,/ 40 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Signal Parameter Mode Min. SIMDAT High Level Output voltage (V ) 3V 2+ SIMDAT Low Level Output voltage (V ) 2/ SIMCLK SIMRST High Level Output voltage (V ) SIMCLK SIMRST Low Level Output voltage (V ) 2+ 2/ Typ. Max. Unit 2.7 3.0 5V 4.7 5.0 3V 0.2 5V 0.2 3V 2.4 3.0 5V 4.4 5.0 3V 0.35 5V 0.3 5.10.1 SIM Detection - SIMPRESENCE SIMPRESENCE is used to determine whether a SIM card has been inserted into or removed from the SIM card holder. You should normally wire it to the “card inserted switch” of the SIM card holder, but different implementations are possible. When left open, an internal pull-up resistor maintains the signal high and means “SIM card missing” to the radio device. When pulled low the radio device assumes a SIM card is inserted. SIMPRESENCE is a Digital 2.75V CMOS input with the following electrical characteristics. Parameter Min. Pull-up resistance (at 2.75 V) 100 Typ. Low Level Input voltage (SIM inserted) High Level Input voltage (SIM missing) 1RWH > 1.93 Max. Units kΩ 0.80 2.75 To meet regulatory approvals SIMPRESENCE must be implemented. 5.11 Service/Programming Pin Signal Dir Description 58 SERVICE Flash programming voltage When the SERVICE input signal is active the radio device will: • be reprogrammed if data is received through UART2 from a computer running Sony Ericsson reprogramming software; • or it will output logging data on UART2. 41 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE The electrical characteristics are given below. The signal reference is DGND. Mode SERVICE Voltage (V) Min. Typ. Normal Operation Service/enable programming 1.9 2.75V Absolute maximum voltage Drive Capacity Max. 0.8 3.6 > 1 mA 13.5 5.12 Buzzer Pin Signal Dir Description 31 BUZZER Buzzer output from radio device Connecting the BUZZER signal to an inverting transistor-buffer followed by a piezoelectric transducer enables the radio device to play preprogrammed melodies or sounds. 5.13 LED Pin Signal Dir Description 33 LED LED Output from radio device The LED states shown below, are hard coded. LED indication Operational status No indication No power or in the OFF state Green, steady Power on, not connected to a network Green, blinking Power on, connected to a network 42 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE The following circuit can be used to connect an LED. VCC 330 LED GR47/48 DGND 10k BC817 10k Figure 5.10 Electrical connections for the LED 5.14 General Purpose Digital I/O Ports Pin I/O port signal Default signal Description 21 IO1 IO1 Programmable Input/Output 1 KEYRow2 22 IO2 IO2 Programmable Input/Output 2 ADC5 23 IO3 IO3 Programmable Input/Output 3 KEYRow3 24 IO4 IO4 Programmable Input/Output 4 KEYRow4 13 IO5 IO5 Programmable Input/Output 5 ADC4 33 IO6 LED Programmable Input/Output 6/LED 43 IO7 TD3 Programmable Input/Output 7/TD3 44 IO8 RD3 Programmable Input/Output 8/RD3 39 IO9 RTS Programmable Input/Output 9/RTS 37 IN1 DTR Programmable Input 1 Data Terminal Ready 32 OUT3 DSR Programmable Output 3/DSR 36 OUT2 RI Programmable Output 2/RI Ring Indicator 38 OUT1 DCD Programmable Output 1/DCD Data Carrier Detect 40 OUT4 CTS Programmable Input/Output 4/CTS Signals which have an entry in the Default Signal column in the above table are multiplexed. 43 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE The operational modes of multiplexed signals are controlled by AT commands and also by intrinsic functions available to an embedded The following table gives you the input impedance. These values only apply when the ports are configured as input signals. 1RWHV Parameter Min. Typ. Max. Units Input impedance (pull-up) 50 100 120 kΩ I/O6 (LED) doesn’t have an internal pull up. If this pin is configured as an input, it should not be left floating. I/O7 (TD3) has a pull down instead of a pull up. 5.15 Extended I/O capabilities To increase flexibility and variety of radio device peripherals, the RS232 hardware flow control shares its physical interface with the keypad scanning interface and the extended general purpose I/O capability. This sharing means that it is not feasible to operate all these features concurrently, however, with care, dynamic switching from one feature to another is possible. Using Embedded Applications When a particular I/O feature is required, the user sets the state of the relevant I/O blocks by disabling one set before enabling others. The radio device checks the state of the I/O when the user requests a new function. The new function is rejected if the current function is not released first. 1RWH Only the states of I/O1 - I/O5 are retained for the next power up. For example, inputs remain as inputs and outputs remain as outputs. The voltage of a defined output pin will still drop to 0 Volts in the radio device power down state. 5.15.1 LED/IO6 Capabilities The LED function pin can be used as a general purpose digital I/O when the flashing LED function is not required. However, this pin does not have an on-board pull-up resistor. It is required that an external pull-up or pulldown resistor be provided by the host circuitry when either not used or when used as a digital input. 44 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.15.2 I#/O# If pins labelled I# and O# are not being used for an alternative function they may be used for general purpose inputs or outputs respectively. The inputs have an on-board 100k pull-up resistor and the outputs are driven rail-to-rail at 2.75V levels. 5.15.3 UART3/IO# The UART3 pins have been given alternative functions as general purpose I/O, both pins may be used for either input or output. However, the TX pin has a 100kΩ pull-down resistor to ground and the RX pin has a 100kΩ pull-up resistor to 2.75V. This must be taken into consideration when designing the host circuit. 5.15.4 IO#/ADC# To increase analog input capabilities, the radio device optimises the I/O by multiplexing or sharing different features on single pins. There are two digital I/O pins which now have an additional ADC input. When configured as digital I/O, the software will not read the voltages at the two new ADC inputs. When configured as ADC inputs the software will configure the digital I/O pins as input or high impedance tri-state. In this state any applied voltage between 0V and 2.75V can be read as an 8 bit value. Because the additional ADC inputs (ADC4 and ADC5) are common with digital I/O, the input circuit of the ADC is not the same as for the original circuits ADC1-3. It is important to understand the input structure of the pin so that the correct analog voltage is read by the application. 5.16 General Purpose Analogue I/O Ports Pin Signal Dir Description 20 DAC Digital to analogue conversion output 26 ADC1 Analogue to digital conversion input 1 27 ADC2 Analogue to digital conversion input 2 28 ADC3 Analogue to digital conversion input 3 13 ADC4 (I/O5) I (I/O) Analogue to digital conversion input 4 22 ADC5 (I/O2) I (I/O) Analogue to digital conversion input 5 The radio device is able to convert digital to analogue signals and vice versa. 45 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.16.1 Digital to Analogue Converter - DAC The DAC is an 8-bit converter. Conversion takes place when an AT command is sent to the radio device. The radio device sends the resulting analogue value to the DAC pin. Tolerance on this internal voltage is ± 5 % DAC output electrical characteristics are given in the following table. Parameter Limit Units Resolution Bits Output voltage for code = 0 (2.75(6) x 0.05) ± 0.05 Output voltage for code = 255 (2.75(6) x 0.95) ± 0.05 Nominal step size (2.75(6) x 0.9)/256 mV Absolute error(7) ≤ ± 0.5 mV Output wide-band noise and clock feed-through 0 - 1.1 MHz ≤ 0.5 mVrms Power-supply rejection ratio 50 Hz - 10 kHz ≥ 40 dB Conversion rate ± 0.5 LSB ≤ 2 (Load A)(8) ms ≤ 50 (Load B)(8) ms Output buffer impedance when disabled ≥ 50 kΩ Output current source or sink ≥1 mA Current consumption (active) ≤ 1.0 mA (6) Tolerance on this internal voltage is ± 5 % Referred to the ideal conversion characteristic. (8) See Figure 5.11, page 46 (7) DAC 100 - 200pF 100k Load A 1k Load B DGND DAC 10nF 1nF DGND Figure 5.11 DAC loads 46 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 5.16.2 Analogue to Digital Converters 1, 2 and 3 - ADCx The ADC is an 8-bit converter. An analogue value applied to any of the ADC pins is converted and stored in a register inside the radio device. When the appropriate AT command is received by the radio device, the digital value stored in the register is read. ADC electrical characteristics are shown in the table below. Parameter Min. Max. Units Resolution Bits Input voltage for 0000 0000 word 0.01 x 2.75(9) Input voltage for 1111 1111 word 0.99 x 2.75(9) 2.75(9) Differential Non-Linearity (DNL) ± 0.75 LSB Overall Non-Linearity (INL) ± 0.60 LSB Absolute accuracy ± 1.5 LSB Input impedance MΩ Average supply current (continuous conversion) mA External source impedance 50 kΩ (9) Tolerance on this internal voltage is ±5% 5.16.3 Analogue to Digital Converters 4 and 5 - IOx/ADCx To increase analog input capabilities, the GR47 optimises the I/O by multiplexing or sharing different features on single pins. There are two ADC inputs which share system connector pins with digital I/O signals. When configured as digital I/O, the software will not read the voltages at the two new ADC inputs. When configured as ADC inputs the software will configure the digital I/O pins as input or high impedance tri-state. In this state any applied voltage between 0V and 2.75V can be read as an 8 bit value. Because the ADC inputs, ADC4 and ADC5, are common with digital I/O, the input circuit of these Adds is not the same as for the circuits ADC1, ADC2 and ADC3. It is important to understand the input structure of the pin so that the correct analog voltage is read by the application (at position ’A’ in Figure 5.12 below). The input structure is provided in Figure 5.12. It consists of a 100kΩ pull-up to 2.75V followed by a series 10kΩ and 1nF capacitor to ground which make a low pass filter with a 3dB roll-off at about 16kHz. The input impedance of the analog IC is 1MΩ minimum. At position ’A’ in Figure 5.12 below, the input characteristics are the same as for the table above. 47 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE 1RWH If the voltage of the signal to be measured may be altered by the internal circuitry of this shared signal, then the application should use ADC1, ADC2 or ADC3 instead. 2.75V 2.75V 1MΩ 100kΩ 10kΩ ADC 10#/ADC# 1nF Analog IC Figure 5.12 Input circuit for combined digital I/O and ADC pins 5.17 External I 2C Serial Control Bus Pin Signal Dir Description 29 SDA I/O I 2 C serial data 30 SCL I 2 C serial clock The I 2 C bus is controlled by embedded application script commands. The external I 2 C bus consists of two signals, SDA and SCL. This bus is isolated from the radio device’s internal I 2 C bus to ensure proper operation of the radio device, in the event of the external I 2 C bus being damaged. Transmit operation The electrical characteristics are shown below. Parameter Min. Frequency I 2 C CLK 81.25 High or low I 2 C CLK 1.2 Delay time after falling edge of I 2 C CLK 308 Hold time after falling edge of I 2 C CLK Typ. Max. Units 400 kHz µs 3081230 ns ns 48 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE Parameter Min. Typ. Receive operation Frequency I 2 C CLK Max. Units 400 kHz High or low I 2 C CLK 1.2 µs Delay time after falling edge of I 2 C CLK 100 ns Hold time after falling edge of I 2 C CLK ns 5.18 TX_ON - Burst Transmission Pin Signal Dir Description 35 TX_ON GSM radio device to transmit Burst transmission is the time when a GSM transceiver unit is transmitting RF signals. TX_ON indicates the radio device is going into transmission mode. 5.19 Real Time Clock Pin Signal Dir Description 25 VRTC Voltage for the Real Time Clock The Real Time Clock (RTC) provides the main microprocessor with a time-of-day calendar and alarm, and a one-hundred-year calendar. Its accuracy is shown in the table below Parameter Min. Typ. Max. Units RTC accuracy 25°C 8 (21) 20 (52) ppm (s/month) RTC accuracy extreme temperatures 89 (231) 101 (262) ppm (s/month) The Real Time Clock operates in two modes when connected to a separate power supply: • RTC normal mode: the radio device is in ON or OFF mode and it is supplied with power (VCC is applied). • RTC back-up mode: VCC is disconnected and the RTC is maintained by a separate backup power supply connected to the VRTC input (see Figure 5.13 below). Backup power is provided by a capacitor, golden-capacitor or battery in your application and must be connected to the VRTC pin. During RTC normal operation, the back up source will be charged. 49 LZT 123 7589 R1A 5. SYSTEM CONNECTOR INTERFACE In back-up mode, the back-up source must provide enough power for RTC operation. Refer to the table for the amount of current required. The following table shows voltage characteristics for both modes. Parameter Min. Typ. Max. Units Supply Voltage RTC (normal mode charging the capacitor) 1.6 1.8 2.0 Supply Voltage RTC (back-up mode Capacitor provides the current) 1.0 1.8 2.0 5.0 10.0 µA Current drawn If the voltage drops below 1.0 V in back-up mode, the RTC will stop working. The following diagram shows the RTC connections. VRTC Backup supply GR47 DGND Figure 5.13 RTC connections 50 LZT 123 7589 R1A 6. ANTENNA CONNECTOR 6. Antenna Connector The radio device’s antenna connector allows transmission of the radio frequency (RF) signals from the radio device to an external customersupplied antenna. The connector is a micro-miniature coaxial MMCX surface mounted component. A number of suitable MMCX type, mating plugs are available from the following manufacturers; • Amphenol; • Suhner; • IMS Connector Systems. The nominal impedance of the antenna interface is 50Ω. 51 LZT 123 7589 R1A 7. KEYBOARD INTERFACE 7. Keyboard Interface To increase I/O capabilities, the radio device optimises the I/O by multiplexing or sharing different features on single pins. The I/O has been extended to allow simple interfacing of a matrix keypad. 7.1 IO#/KEYROW# When configured for keypad operation the software will configure the digital I/O pins as input or high impedance tri-state. In this state, the keypad matrix row can be read from the KEYROW# inputs. These pins have a 100kΩ pull-up to 2.75V and the rows are considered activated when the voltage is pulled low by the external keypad switches. 7.2 KEYCOL# The keypad matrix column drivers share functionality with the RS232 hardware flow control signals. In addition to the keypad column outputs it is possible to use a direct ground connection as an additional column driver, which is interpreted as column zero. Simply connect one keypad column directly to ground. When a key in this column is depressed KEYROW# is activated. Thus it is possible to create a variety of keypad matrix sizes from single column to five columns wide. Finally, a standard keypad matrix directly connects the rows to the columns whenever a key is depressed. In order to avoid short circuits if multiple keys are pressed simultaneously, the column drivers must be open-collector. This must be achieved with external transistors as the logic drive from the radio device is rail-to-rail. Suitable transistors for this interface are of the type with built in bias resistors between base and emitter. 52 LZT 123 7589 R1A 7. KEYBOARD INTERFACE The method of connection is shown below. KEYROW# GR47 RN1107 KEYCOL# RN1107 RN1107 Figure 7.1 Keyboard matrix connections 1RWH This matrix pattern may be repeated up to 5 columns and 4 rows (one column will use a ground connection as a virtual column driver). Examples of suitable transistors are: Brand Part Number Toshiba RN1107 (as shown) On SEMI DTC114YET1 Philips PDTC114YE ROHM DTC114YETL 53 LZT 123 7589 R1A 8. HINTS FOR INTEGRATING THE RADIO DEVICE 8. Hints for Integrating the Radio Device This chapter gives you advice and helpful hints on how to integrate the radio device into your application from a hardware perspective. Please read and consider the information under the following headings before starting your integration work: • Safety advice and precautions. • Installation of the radio device. • Antenna. 8.1 Safety Advice and Precautions 8.1.1 General • Always ensure that use of the radio device is permitted. The radio device may present a hazard if used in proximity to personal medical electronic devices. As a rule, the radio device must not be used in hospitals, airports or planes. • You are responsible for observing your country’s safety standards, and where applicable the relevant wiring rules. • Never use the radio device at a gas station, refuelling point, blasting area or in any other environment where explosives may be present. • Operating the radio device close to other electronic devices, such as antennas, television sets, and radios may cause electromagnetic interference. • Never try to dismantle the radio device yourself. There are no components inside the radio device that can be serviced by the user. If you attempt to dismantle the radio device, you may invalidate the warranty. • To protect the power supply cables and meet the fire safety requirements, it is recommended that the electrical circuits are supplied with a power regulator. The power regulator should be placed as close to the terminals of the power supply as possible. • Do not connect any incompatible component or product to the radio device. 1RWH Sony Ericsson does not warrant against defects, non-conformities or deviations caused thereby. • The connection/disconnection method for the development board is by means of the DC power jack. For this reason, the mains supply should be situated close to the development board and be easily accessible. 54 LZT 123 7589 R1A 8. HINTS FOR INTEGRATING THE RADIO DEVICE 8.1.2 SIM Card • Before handling the SIM card in your application, ensure that you are not charged with static electricity. Use proper precautions to avoid electrostatic discharges. The radio device must be switched off before the SIM card is installed in your application. • When the SIM card hatch is opened, the SIM card connectors lie exposed under the SIM card holder. CAUTION: Do not touch these connectors! If you do, you may release an electrical discharge that could damage the radio device or the SIM card. • When designing your application, the SIM card’s accessibility should be taken into account. We always recommend that you have the SIM card protected by a PIN code. This will ensure that the SIM card cannot be used by an unauthorized person. 8.1.3 Antenna • If the antenna is to be mounted outside, consider the risk of lightning. Follow the instructions provided by the antenna manufacturer. • Never connect more than one radio device to a single antenna. The radio device can be damaged by radio frequency energy from the transmitter of another radio device. • Like any mobile station, the antenna of the radio device emits radio frequency energy. To avoid EMI (electromagnetic interference), you must determine whether the application itself, or equipment in the application’s proximity, needs further protection against radio emission and the disturbances it might cause. Protection is secured either by shielding the surrounding electronics or by moving the antenna away from the electronics and the external signals cable. • The radio device and antenna may be damaged if either come into contact with ground potentials other than the one in your application. Beware, ground potential are not always what they appear to be. • In the final application, the antenna must be positioned more than 20 cm away from human bodies. When this rule cannot be applied, the application designer is responsible for providing the SAR measurement test report and declaration. • Even if SAR measurements are not required, it is considered good practice to insert a warning in any manual produced, indicating it is a radio product and that care should be taken. 55 LZT 123 7589 R1A 8. HINTS FOR INTEGRATING THE RADIO DEVICE 8.2 Installation of the Radio Device 8.2.1 Where to Install the Radio Device There are several conditions which need to be taken into consideration when designing your application as they might affect the radio device and its function. They are: Environmental Conditions The radio device must be installed so that the environmental conditions stated in the Technical Data chapter, such as temperature, humidity and vibration are satisfied. Additionally, the electrical specifications in the Technical Data section must not be exceeded. Signal Strength The radio device has to be placed in a way that ensures sufficient signal strength. To improve signal strength, the antenna can be moved to another position. Signal strength may depend on how close the radio device is to a radio base station. You must ensure that the location at which you intend to use the radio device, is within the network coverage area. Degradation in signal strength can be the result of a disturbance from another source, for example an electronic device in the immediate vicinity. More information about possible communication disturbances can be found in section 8.3.5, page 59. When an application is completed, you can verify signal strength by issuing the AT command AT+CSQ. See the AT Commands Manual for further details. 7LS Before installing the radio device, use an ordinary mobile telephone to check a possible location for it. In determining the location for the radio device and antenna, you should consider signal strength as well as cable length Connection of Components to Radio Device The integrator is responsible for the final integrated system. Incorrectly designed or installed, external components may cause radiation limits to be exceeded. For instance, improperly made connections or improperly installed antennas can disturb the network and lead to malfunctions in the radio device or equipment. Network and Subscription • Before your application is used, you must ensure that your chosen network provides the necessary telecommunication services. Contact your service provider to obtain the necessary information. 56 LZT 123 7589 R1A 8. HINTS FOR INTEGRATING THE RADIO DEVICE • If you intend to use SMS in the application, ensure this is included in your (voice) subscription. • Consider the choice of the supplementary services described in section 2.3.2 Short Message Service, page 10. 8.2.2 How to Install the Radio Device Power Supply • Use a high-quality power supply cable with low resistance. This ensures that the voltages at the connector pins are within the allowed range, even during the maximum peak current. An electrolytic capacitor should be placed close to the power supply pins of the radio device to supply the peak currents during burst transmission. See 5.4 VCC Regulated Power Supply Input, page 23. • See section 5.2.1 General Protection Requirements, page 22. Grounds A ground connection is provided at the mounting hole next to the RF connector on the radio device (see Figure 5.1, page 19). Connect this ground point to the DGND pins of the radio device by the shortest, lowimpedance path possible. The purpose of this connection is to allow any ESD picked up by the antenna to bypass the radio device’s internal ground path. 1RWH It is recommended that you use a cable with a maximum resistance of 5 mΩ for the ground connection. 1RWH AGND and DGND are connected at a single point inside the radio device. They must not be joined together in your application. Audio Use a coupling capacitor in ATMS line if the application does not use the radio device’s bias voltage. See also Figure 5.5 Microphone connections to the radio device, page 31. Software Upgrade To upgrade the software, the system connector must be accessible in your application. The pins SERVICE, TD2, RD2 and the power signals are used for this purpose. Please contact customer support for more details. 57 LZT 123 7589 R1A 8. HINTS FOR INTEGRATING THE RADIO DEVICE 8.3 Antenna 8.3.1 General The antenna is the component in your system that maintains the radio link between the network and the radio device. Since the antenna transmits and receives electromagnetic energy, its efficient function will depend on: • the type of antenna (for example, circular or directional); • the placement of the antenna; • communication disturbances in the vicinity in which the antenna operates. In the sections below, issues concerning antenna type, antenna placement, antenna cable, and possible communication disturbances are addressed. In any event, you should contact your local antenna manufacturer for additional information concerning antenna type, cables, connectors, antenna placement, and the surrounding area. You should also determine whether the antenna needs to be grounded or not. Your local antenna manufacturer might be able to design a special antenna suitable for your the application. 8.3.2 Antenna Type Make sure that you choose the right type of antenna for the radio device. Consider the following requirements: • the antenna must be designed for the dual frequency bands in use: E-GSM900/GSM1800 for the GR47 and GSM 850/GSM1900 for the GR48; • the impedance of the antenna and antenna cable must be 50 Ω; • the antenna output-power handling must be a minimum of 2 W; • the VSWR value should be less than 3:1 to avoid damage to the radio device. 8.3.3 Antenna Placement The antenna should be placed away from electronic devices or other antennas. The recommended minimum distance between adjacent antennas, operating in a similar radio frequency band, is at least 50 cm. If signal strength is weak, it is useful to face a directional antenna at the closest radio base station. This can increase the strength of the signal received by the radio device. The radio device’s peak output power can reach 2 W. RF field strength varies with antenna type and distance. At 10 cm from the antenna the field strength may be up to 70 V/m and at 1m it will have reduced to 7 V/m. 58 LZT 123 7589 R1A 8. HINTS FOR INTEGRATING THE RADIO DEVICE In general, CE-marked products for residential and commercial areas, and light industry can withstand a minimum of 3 V/m. 8.3.4 The Antenna Cable Use 50 Ω impedance low-loss cable and high-quality 50 Ω impedance connectors (frequency range up to 2 GHz) to avoid RF losses. Ensure that the antenna cable is as short as possible. The Voltage Standing-Wave Ratio (VSWR) may depend on the effectiveness of the antenna, cable and connectors. In addition, if you use an adapter between the antenna cable and the antenna connector, it is crucial that the antenna cable is a high-quality, low-loss cable. Minimize the use of extension cables, connectors and adapters. Each additional cable, connector or adapter causes a loss of signal power. 8.3.5 Possible Communication Disturbances Possible communication disturbances include the following: • Noise can be caused by electronic devices and radio transmitters. • Path-loss occurs as the strength of the received signal steadily decreases in proportion to the distance from the transmitter. • Shadowing is a form of environmental attenuation of radio signals caused by hills, buildings, trees or even vehicles. This can be a particular problem inside buildings, especially if the walls are thick and reinforced. • Multi-path fading is a sudden decrease or increase in the signal strength. This is the result of interference caused when direct and reflected signals reach the antenna simultaneously. Surfaces such as buildings, streets, vehicles, etc., can reflect signals. • Hand-over occurs as you move from one cell to another in the GSM network. Your mobile application call is transferred from one cell to the next. Hand-over can briefly interfere with communication and may cause a delay, or at worst, a disruption. 59 LZT 123 7589 R1A 9. EMBEDDED APPLICATIONS 9. Embedded Applications The radio device has the capability to store and run customer written code in the form of a script during the processor’s idle time, through the use of an on board interpreter. 9.1 Features Main features of embedded applications are as follows. • C based scripting language (Sony Ericsson specific); • Over the air upgrade of scripts (NOT GSM software); • Library of intrinsic functions; • 2 scripts can be stored in the memory at any time but only 1 can be active. 9.2 Implementation The radio device has up to 44k of space available for storage of two scripts in the scripting language and 25k of operating RAM. Structures included in this language are: • If - then - else statements • While loops • For loops All hardware interfaces that are normally available to the radio device through the AT commands are available to the embedded application. Further drivers have been written such as M bus, keypad, SPI and I2C for use by the embedded application (EA) through the use of the I/O pins. 9.2.1 Limitations Since the radio device is processing the script using its own memory, limitations are placed onto the scripts that are run. • A direct comparison cannot be made to a fully compiled C program in terms of size but a gauge of script size is that if each line were 128 characters long in the script then the script could be 350 lines long. • Processing power is something that needs to be considered as the script is run as a low priority process within the software. However, controller mode stops GSM operation and provides all the processing power for the script to be run. See the M2mpower Application Guide for more details. • Code cannot be ported directly from an existing application and loaded directly onto the radio device. It must be re written in the Sony Ericsson Mobile script language so that the radio device interpreter can function correctly. 60 LZT 123 7589 R1A 9. EMBEDDED APPLICATIONS 9.2.2 M2mpower IDE (Integrated Development Environment) The IDE is a Windows based package which allows the user to write, simulate, debug and download the application into a radio device with the embedded application (EA) software. The standard version is designed to run on Windows XP and 2000, other versions are available for 98 if required. The M2mpower Application Guide is available for implementing applications using the developer’s kit and the embedded application (EA) functionality. This is a required package to be able to implement an embedded application (EA). For further information please contact Sony Ericsson Mobile Communications customer support. 61 LZT 123 7589 R1A 10. TCP/IP STACK 10. TCP/IP Stack An on board IP/TCP/UDP stack has been integrated into the software negating the need for the customer to implement one in their own code base. This is only accessible by using an embedded applications (see section 9) using intrinsic functions. 10.1 Implementation The following types of commands allow various functions: • Open/closing IP connection - Negotiates/closes a dynamic IP address with the web server. • Send/Receive TCP packets - Performs all TCP operations to send and receive packets. • Send/Receive UDP packets - Performs all UDP operations to send and receive packets. • Resolve URL to an IP address - Similar to nslookup command in DOS When the unit is set up and controlled using the embedded applications either the embedded applications or an external application can generate data to be sent and pass it to the radio device for transmission. This effectively provides a transparent communication link from the application to an internet server over GPRS. 62 LZT 123 7589 R1A 11. TECHNICAL DATA 11. Technical Data Mechanical Specifications Maximum length 50 mm Maximum width 33 mm Maximum thickness 6.82 mm(excluding connector pins and top of antenna connector) Weight 18.5 g Power supply voltage, normal operation Voltage 3.6 V nominal (3.4 V - 4.0 V) Ripple < 100 mV @ <200 kHz; < 20 mV @ > 200 kHz Voltage must always stay within a normal operating range, ripple included Power consumption Voice/CSD: < 250 mA (< 2 A peak) Data (GPRS 4+1); < 350 mA (< 2 A peak) Idle mode: < 5 mA Switched off: < 100 µA Radio specifications Frequency range GR47: E-GSM 900 MHz and GSM 1800 MHz (dual band) GR48: GSM 850 MHz and GSM 1900 MHz (dual band) Maximum RF output power GR47: 900 MHz, Class 4, 2 W; 1800 MHz Class 1, 1 W Antenna impedance 50 Ω GR48: 850 MHz, Class 4, 2W; 1900 MHz Class 1, 1 W SIM card 3 V or 5 V Support of external SIM card 63 LZT 123 7589 R1A 11. TECHNICAL DATA Environmental specifications Operating temperature range (full specification) -10 °C to +55 °C Operating temperature range (working) -30 °C to +75 °C Storage temperature range -40 °C to +85 °C Maximum relative humidity 95 % at +40 °C Stationary vibration, sinusoidal Displacement: 7.5 mm Acceleration amplitude: 20 m/s² and 40 m/s² Frequency range: 2-8 Hz, 8-200 Hz, 200-500 Hz Stationary vibration, random Acceleration spectral density (m²/s²): 0.96, 2.88, 0.96 Frequency range: 5-10 Hz, 10-200 Hz, 200-500 Hz, 60 min/axis Non-stationary vibration, including shock Shock response spectrum I, peak acceleration: 3 shocks in each axis and direction; 300 m/s², 11 ms Shock response spectrum II, peak acceleration: 3 shocks in each axis and direction; 1000 m/s², 6 ms Bump Acceleration: 250 m/s² Free fall transportation 1.2 m Rolling pitching transportation Angle: ±35 degrees; period: 8 s Static load 10 kPa Low air pressure/high air pressure 70 kPa/106 kPa Data Storage SMS storage capacity 40 in ME In addition, the unit can handle as many SMS as the SIM can store Phone book capacity 100 64 LZT 123 7589 R1A 12. DECLARATION OF CONFORMITY 12. Declaration of Conformity 65 LZT 123 7589 R1A Developer’s Kit Product Photo/Illustration 13. Introduction to the Developer’s Kit The developer’s kit for the radio devices is designed to get you started quickly. It contains all the hardware you will need to begin the development of an application. The only items you need to provide are; a computer, a SIM card and network subscription, and a knowledge of programming with AT commands. 1RWH Before connecting up and using the developer’s kit, we strongly recommend you read “Integrating the Radio Device”, page 16 and all of this section. There are many switches, jumpers and connector options in the developer’s kit. A knowledge of the functionality of the radio device is therefore essential before you start altering the hardware settings. The main hardware in the developer’s kit is a box, containing a board onto which you plug the radio device. Connectors, switches, jumpers and SIM card holder are provided to allow you to configure and access all the functions of the radio device. 13.1 Contents of the Kit Please take the time to check the contents of your kit against the list shown below. If any of the items are missing contact your supplier immediately. Developer’s kit - Part Number DPY 102 225 Description Product Number Radio Device: GR47 or GR48 DPY 102 220 DPY 102 222 GR47/GR48 developer’s kit (box and development board) KRY 101 1919 Switched mode PSU 12 V d.c. BML 161 1014 UK mains plug KRY 111 087 European mains plug KRY 111 086 USA mains plug KRY 111 088 9 pin serial connector cable RPM 113 7796 Headset RLF 501 40 Quad band antenna KRE 101 1970 Data carrier/CD-ROM containing: Software Manual; Integrator’s Manual LZY 214 2583 DRAFT LZT 123 7589 R1A Qty 67 13. INTRODUCTION TO THE DEVELOPER’S KIT 13.2 General Functioning of the Kit The following block diagrams are provided to help you understand the general principles of operation of the developer’s kit. You can use the kit’s connectors to access and control the radio device (all switches and jumpers in their default positions). Figure 13.1 shows the various on-board voltages and how they are fed to the radio device and other circuitry. The developer’s board is powered by an external power supply connected to Vcc, see below. The power to the developer’s board circurity is selectable from internal or external 3V6 source. To Development board and interface circuits INT EXT VIO LED VIO External 3.6V GR47 or GR48 VCC Switch 5V? 32V DC Jack 3V6 Reg n/c VCC DGND Figure 13.1 Power supply connection and the on-board voltages 68 LZT 123 7589 R1A 13. INTRODUCTION TO THE DEVELOPER’S KIT Figure 13.2, Figure 13.3 and Figure 13.4 show how various signals are routed on the developer’s board. Thicker lines indicate multiple signals. X3 X2 3V6 VIO On/Off On/Off & PSU Control GPIO X1 Status LED LED DAC / ADC 1 - 5 I2C I2C GPIO TX_ON SIM SIM Header VRTC SIM Figure 13.2 Miscellaneous signals, connection and routing ATMS MIC 3.5mm socket AFMS EAR 3.5mm socket X1 MICN, MICP, BEARN, BEARP Handset RJ9 connector BUZZER PCM Buzzer PCM 6 pin header Figure 13.3 Audio signals, connection and routing 69 LZT 123 7589 R1A 13. INTRODUCTION TO THE DEVELOPER’S KIT X3 X2 DSR, RI, DTR, CTS, RTS, DCD X1 UART1 Flow Control TD, RD TD2, RD2 UART TD3, RD3 SERVICE SERVICE LED Figure 13.4 Comms signals, connection and routing 70 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14. Using the Developer’s Kit This section provides you with the information needed to setup and use the developer’s kit. Before changing switch and jumper settings, refer to “14.3 Jumpers”, page 74. Front and rear views of the developer’s kit are shown below. Use a flat blade screwdriver to unhinge the side clips of the kit and lift the plastic lid off to access the inside. S o ny E r ic s s o n er 48 D ev el op G R 47 / G R 's K it EXT VCC RF Figure 14.1 Front view 5 - 32V DC VCC EXT N/C INT On Off Status VIO UART MIC EAR HANDSET Figure 14.2 Rear view 71 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14.1 Start up Check List To use the developer’s kit in standard format check the following: • With the case lid removed, make sure the radio device is plugged into X1 and the RF lead is connected to the MMCX socket of the radio device; • Add your SIM card; • Check the jumpers are in their default positions. Refer to Figure 14.3; • Connect the serial cable between your computer and the UART connector on the rear panel; • Connect the antenna to the RF connector on the front panel; • Connect the audio equipment if required; • Plug the external power supply into the socket marked 5-32V DC on the rear panel; • Switch Vcc to INT; • Push ON/OFF for at least 2 seconds until the yellow VIO LED is on. Your developer’s kit should now be operational and ready to receive AT commands. 72 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14.2 Developer’s Board Overlay D21 Figure 14.3 shows the developer’s board, including the position of all the connectors, switches and jumpers (default positions). X8 X6 SHDN ATMS GND WAKE RD2 RD3 3V6 U8 BAUD PCM ULD DIS PORT SRVC U1 C15 IN SYN CLK SHDN BUZZER OUT TO_IN DLD VRTC X5 X9 SW1 SW2 TD2 TD3 CHG GND EXT X4 U4 INT EXT X7 U7 A0 A1 A2 LS1 X2 40 X3 39 40 C0 R1 C1 R2 C2 R3 C3 R4 P1 P2 P3 P4 P5 P6 P7 U5 SonyEricsson P0 SERIAL NUMBER TD DCD RTS CTS DTR RI LED DATA 39 INT SCL PR# GND VPP DAT RST CLK DSR SIM VCC GND C4 Figure 14.3 Developer’s board overlay 73 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14.3 Jumpers All jumpers are located on the developer’s board (see “Developer’s board overlay”, page 73). 3RZHUDQG&RQWURO Jumper Default Description INT/EXT INT Selects which voltage path supplies the DK support circuitry (not the supply to the radio device). INT selects power from the internal +3.6V DC supply. EXT selects power from the EXT VCC connector. TO_IN With jumper TO_IN fitted, the DK and the radio device will automatically power-up as soon as power is applied to DC Jack X9. SHDN With jumper SHDN fitted, the internal +3.6V power supply will be disabled. Note: There is a second jumper labelled ’SHDN’ which is in the UART area (by X4). VRTC Fitted This jumper connects the DK real-time-clock backup capacitor to the VRTC pin of the radio device. 8$57 Jumper Default Description SRVC When fitted, the module will be operated in ’Service’ mode enabling system-status logging from the radio device.The red ‘Service’ LED will be illuminated. PORT When fitted, switches the serial port from the 'AT' command port UART1 to UART2/UART3. Note: Use the PORT jumper link in conjunction with links “TD2/TD3” and “RD2/RD3” to select between UART2/UART3. TD2/TD3 This dual jumper selects the TD (Transmit Data) line for either UART2 or UART3 as the alternative serial port when jumper 'PORT' is fitted. The jumper connects TD2 or TD3 to the centre pin to make the selection. See “Connectors”, page 80 for more details. Note: When UART2 or UART3 is used via the application connector, the TD2 or TD3 jumper must be removed to avoid circuit conflicts within the DK. RD2/RD3 This dual jumper selects the RD (Receive Data) line for either UART2 or UART3 as the alternative serial port when jumper 'PORT' is fitted. The jumper connects RD2 or RD3 to the centre pin to make the selection. See “Connectors”, page 80 for more details. Note: When UART2 or UART3 is used via the application connector, the RD2 or RD3 jumper must be removed to avoid circuit conflicts within the DK. 74 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT Jumper Default Description DIS When fitted, the serial port driver IC disables the receiver buffers that normally drive UART signals into the radio device. This will prevent the radio device from receiving data through the serial port. WAKE When fitted, the radio device will automatically power-up when the UART DTR signal is driven high. This allows a convenient mechanism for an external host computer to switch on the module. The DTR signal must be driven low or negative before the module can be switched off under software command. Note: If DTR is not driven low or negative and the host computer commands the module to shut-down, the DTR signal in its high state will immediately indicate that the module is to switch back on. BAUD When fitted, this jumper allows the serial port driver IC to operate at baud rates in excess of 250 kbps and up to 1 Mbps. Note: There will be an increase in current consumption with this option selected. SHDN When fitted, the serial port IC is forced into a low power state with the internal transmitters disabled. In the shut-down state the radio device will still receive commands but any transmission attempts from the radio device will be blocked by the serial port IC. Notes: In the shut-down state all the hardware flow control transmitters will be switched off. In order to send commands to the radio device in this state, the host computer must also have hardware flow control switched off. There is a second jumper labelled ’SHDN’ which is in the Power Supply area (adjacent to U7). 75 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT $XGLRDQG3&0 Jumper Default Description ULD To OUT To enable analog audio microphone path ULD must be connected to OUT using the jumper. OUT To ULD To enable analog audio microphone path OUT must be connected to ULD using the jumper. DLD To IN To enable analog audio earpiece path DLD must be connected to IN using the jumper. In To DLD To enable analog audio earpiece path IN must be connected to DLD using the jumper. SYN This is an output connection for the PCM synchronisation signal from the radio device. CLK This is an output connection for the PCM clock signal from the radio device. BUZZER Fitted When fitted, this link enables the DK buzzer driver circuitry. Jumper Default Description DSR Fitted Connects serial port flow control signal DSR between UART connector X4 and radio device. Note: DSR is a dual function signal from the radio device. When this signal is being used for any other purpose (e.g. Keypad or application specific through X2 or X3), this jumper must be removed. RI Fitted Connects serial port control signal RI between UART connector X4 and radio device. Note: RI is a dual function signal from the radio device. When this signal is being used for any other purpose (e.g. Keypad or application specific through X2 or X3), this jumper must be removed. DTR Fitted Connects serial port flow control signal DTR between UART connector X4 and radio device. Note: DTR is a dual function signal from the radio device. When this signal is being used for any other purpose (e.g. Keypad or application specific through X2 or X3), this jumper must be removed. CTS Fitted Connects serial port flow control signal CTS between UART connector X4 and radio device. Note: CTS is a dual function signal from the radio device. When this signal is being used for any other purpose (e.g. Keypad or application specific through X2 or X3), this jumper must be removed. RTS Fitted Connects serial port flow control signal RTS between UART connector X4 and radio device. Note: RTS is a dual function signal from the radio device. When this signal is being used for any other purpose (e.g. application specific I/O through X2 or X3), this jumper must be removed. 0LVFHOODQHRXV 76 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT DCD Fitted Connects serial port control signal DCD between UART connector X4 and radio device. Note: DCD is a dual function signal from the radio device. When this signal is being used for any other purpose (e.g. Keypad or application specific through X2 or X3), this jumper must be removed. TD Fitted Connects serial port Transmit Data signal TD between UART connector X4 and radio device. Note: It is only valid to have one Transmit Data buffer in the circuit. If TD is driven by the application through connector X2 or X3, this jumper must be removed to avoid circuit conflicts. LED Fitted When fitted, this enables the STATUS LED to be illuminated by signal LED from the radio device. Note: LED is a dual function signal in the radio device. When this signal is being used for any other purpose (e.g. application specific I/O through X2 or X3), it is recommended that this jumper is removed to avoid circuit conflicts or unexpected circuit behavior. SCL When fitted, connects the I2C clock signal from the radio device to the GPIO interface IC, U5. Note: Use the address selectors A0-A2 to set GPIO interface I2C address. Ensure that the selected address is unique to all I2C devices using SCL and SDA from radio device. DATA When fitted, connects the I2C data signal from the radio device to the GPIO interface IC, U5. Note: Use the address selectors A0-A2 to set GPIO interface I2C address. Ensure that the selected address is unique to all I2C devices using SCL and SDA from radio device. A0 When fitted, connects address pin A0 of IC U5 to logic high. When the jumper is not fitted, address A0 is held to logic low by the DK. Note: IC U5 address range is 0x70 to 0x7F. A1 When fitted, connects address pin A1 of IC U5 to logic high. When the jumper is not fitted, address A1 is held to logic low by the DK. Note: IC U5 address range is 0x70 to 0x7F. A2 When fitted, connects address pin A2 of IC U5 to logic high. When the jumper is not fitted, address A2 is held to logic low by the DK. Note: IC U5 address range is 0x70 to 0x7F. 77 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14.4 Switches All switches are mounted on the front panel of the developer’s box. Switch Default Description Vcc (SW1) N/C This switch chooses the voltage source that the radio device will use. The default state N/C makes the voltage path to the radio device open circuit. Choosing INT connects the internal +3.6V DC supply to the VCC pins of the radio device. Choosing EXT connects the external +3.6V DC supply to the VCC pins of the radio device. Note: The external +3.6V DC supply is a user provided source through the EXT VCC connector. ON/OFF (SW2) This is a momentary push-button switch to enable the user to manually turn the module on and off. The radio device is turned on by pressing and holding the ON/OFF switch for at least 1 second before releasing.The radio device is turned off by pressing and holding the ON/OFF switch for at least 2 second before releasing. The module will detect the OFF request and the software will perform all the necessary shutdown tasks (e.g. SIM power management and network detach) before the VIO LED is extinguished. Note: In the event of the radio device locking up and being unrecoverable under software control, the ON/ OFF switch provides an alternative HARD SHUTDOWN control. To initiate the HARD SHUTDOWN feature press and hold the ON/OFF switch for at least 10 seconds or until the module powers down and VIO LED is no longer illuminated. 78 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14.5 Headers Header Connections Description PCM ULD, DLD, OUT, IN, SYN, CLK Carries digital audio PCM signals for access by user application. Note: In order for analog audio to be created internally by the radio device, signal ULD must be connected to OUT for the MIC path and signal DLD must be connected to IN for the EAR path. SIM VCC, RST, CLK, VPP, DAT, PR#, GND This connector allows access to the SIM interface signals. These test points are connected in parallel with SIM connector ’X5’. Note: If this header is used to attach to an external SIM, an internal SIM fitted into connector ’X5’ must be removed. KEYPAD C0, C1, C2, C3, C4, R1, R2, R3, R4 This header provides all the connections required to connect to a standard 20 key (5 columns x 4 rows) keypad matrix. ’C#’ are output drivers to connect to keypad columns. ’R#’ are input receivers to connect to keypad rows. Note: C0 is a virtual keypad column driver and is simply a connection to ground. C0 therefore does not appear on the radio device as a keypad driver output. The keypad interface recognises when the rows (R1-R4) are connected logic ’low’. If this is registered while the columns (C1-C4) are idle then it is accepted that the ’active’ column is C0 (column zero). I2C GPIO P0, P1, P2, P3, P4, P5, P6, P7, INT This header provides a general purpose I/O port from the I2C to GPIO interface. P0-P7 are the 8 bits of the data port. INT is the interrupt output of the interface. The interface IC which drives these signals is part number PCF8574AT from Philips Semiconductor. ATMS ATMS In addition to being able to feed in a microphone signal from an alternative source, this pin can be used to answer an incoming telephone call. By momentarily connecting this signal to GND when an incoming call is ’ringing’, the radio device will ’answer’ the call. GND GND These two headers can be used as the signal reference ground for test and measurement. 79 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14.6 Connectors Connector Type Description RADIO DEVICE ‘X1’ 60 PinDual Row0.05” pitch The radio device is 'plugged-in' to the development kit. This allows direct connection of the module to the development board. APPLICATION ‘X2’ 40 PinDual Row0.1” pitch This 40-pin connector is compatible with standard 0.1" pitch mating connectors and with 0.05" pitch IDC ribbon cable connectors. This allows the user a range of connection methods to interface to the application. This connector is wired in parallel with application connector 'X3', which can be used for test probing or to wire patch alternative signals into the four 'N/C' pins. APPLICATION ’X3’ 40 PinDual Row0.1” pitch This 40-pin connector is compatible with standard 0.1" pitch mating connectors and with 0.05" pitch IDC ribbon cable connectors. This allows the user a range of connection methods to interface to the application. This connector is wired in parallel with application connector 'X2', which can be used for test probing or to wire patch alternative signals into the four 'N/C' pins. UART 'X4’ 9-pin D Female Socket This is a full 9-pin RS232 compatible communication port. Using jumpers on the DK, this connector may be used for UART1, UART2 or UART3 of the radio device. Note: UART2 and UART3 of the radio DCD device are DSR considered 3-wire RD interface only. The RTS hardware flow and TD CTS other control DTR signals which are RI passed through this connector are only relevant when used with UART1. SIM 'X5’ Latch and lift style holder with integral SIM detect contact This is a standard holder for a GSM SIM card. The top piece slides towards “Open” and then lifts to release or insert the SIM card using the integral guide rails. To close, lower the pivoting top piece flush with the bottom piece and slide the top towards “Lock”. 80 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT Connector Type Description Handset ‘X6’ RJ9 socket Connector for a standard telephone handset. Carries signals from the balanced outputs BEARN and BEARP and to the balanced inputs MICN and MICP. To enable an analog audio link it is necessary to link PCM signals “ULD to OUT” and “DLD to IN” using jumper links on the PCM header. Note: The PCM links to enable analog audio are fitted by default but may have been removed during customer development. There will be no analog audio without these links. Please check carefully. EAR 'X7' 3.5mm Stereo JackSocket This is a standard unbalanced audio output (AFMS) which is compatible with a standard PC-style stereo headset. Note: This MONO audio signal is fed to both left and right channels of the stereo connector. To enable this analog audio link it is necessary to link PCM signal DLD to signal IN using a jumper link on the PCM header. Note: The PCM links to enable analog audio are fitted by default but may have been removed during customer development. There will be no analog audio without these links. Please check carefully. ear 1234 ground MIC 'X8' 3.5mm Stereo JackSocket This is a standard unbalanced audio input (ATMS) which is compatible with a standard PC-style microphone. Note: Microphone bias voltage is provided through this connector in the range 2.0VDC to 2.5VDC.To enable this analog audio link it is necessary to link PCM signal ULD to signal IN using a jumper link on the PCM header. Note: The PCM links to enable analog audio are fitted by default but may have been removed during customer development. There will be no analog audio without these links. Please check carefully. mic ground 5 - 32V DC 'X9' 2.1mm DC Jack Socket ear mic Allows connection of an external power supply in the voltage range +5.0VDC to +32.0VDC at 4 Watts. 81 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT Connector Type Description EXT VCC 3 pin Circular This connector carries three signals: EXT VCC (1); CHG_IN (3); GND (2). (These signals are wired into PCB holes labelled EXT, CHG, GND respectively).EXT VCC must be a +3.6VDC source capable of supplying up to 2.0A. This can be a battery source.CHG_IN can be a +5.0VDC source capable of supplying 600mA maximum.GND is the ground reference to be used by the external supplies. Note: If battery charging is enabled the charging source must be capable of supplying the required charging current but the charging current must not exceed 500mA. RF SMA Panel Socket Connect the supplied antenna. 14.7 LED Indicators LED (Colour) Location Description Status (Green) Front Panel This LED is enabled by fitting the “LED” jumper link (located between the internal power supply and the keypad header).The LED is driven on by a signal from the radio device pin 33 (LED/IO6).When the radio device connection “LED/IO6” is configured as the LED driver this LED signifies the module and network status as follows; ON - Module cannot connect to a network. FLASHING - MODULE has SIM fitted and is locked onto a valid GSM network. VIO (Yellow) Front Panel This LED is illuminated when the radio device is switched on. The module outputs +2.75VDC on signal VIO (pin 34). SRVC (Red) PCB When the SRVC jumper link is fitted and the DK has +3.6VDC power, this LED illuminates to indicate that SERVICE mode is activated. 3V6 (Green) PCB When the DK has +3.6VDC power, this LED will illuminate. Note: The DK +3.6V and the radio device VCC inputs are connected through switch VCC (SW1) on the front panel. The 3V6 LED does NOT indicate that the module has power applied to its VCC connections. 82 LZT 123 7589 R1A 14. USING THE DEVELOPER’S KIT 14.8 System Connector Pin Assignments Refer to the table below when monitoring signals on, or connecting to, X1. The table shows the system-connector pin assignments for the radio devices. See “System Connector Interface”, page 19for more details. VCC DGND VCC DGND VCC DGND VCC DGND VCC DGND 10 11 CHG_IN DGND 12 13 IO5/ADC4 ON/OFF 14 15 SIMVCC SIMPRESENCE 16 17 SIMRST SIMDAT 18 19 SIMCLK DAC 20 21 IO1/KEYROW2 IO2/ADC5 22 23 IO3/KEYROW3 IO4/KEYROW4 24 25 VRTC ADC1 26 27 ADC2 ADC3 28 29 SDA SCL 30 31 BUZZER DSR/O3/KEYCOL3 32 33 LED/IO6 VIO 34 35 TX_ON RI/O2/KEYCOL2 36 37 DTR/IN1/KEYROW1 DCD/O1/KEYCOL1 38 39 RTS/IO9 CTS/O4/KEYCOL4 40 41 TD RD 42 43 TD3/IO7 RD3/IO8 44 45 TD2 RD2 46 47 PCMULD PCMDLD 48 49 PCMOUT PCMIN 50 51 PCMSYNC PCMCLK 52 53 MICP MICN 54 55 BEARP BEARN 56 57 AFMS SERVICE 58 59 ATMS AGND 60 Figure 14.4 System connector pin assignments 83 LZT 123 7589 R1A D21 14. USING THE DEVELOPER’S KIT INT EXT U8 ULD DLD OUT IN SYN CLK 60 PCM X5 59 +3.6V internal power supply BUZZER SIM CHG GND EXT SW2 UART X9 SW1 Audio A0 A1 A2 Buzzer GND PR# DAT GND RST CLK VPP VCC 39 TD DCD RTS CTS DTR RI LED DSR SIM INT X2 X3 Application interface Keypad interface C2 R3 C3 R4 C4 P0 P1 P2 P3 I2C to GPIO X1 pin numbering viewed from the front of the developer's kit. Figure 14.5 Pin Orientation and Board assignments VCC DGND ON/OFF HR_IN IO1 / KEYROW2 IO3 / KEYROW3 VIO IO5 / ADC4 ADC2 DAC LED / IO6 SDA DGND RX RTS / IO9 DSR / KEYCOL3 / OUT3 DCD / KEYCOL1 / OUT1 TX2 TX3 n/c 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 VCC DGND TO IN n/c IO2 / ADC5 IO4 / KEYROW4 DGND ADC1 ADC3 DGND TXON SCL n/c TX CTS / KEYCOL4 / OUT4 RI / KEYCOL2 / OUT2 DTR / KEYROW1 RX2 RX3 n/c Figure 14.6 Application Interface Connector (X2 and X3) - Pin Assignment 84 LZT 123 7589 R1A
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