THALES DIS AlS Deutschland MC45 Transmitter Module for mobile applications User Manual MC45
Gemalto M2M GmbH Transmitter Module for mobile applications MC45
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![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 9 of 90 12.08.2002 1 Introduction This document describes the hardware interface of the Siemens MC45 module that connects to the cellular device application and the air interface. As MC45 is intended to integrate with a wide range of application platforms, all functional components are described in great detail. So this guide covers all information you need to design and set up cellular applications incorporating the MC45 module. It helps you quickly retrieve interface specifications, electrical and mechanical details and, last but not least, information on the requirements to be considered for integrating further components. 1.1 Related documents [1] MC45 AT Command Set for Version 00.02 [2] MC45 GPRS Startup User's Guide (in preparation) [3] MC45 Remote-SAT User's Guide, as of Version 00.02 (in preparation) [4] DSB45 Support Box - Evaluation Kit for Siemens Cellular Engines [5] Application Note 16: Upgrading MC45 Firmware (in preparation) [6] Application Note 14: Audio and Battery Parameter Download [7] MC45 Multiplexer User's Guide, as of Version 00.02 (in preparation) Prior to using the MC45 engines be sure to carefully read and understand the latest product information provided in the Release Notes (not available for release 00.02.) To visit the Siemens Website you can use the following link: http://www.siemens.com/wm](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-9.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 28 of 90 12.08.2002 3.2.3.1 Battery pack characteristics The charging algorithm has been optimized for a Li-Ion battery pack that meets the characteristics listed below. It is recommended that the battery pack you want to integrate into your MC45 application is compliant with these specifications. This ensures reliable operation, proper charging and, particularly, allows you to monitor the battery capacity using the AT^SBC command (see [1] for details). Failure to comply with these specifications might cause AT^SBC to deliver incorrect battery capacity values. A battery pack especially designed to operate with MC45 modules is specified in Chapter 3.2.3.2. · Li-Ion battery pack specified for a maximum charging voltage of 4.2 V and a capacity of 800 mAh. Battery packs with a capacity down to 600 mAh or more than 800 mAh are allowed, too. · Since charging and discharging largely depend on the battery temperature, the battery pack should include an NTC resistor. If the NTC is not inside the battery it must be in thermal contact with the battery. The NTC resistor must be connected between BATT_TEMP and GND. Required NTC characteristics are: 10 kΩ +5% @ 25°C, B25/85 = 3435K +3% (alternatively acceptable: 10 kΩ +2% @ 25°C, B25/50 = 3370K +3%). Please note that the NTC is indispensable for proper charging, i.e. the charging process will not start if no NTC is present. · Ensure that the pack incorporates a protection circuit capable of detecting overvoltage (protection against overcharging), undervoltage (protection against deep discharging) and overcurrent. The circuit must be insensitive to pulsed current. · On the MC45 module, a built-in measuring circuit constantly monitors the supply voltage. In the event of undervoltage, it causes MC45 to power down. Undervoltage thresholds are specific to the battery pack and must be evaluated for the intended model. When you evaluate undervoltage thresholds, consider both the current consumption of MC45 and of the application circuit. · The internal resistance of the battery and the protection should be as low as possible. It is recommended not to exceed 150m", even in extreme conditions at low temperature. The battery cell must be insensitive to rupture, fire and gasing under extreme conditions of temperature and charging (voltage, current). · The battery pack must be protected from reverse pole connection. For example, the casing should be designed to prevent the user from mounting the battery in reverse orientation. · The battery pack must be approved to satisfy the requirements of CE conformity. Figure 4 shows the circuit diagram of a typical battery pack design that includes the protection elements described above. Figure 4: Battery pack circuit diagram to BATT_TEMP to GNDNTCPolyfuseJProtection Circuit+-Battery cellto BATT+](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-28.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 33 of 90 12.08.2002 3.3 Power up / down scenarios 3.3.1 Turn on MC45 MC45 can be activated in a variety of ways, which are described in the following chapters: · via ignition line /IGT: starts normal operating state (see Chapters 3.3.1.1 and 3.3.1.2) · via POWER line: starts charging algorithm (see Chapters 3.2.3.4 and 3.3.1.3) · via RTC interrupt: starts Alarm mode (see Chapter 3.3.1.4) 3.3.1.1 Turn on MC45 using the ignition line /IGT (Power on) To switch on MC45 the /IGT (Ignition) signal needs to be driven to ground level for at least 100ms. This can be accomplished using an open drain/collector driver in order to avoid current flowing into this pin. Internal resetca. 180msgenerated by GSM engine/EMERGOFFmax. 900msRS-232 interface undefined definedVDD50 to100msBATT+/IGTmin. 10msmin.100ms HiZHiZ Figure 6: Power-on by ignition signal If configured to a fix baud rate, MC45 will send the result code ^SYSSTART to indicate that it is ready to operate. This result code does not appear when autobauding is active. See Chapter AT+IPR in [1]. In a battery operated MC45 application, the duration of the /IGT signal must be 1s minimum when the charger is connected and you may want to go from charging to Normal mode. For details please see Chapter 3.3.1.2](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-33.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 36 of 90 12.08.2002 3.3.2 Power saving SLEEP mode reduces the functionality of the MC45 module to a minimum and, thus, minimizes the current consumption to the lowest level. SLEEP mode is set with the AT+CFUN command which provides the choice of the functionality levels <fun>=0, 1, 5, 6, 7 or 8, all explained below. Further instructions of how to use AT+CFUN can be found in [1]. IMPORTANT: The AT+CFUN command can be executed before or after entering PIN1. Nevertheless, please keep in mind that power saving works only while the module is registered to the GSM network. If you attempt to activate power saving while the module is detached, the selected <fun> level will be set, though power saving does not take effect. To check whether power saving is on, you can query the status of AT+CFUN if you have chosen CYCLIC SLEEP mode. If available, you can take advantage of the status LED controlled by the SYNC pin (see Chapter 3.8.2.2). The LED stops flashing once the module starts power saving. The wake-up procedures are quite different depending on the selected SLEEP mode. Table 10 compares the wake-up events that can occur in NON-CYCLIC SLEEP mode and in the four CYCLIC SLEEP modes. 3.3.2.1 No power saving (AT+CFUN=1) The functionality level <fun>=1 is where power saving is switched off. This is the default after startup. 3.3.2.2 NON-CYCLIC SLEEP mode (AT+CFUN=0) If level 0 has been selected (AT+CFUN=0), the serial interface is blocked. The module shortly deactivates power saving to listen to a paging message sent from the base station and then immediately resumes power saving. Level 0 is called NON-CYCLIC SLEEP mode, since the serial interface is not alternatingly made accessible as in CYCLIC SLEEP mode. The first wake-up event fully activates the module, enables the serial interface and terminates the power saving mode. In short, it takes MC45 back to the highest level of functionality <fun>=1. 3.3.2.3 CYCLIC SLEEP mode (AT+CFUN=5, 6, 7 and 8) The functionality levels AT+CFUN=5, AT+CFUN=6, AT+CFUN=7 and AT+CFUN=8 are referred to as CYCLIC SLEEP modes. The major benefit over the NON-CYCLIC SLEEP mode is that the serial interface is not permanently blocked and that packet switched calls may go on without terminating the selected CYCLIC SLEEP mode. This allows MC45 to become active, for example to perform a GPRS data transfer, and to resume power saving after the GPRS data transfer is completed. The four CYCLIC SLEEP modes give you greater flexibility regarding the wake-procedures: Basically, you can enter AT+CFUN=1 to permanently wake up the module. Also, MC45 can automatically resume power saving, after you have sent or received a short message or made a call. Please refer to Table 10 for more details.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-36.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 42 of 90 12.08.2002 3.3.4 Automatic shutdown To ensure proper operation of all assemblies under varying conditions, such as temperature, input voltage, transmission power etc., MC45 features protection elements for automatic shutdown. Automatic shutdown takes effect if · the MC45 board is exceeding the critical limits of overtemperature or undertemperature · the battery is exceeding the critical limits of overtemperature or undertemperature · undervoltage is detected · overvoltage is detected. The automatic shutdown procedure is equivalent to the power-down initiated with the AT^SMSO command, i.e. MC45 logs off from the network and the software enters a secure state avoiding loss of data. This is not applicable to overvoltage shutdown, where power is cut off immediately. Alert messages transmitted before the device switches off are implemented as Unsolicited Result codes (URCs). The presentation of these URCs can be enabled or disabled with the two AT commands AT^SBC and AT^SCTM. The URC presentation mode varies with the condition, please see Chapters 3.3.4.1 to 3.3.4.4 for details. For further instructions on AT commands refer to [1]. 3.3.4.1 Temperature dependent shutdown The board temperature is constantly monitored by an internal NTC resistor located on the PCB. The NTC that detects the battery temperature must be part of the battery pack circuit as described in Chapter 3.2.3. The values detected by either NTC resistor are measured directly on the board or the battery and therefore, are not fully identical with the ambient temperature. Proceeding from the measured temperature, MC45 sends an alert in the form of a URC and switches off when exceeding the critical limits: · URCs indicating the alert level "1" or "-1" allow you to take appropriate precautions, such as protect the module or battery from exposure to extreme conditions, or save or back up data etc. The presentation of the URCs depends on the settings selected with the AT^SCTM write command: AT^SCTM=1: Presentation of URCs is always enabled. AT^SCTM=0 (default): Presentation of URCs is enabled for 15 seconds time after start-up of MC45. After 15 seconds operation, the presentation will be disabled, i.e. no alert messages can be generated. · URCs indicating the alert level "2" or "-2" are followed by immediate shutdown. The presentation of these URCs is always enabled, i.e. they will be output even though the factory setting AT^SCTMC=0 was never changed. · When the temperature is back to normal, again a message will be delivered. In this case, the URC indicates level “0”. Table 11 summarizes the maximum ratings and the associated URCs.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-42.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 43 of 90 12.08.2002 Table 11: Temperature dependent behaviour Sending temperature alert (15 s after start-up, otherwise only if URC presentation enabled) ^SCTM_A: 1 Caution: Tamb of battery close to overtemperature limit. ^SCTM_B: 1 Caution: Tamb of board close to overtemperature limit. ^SCTM_A: -1 Caution: Tamb of battery close to undertemperature limit. ^SCTM_B: -1 Caution: Tamb of board close to undertemperature limit. ^SCTM_A: 0 Battery back to uncritical temperature range. ^SBCTM_B: 0 Board back to uncritical temperature range. Automatic shutdown (URC appears no matter whether or not presentation was enabled) ^SCTM_A: 2 Alert: Tamb of battery equal or beyond overtemperature limit. MC45 switches off.^SCTM_B: 2 Alert: Tamb of board equal or beyond overtemperature limit. MC45 switches off. ^SCTM_A: -2 Alert: Tamb of battery equal or below undertemperature limit. MC45 switches off. ^SCTM_B: -2 Alert: Tamb of board equal or below undertemperature limit. MC45 switches off. The values stated in Table 11 are based on test conditions according to IEC 60068-2-2 (still air). 3.3.4.2 Undervoltage shutdown if battery NTC is present In applications where the module’s charging technique is used and an NTC is connected to the BATT_TEMP terminal, the software constantly monitors the applied voltage to check that the battery voltage is sufficient to set up a call. When the battery voltage decreases to VBATT+<3.6V, the following URC will be presented: ^SBC: Undervoltage To enable or disable the URC use the AT^SBC command. The URC will be enabled when you enter the write command and specify the power consumption of your GSM application. Step by step instructions are provided in [1]. The message will be reported, for example, when you attempt to set up a call while the voltage is close to the critical limit and further power loss is caused during the transmit burst. To remind you that the battery needs to be charged soon, the URC appears several times before the module switches off. 3.3.4.3 Undervoltage shutdown if no battery NTC is present The undervoltage protection is also effective in applications, where no NTC connects to the BATT_TEMP terminal. Thus, you can take advantage of this feature even though the application handles the charging process or MC45 is fed by a fixed supply voltage. All you need to do is executing the write command AT^SBC=<current> which automatically enables the presentation of URCs. You do not need to specify <current>. Please note, that in contrast to applications with an NTC connected to BATT_TEMP, the module will present the URC ^SBC: Undervoltage only once and will then switch off without sending any further messages.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-43.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 49 of 90 12.08.2002 3.6 Audio interfaces MC45 comprises three audio interfaces available on the board-to-board connector: · Two analog audio interfaces, each with a balanced analog microphone input and a balanced analog earpiece output. The second analog interface provides a supply circuit to feed an active microphone. · Serial digital audio interface (DAI) using PCM (Pulse Code Modulation) to encode analog voice signals into digital bit streams. This means you can connect up to three audio devices in any combination, all at the same time. Using the AT^SAIC command you can easily switch back and forth. M U X ADC DSP DACAir InterfaceDigital Audio Interface (DAI) MICP1 MICN1 MICP2 MICN2 EPP1 EPN1 EPP2 EPN2 SCLK RXDDAI TFSDAI RFSDAI TXDDAI Figure 16: Audio block diagram MC45 offers six audio modes which can be selected with the AT^SNFS command, no matter which of the three interfaces is currently active. The electrical characteristics of the voiceband part vary with the audio mode. For example, sending and receiving amplification, sidetone paths, noise suppression etc. depend on the selected mode and can be altered with AT commands (except for mode 1). On each audio interface you can use all audio AT commands specified in [1] to alter parameters. The only exception are the DAC and ADC gain amplifier attenuation <outBbcGain> and <inBbcGain> which cannot be modified when the digital audio interface is used, since in this case the DAC and ADC are switched off. Please refer to Chapter 6.5 for specifications of the audio interface and an overview of the audio parameters. Detailed instructions on using AT commands are presented in the "MC45 AT Command Set" [1]. Table 31 on page 83 summarizes the characteristics of the various audio modes and shows what parameters are supported in each mode.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-49.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 51 of 90 12.08.2002 3.6.2 Speech processing The speech samples from the ADC or DAI are handled by the DSP of the baseband controller to calculate e.g. amplifications, sidetone, echo cancellation or noise suppression depending on the configuration of the active audio mode. These processed samples are passed to the speech encoder. Received samples from the speech decoder are passed to the DAC or DAI after post processing (frequency response correction, adding sidetone etc.). Full rate, half rate, enhanced full rate, speech and channel encoding including voice activity detection (VAD) and discontinuous transmission (DTX) and digital GMSK modulation are also performed on the GSM baseband processor. Customer specific audio parameters can be evaluated by Siemens on customer request. These parameters can be downloaded to MC45 using an AT command. For further information refer to [6] or contact your Siemens distributor. 3.6.3 DAI timing To support the DAI function, MC45 integrates a simple five-line serial interface with one input data clock line (SCLK) and input / output data and frame lines (TXDDAI, TFSDAI, RXDDAI, RFSDAI). The serial interface is always active if the external input data clock SLCK is present, i.e. the serial interface is not clocked by the DSP of the MC45 baseband processor. SLCK must be supplied from the application and can be in a frequency range between 0.2 and 10 MHz. Serial transfer of 16-bit words is done in both directions. Data transfer to the application is initiated by the module through a short pulse of TFSDAI. The duration of the TFSDAI pulse is one SCLK period, starting at the rising edge of SLCK. During the following 16 SLCK cycles, the 16-bit sample will be transferred on the TXDDAI line. The next outgoing sample will be transferred after the next TFSDAI pulse which occurs every 125 µs. The TFSDAI pulse is the master clock of the sample transfer. From the rising edge of the TFSDAI pulse, the application has 100 µs to transfer the 16-bit input sample on the RXDDAI line. The rising edge of the RFSDAI pulse (supplied by the application) may coincide with the falling edge of TFSDAI or occur slightly later - it is only significant that, in any case, the transfer of the LSB input sample will be completed within the specified duration of 100 µs. Audio samples are transferred from the module to the application in an average of 125µs. This is determined by the 8kHz sampling rate, which is derived from and synchronized to the GSM network. As SLCK is independent of the GSM network, the distance between two succeeding sample transfers may vary about + 1 SLCK period. The application is required to adapt its sampling rate to the TFDSDAI rate. Failure to synchronize the timing between the module and the application may cause audible pops and clicks in a conversation The timing characteristics of both data transfer directions are shown in Figure 18 and Figure 19.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-51.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 55 of 90 12.08.2002 3.7.2 Design considerations for SIM card holder The schematic below is a sample configuration that illustrates the Molex SIM card holder located on the DSB45 Support Box (evaluation kit used for type approval of the Siemens MC45 reference setup, see [4]). X503 is the designation used for the SIM card holder in [4]. Molex card holder GSM module Figure 20: SIM card holder of DSB45 Support Box Table 14 : Pin assignment of Molex SIM card holder on DSB45 Support Box Pin no. Signal name I/O Function 1 CCVCC I Supply voltage for SIM card, generated by the GSM engine 2 CCRST I Chip card reset, prompted by the GSM engine 3 CCCLK I Chip card clock 4 CCGND - Individual ground line for the SIM card to improve EMC 5 CCVPP - Not connected 6 CCIO I/O Serial data line, bi-directional 7 CCDET1 - Connect to CCVCC 8 CCDET2 Connects to the CCIN input of the GSM engine. Serves to recognize whether a SIM card is in the holder. Removing the SIM card during operation will immediately stop further transmission of signals to the card to protect the card from damage. Pins 1 through 6 are the minimum requirement according to the GSM Recommendations, while 7 and 8 are needed for the CCIN pin. Place the capacitors C1205 and C1206 (or instead one capacitor of 200nF) as close as possible to the pins 1 (CCVCC) and 4 (GND) of the card holder. Connect the capacitors to the pins via low resistance tracks. The X507 switch is not mandatory, but may be added to help the system integrator control the CCIN signal, e.g. for designing and testing purposes. When the switch is pushed open (3 is switched to 2), the line simulates an empty SIM card holder although the SIM is inserted. When closed (3 connected to 1), the line simulates that the SIM card is present.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-55.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 81 of 90 12.08.2002 6.5 Electrical characteristics of the voiceband part 6.5.1 Setting audio parameters by AT commands The audio modes 2 to 6 can be adjusted according to the parameters listed below. Each audio mode is assigned a separate set of parameters. Table 30: Audio parameters adjustable by AT command Parameter Influence to Range Gain range Calculation inBbcGain MICP/MICN analogue amplifier gain of baseband controller before ADC 0...7 0...42dB 6dB steps inCalibrate digital attenuation of input signal after ADC 0...32767 -$...0dB 20 * log (inCalibrate/ 32768) outBbcGain EPP/EPN analogue output gain of baseband controller after DAC 0...3 0...-18dB 6dB steps outCalibrate[n] n = 0...4 digital attenuation of output signal after speech decoder, before summation of sidetone and DAC present for each volume step[n] 0...32767 -$...+6dB 20 * log (2 * outCalibrate[n]/ 32768) sideTone digital attenuation of sidetone is corrected internally by outBbcGain to obtain a constant sidetone independent of output volume 0...32767 -$...0dB 20 * log (sideTone/ 32768) Note: The parameters inCalibrate, outCalibrate and sideTone accept also values from 32768 to 65535. These values are internally truncated to 32767.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-81.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 82 of 90 12.08.2002 6.5.2 Audio programming model The audio programming model shows how the signal path can be influenced by varying the AT command parameters. The model is the same for all three interfaces, except for the parameters <outBbcGain> and <inBbcGain> which cannot be modified on the digital audio interface is being used, since in this case the DAC is switched off. The parameters inBbcGain and inCalibrate can be set with AT^SNFI. All the other parameters are adjusted with AT^SNFO. ADAD-¥...0dB speechcoder (0dB; -6db, -12dB; -18dB) +0..42dB in 6dB-steps1k 1k 1k 1k 2,65V 10uF+ sideTone AT parameter outCalibrate[n] n = 0...4 inCalibrate inBbcGain outBbcGain speechdecoder MIC2 Figure 40: AT audio programming model](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-82.png)
![MC45 Hardware Interface Description P R E L I M I N A R Y MC45_HD_01_V00.02a Page 83 of 90 12.08.2002 6.5.3 Characteristics of audio modes The electrical characteristics of the voiceband part depend on the current audio mode set with the AT^SNFS command. Table 31: Voiceband characteristics (typical), all values preliminary Audio mode no. AT^SNFS= 1 (Default settings, not adjustable) 2 3 4 5 6 Name Default Handset Basic Handsfree Headset User Handset Plain Codec 1 Plain Codec 2 Purpose DSB with M20T hand-set Siemens Car Kit Portable Siemens Headset DSB with individual handset Direct access to speech coder Direct access to speech coder Gain setting via AT command. Defaults: inBbcGain outBbcGain Fix 4 (24dB) 1 (-6dB) Adjustable 2 (12dB) 1 (-6dB) Adjustable 5 (30dB) 2 (-12dB) Adjustable 4 (24dB) 1 (-6dB) Adjustable 0 (0dB) 0 (0dB) Adjustable 0 (0dB) 0 (0dB) Default audio interface 1 2 2 1 1 2 4) Power supply ON ON ON ON OFF OFF Sidetone ON --- Adjustable Adjustable Adjustable Adjustable Volume control OFF Adjustable Adjustable Adjustable Adjustable Adjustable Limiter (receive) ON ON ON ON --- --- Compressor (receive) --- ON1) --- --- --- --- AGC (send) --- --- ON --- --- --- Echo control (send) Suppression Cancellation +suppression --- Suppres-sion --- --- Noise suppression2) --- up to 10dB 10dB --- --- --- MIC input signal for 0dBm0 @ 1024 Hz (default gain) 23mV 58mV 7.5mV @ -3dBm0 due to AGC 23mV 315mV 315mV EP output signal in mV rms. @ 0dBm0, 1024 Hz, no load (default gain); @ 3.14 dBm0 284mV 120mV default @ max volume 300mV default @ max volume 284mV default @ max volume 895mV 3.7Vpp 895mV 3.7Vpp Sidetone gain at default settings 22.8dB -$ dB Affected by AGC, 13dB @ 7.5mV (MIC) 22.8dB 0dB @ sideTone = 81923) 0dB @ sideTone = 81923) 1) Adaptive, receive volume increases with higher ambient noise level. 2) In audio modes with noise reduction, the microphone input signal for 0dBm0 shall be measured with a sine burst signal for a tone duration of 5 seconds and a pause of 2 sec. The sine signal appears as noise and, after approx. 12 sec, is attenuated by the noise reduction by up to 10dB. 3) See AT^SNFO command in [1]. 4) Audio mode 5 and 6 are identical. With AT^SAIC, you can easily switch mode 5 to the second interface. Therefore, audio mode 6 is only kept for compatibility to earlier Siemens GSM products.](https://usermanual.wiki/THALES-DIS-AlS-Deutschland/MC45/User-Guide-270326-Page-83.png)
