u blox LEONG100N LEON-G1 series quad-band GSM/GPRS data & voice modules User Manual LEON G1 series
u-blox AG LEON-G1 series quad-band GSM/GPRS data & voice modules LEON G1 series
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![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 13 of 118 1.4 Operating modes LEON-G1 series modules include several operating modes, each have different features and interfaces. Table 4 summarizes the various operating modes and provides general guidelines for operation. Operating Mode Description Features / Remarks Transition condition General Status: Power-down Not-Powered Mode VCC supply not present or below normal operating range. Microprocessor switched off (not operating). RTC only operates if supplied through V_BCKP pin. Module is switched off. Application interfaces are not accessible. Internal RTC timer operates only if a valid voltage is applied to V_BCKP pin. Any external signal connected to the UART I/F, I2S I/F, HS_DET, GPIOs must be tristated to avoid an increase of module power-off consumption. Module cannot be switched on by a falling edge provided on the PWR_ON input, neither by a preset RTC alarm. Power-Off Mode VCC supply within normal operating range. Microprocessor not operating. Only RTC runs. Module is switched off: normal shutdown after sending the AT+CPWROFF command (refer to u-blox AT Commands Manual [2]). Application interfaces are not accessible. Only internal RTC timer in operation. Any external signal connected to the UART I/F, I2S I/F, HS_DET, GPIOs must be tristated to avoid an increase of the module power-off consumption. Module can be switched on by a falling edge provided on the PWR_ON input, by a preset RTC alarm. General Status: Normal Operation Idle-Mode Microprocessor runs with 32 kHz as reference oscillator. Module does not accept data signals from an external device. If power saving is enabled, the module automatically enters idle mode whenever possible. If hardware flow control is enabled, the CTS line indicates that the module is in active-mode and the UART interface is enabled: the line is driven in the OFF state when the module is not prepared to accept data by the UART interface. If hardware flow control is disabled, the CTS line is fixed to ON state. Module by default is not set to automatically enter idle mode whenever possible, unless power saving configuration is enabled by appropriate AT command (refer to u-blox AT Commands Manual [2], AT+UPSV). If the module is registered with the network and power saving is enabled, it automatically enters idle mode and periodically wakes up to active mode to monitor the paging channel for the paging block reception according to network indication. If module is not registered with the network and power saving is enabled, it automatically enters idle mode and periodically wakes up to monitor external activity. Module wakes up from idle-mode to active-mode for an incoming voice or data call. Module wakes up from idle mode to active mode if an RTC alarm occurs. Module wakes up from idle mode to active mode when data is received on UART interface (see section 1.9.1). Module wakes up from idle mode to active mode when the RTS input line is set to the ON state by the DTE if the AT+UPSV=2 command is sent to the module (see section 1.9.1). Active-Mode Microprocessor runs with 26 MHz as reference oscillator. The module is ready to accept data signals from an external device. Module is switched on and is fully active: power saving is not enabled. The application interfaces are enabled. If power saving is enabled, the module automatically enters idle mode whenever possible.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-13.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 16 of 118 1.5.2 Module supply (VCC) LEON-G1 series modules must be supplied through VCC pin by a DC power supply. Voltages must be stable, due to the surging consumption profile of the GSM system (described in the section 1.5.3). Name Description Remarks VCC Module Supply Clean and stable supply is required: low ripple and low voltage drop must be guaranteed. Voltage provided has to be always above the minimum limit of the operating range. Consider that there are large current spike in connected mode, when a GSM call is enabled. GND Ground GND pins are internally connected but good (low impedance) external ground can improve RF performances: all GND pins must be externally connected to ground. Table 5: Module supply pins VCC pin ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the line is externally accessible on the application board. A higher protection level can be achieved mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the line connected to this pin if it is externally accessible on the application board. The voltage provided to VCC pin must be within the normal operating range limits specified in the LEON-G1 series Data Sheet [1]. Complete functionality of the module is only guaranteed within the specified operational normal voltage range. The module cannot be switched on if the VCC voltage value is below the specified normal operating range minimum limit: ensure that the input voltage at VCC pin is above the minimum limit of the normal operating range for more than 1 second after the start of the switch-on of the module. When LEON-G1 series modules are in operation, the voltage provided to VCC pin can exceed the normal operating range limits but must be within the extended operating range limits specified in LEON-G1 series Data Sheet [1]. Module reliability is only guaranteed within the specified operational extended voltage range. The module switches off when VCC voltage value drops below the specified extended operating range minimum limit: ensure that the input voltage at VCC pin never drops below the minimum limit of the extended operating range when the module is switched on, not even during a GSM transmit burst, where the current consumption can rise up to maximum peaks of 2.5 A in case of a mismatched antenna load. Operation above the extended operating range maximum limit is not recommended and extended exposure beyond it may affect device reliability. Stress beyond the VCC absolute maximum ratings may cause permanent damage to the module: if necessary, voltage spikes beyond VCC absolute maximum ratings must be limited to values within the specified boundaries by using appropriate protection.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-16.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 23 of 118 1.5.3 Current consumption profiles During operation, the current consumed by LEON-G100 through VCC pin can vary by several orders of magnitude. This is applied to ranges from the high peak of current consumption during the GSM transmitting bursts at maximum power level in connected mode, to the low current consumption in idle mode when power saving configuration is enabled. 1.5.3.1 Current consumption profiles – Connected mode When a GSM call is established, the VCC consumption is determined by the current consumption profile typical of the GSM transmitting and receiving bursts. The current consumption peak during a transmission slot is strictly dependent on the transmitted power, which is regulated by the network. If the module transmits in GSM talk mode in the GSM 850 or in the EGSM 900 band at the maximum power control level (32.2 dBm typical transmitted power in the transmit slot/burst), the current consumption can reach up to 2500 mA (with highly unmatched antenna) for 576.9 µs (width of the transmit slot/burst) with a periodicity of 4.615 ms (width of 1 frame = 8 slots/bursts), so with a 1/8 duty cycle, according to GSM TDMA. During a GSM call, current consumption is in the order of 100-200 mA in receiving or in monitor bursts and is about 30-50 mA in the inactive unused bursts (low current period). The more relevant contribution to determine the average current consumption is set by the transmitted power in the transmit slot. Figure 9 shows an example of current consumption profile of the data module in GSM talk mode. Time [ms]RX slotunused slotunused slotTX slotunused slotunused slotMON slotunused slotRX slotunused slotunused slotTX slotunused slotunused slotMON slotunused slotGSM frame 4.615 ms (1 frame = 8 slots)Current [A]200 mA ~170 mA2500 mAPeak current depends on TX powerGSM frame 4.615 ms (1 frame = 8 slots)1.51.00.50.02.52.0~170 mA ~40 mA Figure 9: Description of the VCC current consumption profile versus time during a GSM call (1 TX slot) When a GPRS connection is established there is a different VCC current consumption profile also determined by the transmitting and receiving bursts. In contrast to a GSM call, during a GPRS connection more than one slot can be used to transmit and/or more than one slot can be used to receive. The transmitted power depends on network conditions and sets the peak of current consumption, but following the GPRS specifications the maximum transmitted power can be reduced if more than one slot is used to transmit, so the maximum peak of current consumption is not as high as can be the case in a GSM call. If the module transmits in GPRS class 10 connected mode in the GSM 850 or in the EGSM 900 band at the maximum power control level (30.5 dBm typical transmitted power in the transmit slot/burst), the current consumption can reach up to 1800 mA (with highly unmatched antenna) for 1.154 ms (width of the 2 transmit](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-23.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 24 of 118 slots/bursts) with a periodicity of 4.615 ms (width of 1 frame = 8 slots/bursts), so with a 1/4 duty cycle, according to GSM TDMA. Figure 10 reports the current consumption profiles with 2 slots used to transmit. Time [ms]RX slotunused slotunused slotTX slotTX slotunused slotMON slotunused slotRX slotunused slotunused slotTX slotTX slotunused slotMON slotunused slotGSM frame 4.615 ms (1 frame = 8 slots)Current [A]200mA ~170 mA1800 mAPeak current depends on TX power~170 mAGSM frame 4.615 ms (1 frame = 8 slots)1.51.00.50.02.52.0~40 mA Figure 10: Description of the VCC current consumption profile versus time during a GPRS connection (2 TX slots) 1.5.3.2 Current consumption profiles – Cyclic idle/active mode (power saving enabled) The power saving configuration is by default disabled, but it can be enabled using the appropriate AT command (refer to u-blox AT Commands Manual [2], AT+UPSV command). When the power saving is enabled, the module automatically enters idle-mode whenever possible. When power saving is enabled, the module is registered or attached to a network and a voice or data call is not enabled, the module automatically enters idle-mode whenever possible, but it must periodically monitor the paging channel of the current base station (paging block reception), in accordance to GSM system requirements. When the module monitors the paging channel, it wakes up to active mode, to enable the reception of paging block. In between, the module switches to idle-mode. This is known as GSM discontinuous reception (DRX). The module processor core is activated during the paging block reception, and automatically switches its reference clock frequency from the 32 kHz used in idle-mode to the 26 MHz used in active-mode. The time period between two paging block receptions is defined by the network. It can vary from 470.76 ms (width of 2 GSM multiframes = 2 x 51 GSM frames = 2 x 51 x 4.615 ms) up to 2118.42 ms (width of 9 GSM multiframes = 9 x 51 frames = 9 x 51 x 4.615 ms): this is the paging period parameter, fixed by the base station through broadcast channel sent to all users on the same serving cell. An example of the current consumption profile of the data module when power saving is enabled is shown in Figure 11: the module is registered with the network, automatically goes into idle mode and periodically wakes up to active mode to monitor the paging channel for paging block reception (cyclic idle/active mode).](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-24.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 25 of 118 ~30 msIDLE MODE ACTIVE MODE IDLE MODE500-700 µA 8-10 mA 20-22 mA~150 mAActive Mode EnabledIdle Mode EnabledPLL EnabledRX Enabled500-700 µA~150 mA0.44-2.09 sIDLE MODE~30 msACTIVE MODETime [s]Current [mA]150100500Time [ms]Current [mA]15010050038-40 mADSP Enabled Figure 11: Description of the VCC current consumption profile versus time when power saving is enabled: the module is in idle mode and periodically wakes up to active mode to monitor the paging channel for paging block reception 1.5.3.3 Current consumption profiles – Fixed active mode (power saving disabled) Power saving configuration is by default disabled, or it can be disabled using the appropriate AT command (refer to u-blox AT Commands Manual [2], AT+UPSV command). When power saving is disabled, the module does not automatically enter idle-mode whenever possible: the module remains in active mode. The module processor core is activated during active-mode, and the 26 MHz reference clock frequency is used. An example of the current consumption profile of the data module when power saving is disabled is shown in Figure 12: the module is registered with the network, active-mode is maintained, and the receiver and the DSP are periodically activated to monitor the paging channel for paging block reception.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-25.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 26 of 118 ACTIVE MODE20-22 mA 20-22 mA20-22 mA~150 mA0.47-2.12 sPaging periodTime [s]Current [mA]150100500Time [ms]Current [mA]150100500RX EnabledDSP Enabled~150 mA38-40 mA Figure 12: Description of the VCC current consumption profile versus time when power saving is disabled: active-mode is always held, and the receiver and the DSP are periodically activated to monitor the paging channel for paging block reception](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-26.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 27 of 118 1.5.4 RTC supply (V_BCKP) V_BCKP connects the Real Time Clock (RTC) supply, generated internally by a linear regulator integrated in the module chipset. The output of this linear regulator is enabled when the main voltage supply providing the module through VCC is within the valid operating range, or if the module is switched-off. Name Description Remarks V_BCKP Real Time Clock supply V_BCKP = 2.0 V (typical) generated by the module to supply Real Time Clock when VCC supply voltage is within valid operating range. Table 10: Real Time Clock supply pin V_BCKP pin ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the line is externally accessible on the application board. A higher protection level can be achieved by mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the line connected to this pin if it is externally accessible on the application board. The RTC provides the time reference (date and time) of the module, also in power-off mode, since the RTC runs when the V_BCKP voltage is within its valid range (specified in the LEON-G1 series Data Sheet [1]). The RTC block is able to provide programmable alarm functions by means of the internal 32.768 kHz clock. The RTC block has very low, but highly temperature dependent power consumption. For example at 25°C and a V_BCKP voltage of 2.0 V the power consumption is approximately 2 µA, whereas at 85°C and an equal voltage it increases to 5 µA. The RTC can be supplied from an external back-up battery through V_BCKP, when the main voltage supply is not provided to the module through VCC. This enables the time reference (date and time) to run even when the main supply is not provided to the module. The module cannot switch on if a valid voltage is not present on VCC, even when RTC is supplied through V_BCKP (meaning that VCC is mandatory to switch-on the module). If V_BCKP is left unconnected and the main voltage supply of the module is removed from VCC, the RTC is supplied from the 1 µF buffer capacitor mounted inside the module. However, this capacitor is not able to provide a long buffering time: within 0.5 seconds the voltage on V_BCKP will fall below the valid range (1 V min). If RTC is not required when VCC supply is removed, V_BCKP can be left floating on the application board. If RTC has to run for a time interval of T [seconds] at 25°C and VCC supply is removed, place a capacitor of nominal capacitance of C [µF] at the V_BCKP pin. Choose the capacitor using the following formula: C [µF] = (Current_Consumption [µA] x T [seconds]) / Voltage_Drop [V] = 2 x T [seconds] The current consumption of the RTC is around 2 µA at 25°C, and the voltage drop is equal to 1 V (from the V_BCKP typical value of 2.0 V to the valid range minimum limit of 1.0 V). For example, a 100 µF capacitor (such as the Murata GRM43SR60J107M) can be placed at V_BCKP to provide a long buffering time. This capacitor will hold V_BCKP voltage within its valid range for around 50 seconds at 25°C, after the VCC supply is removed. If a very long buffering time is required, a 70 mF super-capacitor (e.g. Seiko Instruments XH414H-IV01E) can be placed at V_BCKP, with a 4.7 k series resistor to hold the V_BCKP voltage within its valid range for around 10 hours at 25°C, after the VCC supply is removed. The purpose of the series resistor is to limit the capacitor charging current due to the big capacitor specifications, and also to let a fast rise time of the voltage value at the V_BCKP pin after VCC supply has been provided. These capacitors will allow the time reference to run during a disconnection of the VCC supply.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-27.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 29 of 118 1.6.1.1 Rising edge on VCC When a supply is connected to VCC pin, the module supply supervision circuit controls the subsequent activation of the power up state machines: the module is switched-on when the voltage rises up to the VCC normal operating range minimum limit (3.35 V) starting from a voltage value lower than 2.25 V. 1.6.1.2 Low level on the PWR_ON Power-on sequence of the module starts when a low level is forced on the PWR_ON signal for at least 5 ms. The electrical characteristics of the PWR_ON input pin are different from the other digital I/O interfaces: the high and the low logic levels have different operating ranges and the pin is tolerant against voltages up to the battery voltage. The detailed electrical characteristics are described in the LEON-G1 series Data Sheet [1]. PWR_ON pin has high input impedance and is weakly pulled to the high level on the module. Avoid keep it floating in noisy environment. To hold the high logic level stable, the PWR_ON pin must be connected to a pull-up resistor (e.g. 100 kΩ) biased by the V_BCKP supply pin of the module. If PWR_ON input is connected to a push button that shorts the PWR_ON pin to ground, the V_BCKP supply pin of the module can be used to bias the pull-up resistor. If PWR_ON input is connected to an external device (e.g. application processor), it is suggested to use an open drain output of the external device with an external pull-up. Connect the pull-up the V_BCKP supply pin of the module. If PWR_ON pin is connected to a push-pull output pin of an application processor, the pull-up can be provided to pull high the PWR_ON level when the application processor is switched off. If the high-level voltage of the push-pull output pin of the application processor is greater than 2.0 V, the V_BCKP supply cannot be used to bias the pull-up resistor: the supply rail of the application processor, or the VCC supply could be used but this will increase the V_BCKP (RTC supply) current consumption when the module is in not-powered mode (i.e. VCC supply not present). Using a push-pull output of the external device, take care to fix the proper level in all the possible scenarios to avoid an inappropriate switch-on of the module. The module can be switched-on by forcing a low level for at least 5 ms on the PWR_ON pin: the module is not switched-on by a falling edge provided on the PWR_ON pin. The suggested PWR_ON pull-up resistor value is 100 kΩ: lower resistance value will increase the module power-off consumption. The suggested supply to bias the pull-up resistor is the V_BCKP supply pin of the module.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-29.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 30 of 118 Power-on push buttonLEON-G10019 PWR_ONLEON-G10019 PWR_ONApplication Processor100 k2V_BCKPESD100 k2V_BCKP Figure 14: Power on (PWR_ON) application circuits using a push button or using an application processor 1.6.1.3 RTC alarm The module can be switched-on by the RTC alarm if a valid voltage is applied to VCC pin, when Real Time Clock system reaches a pre-defined scheduled time. The RTC system will then initiate the boot sequence by indicating to the power management unit to turn on power. Also included in this setup is an interrupt signal from the RTC block to indicate to the baseband processor, that a RTC event has occurred. 1.6.1.4 Additional considerations The module is switched on when the voltage rises up to the VCC normal operating range: the first time that the module is used, it is switched on in this way. Then, the proper way to switch-off the module is by means of the AT+CPWROFF command. When the module is in power-off mode, i.e. the AT+CPWROFF command has been sent and a voltage value within the normal operating range limits is still provided to the VCC pin, the digital input-output pads of the baseband chipset (i.e. all the digital pins of the module) are locked in tri-state (i.e. floating). The power down tri-state function isolates the pins of the module from its environment, when no proper operation of the outputs can be guaranteed. To avoid an increase of the module current consumption in power down mode, any external signal of the digital interfaces connected to the module must be set low or tri-stated when the module is in not-powered mode or in the power-off mode. The module can be switched on from power-off mode by forcing a proper start-up event (i.e. a low level on the PWR_ON pin, or an RTC alarm). After the detection of a start-up event, all the digital pins of the module are held in tri-state until all the internal LDO voltage regulators are turned on in a defined power-on sequence. Then, as described in Figure 15, the baseband core continues to be held in reset state for a time interval: the module still pulls the RESET_N pin low and any signal from the module digital interfaces is held in reset state. The reset state of all the digital pins is reported in the pin description table of the LEON-G1 series Data Sheet [1]. When the module releases the RESET_N pin, the level at this pin will be pulled high by the action of the internal pull-up and the configuration of the module interfaces will start: during this phase any digital pin is set in a proper sequence from reset state to the default operational configuration. The module is fully ready to operate when all the interfaces are configured.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-30.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 32 of 118 1.6.2 Module power off The correct way to switch off LEON-G1 series modules is by means of the AT command AT+CPWROFF (more details in u-blox AT Commands Manual [2]): in this way the current parameter settings are saved in the module’s non-volatile memory and a proper network detach is performed. An under-voltage shutdown will be done if VCC falls below the extended operating range minimum limit (see the LEON-G1 series Data Sheet [1]), but in this case the current parameter settings are not saved in the module’s non-volatile memory and a proper network detach cannot be performed. When the AT+CPWROFF command is sent, the module starts the switch-off routine replying OK on the AT interface: during this phase, the current parameter settings are saved in the module’s non-volatile memory, a network detach is performed and all module interfaces are disabled (i.e. the digital pins are locked in tri-state by the module). Since the time to perform a network detach depends on the network settings, the duration of this phase can differ from the typical value reported in Figure 16. At the end of the switch-off routine, the module pulls the RESET_N pin low to indicate that it is in power-off mode: all the digital pins are locked in tri-state by the module and all the internal LDO voltage regulators except the RTC supply (V_BCKP) are turned off in a defined power-off sequence. The module remains in power-off mode as long as a switch-on event does not occur (i.e. a low level on the PWR_ON pin, or an RTC alarm), and enters not-powered mode if the supply is removed from the VCC pin. To avoid an increase of module current consumption in power-down mode, any external signal connected to the module digital pins (UART interface, Digital audio interface, HS_DET, GPIOs) must be tri-stated when the module is in the not-powered or power-off modes. If the external signals connected to the module digital pins cannot be set low or tri-stated, insert a switch (e.g. Texas Instruments SN74CB3Q16244, or Texas Instruments TS5A3159, or Texas Instruments TS5A63157) between the two-circuit connections. Set the switch to high impedance when the module is in power-down mode (to avoid an increase of the module power consumption). Figure 16 describes the power-off sequence. VCCV_BCKPPWR_ON *LDOsRESET_NSystem StateBB Pads State OperationalOFFTristate / Floating ONOperational → Tristate / FloatingAT+CPWROFFsent to the module0 ms~50 ms~400 msOKreplied by the module Figure 16: Power off sequence description (* - the PWR_ON signal state is not relevant during this phase)](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-32.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 33 of 118 1.6.3 Module reset LEON-G100 modules can be reset using the RESET_N pin: when the RESET_N pin is forced low for at least 50 ms, an “external” or “hardware” reset is performed, that causes an asynchronous reset of the entire module, except for the RTC. Forcing an “external” or “hardware” reset, the current parameter settings are not saved in the module’s non-volatile memory and a proper network detach is not performed. LEON-G100 modules can also be reset by means of the AT command AT+CFUN (more details in u-blox AT Commands Manual [2]): in this case an “internal” or “software” reset is performed, that causes, like the “external” or “hardware” reset, an asynchronous reset of the entire module except for the RTC. Forcing an “internal” or “software” reset, the current parameter settings are saved in the module’s non-volatile memory and a proper network detach is performed. The RESET_N pin is pulled low by the module when the module is in power-off mode or an internal reset occurs. In these cases an internal open drain FET pulls the line low. Name Description Remarks RESET_N Reset signal A series Schottky diode is integrated in the module as protection. An internal 12.6 kΩ pull-up resistor pulls the line to 1.88 V when the module is not in the reset state. An internal open drain FET pulls the line low when an internal reset occurs and when the module is in power down mode. Table 13: Reset pin RESET_N pin ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the line is externally accessible on the application board. A higher protection level can be achieved mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the line connected to this pin if it is externally accessible on the application board. For more details about the general precautions for ESD immunity about RESET_N pin, see section 2.5.1. The reset state of each digital pin is reported in the pin description table in the LEON-G1 series Data Sheet [1]. The electrical characteristics of RESET_N are different from the other digital I/O interfaces. The high and low logic levels have different operating ranges and absolute maximum ratings. The detailed electrical characteristics are described in the LEON-G1 series Data Sheet [1]. As described in the Figure 17, a series Schottky diode is mounted inside the module on the RESET_N pin to increase the maximum allowed input voltage up to 4.5 V as operating range. Nevertheless the module senses a low level when the RESET_N pin is forced low from the external. As described in Figure 17, the module has an internal pull-up resistor (12.6 kΩ typical) which pulls the level on the RESET_N pin to 1.88 V (typical) when the module is not in reset state. Therefore an external pull-up is not required on the application board. Forcing RESET_N low for at least 50 ms will cause an external reset of the module. When RESET_N is released from the low level, the module automatically starts its power-on reset sequence. If RESET_N is connected to an external device (e.g. an application processor on an application board) an open drain output can be directly connected without any external pull-up. Otherwise, use a push-pull output. Make sure to fix the proper level on RESET_N in all possible scenarios, to avoid unwanted reset of the module. As an ESD immunity test precaution, a 47 pF bypass capacitor (e.g. Murata GRM1555C1H470JA01) and a series ferrite bead (e.g. Murata BLM15HD182SN1) must be added on the RESET_N line pin to avoid a module reset caused by an electrostatic discharge applied to the application board (for more details, refer to section 2.5.1).](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-33.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 36 of 118 Depends on the pull-down strength(~35 µs with 680 k)time [µs]1600LOW = 0 VHIGH = 1.88 VReset state start Reset state endRESET_N Figure 19: RESET_N behavior due to an internal reset 1.6.4 Note: tri-stated external signal Any external signal connected to the UART interface, I2S interfaces and GPIOs must be tri-stated when the module is in power-down mode, when the external reset is forced low, and during the module power-on sequence (at least for 3 s after the start-up event), to avoid latch-up of circuits and allow a proper boot of the module. If the external signals connected to the wireless module cannot be tri-stated, insert a multi channel digital switch (e.g. Texas Instruments SN74CB3Q16244, TS5A3159, or TS5A63157) between the two-circuit connections and set to high impedance during module power down mode, when external reset is forced low and during power-on sequence. 1.7 RF connection The ANT pin has 50 Ω nominal impedance and must be connected to the antenna through a 50 Ω transmission line to allow transmission and reception of radio frequency (RF) signals in the GSM operating bands. Name Description Remarks ANT RF antenna 50 nominal impedance. Table 14: Antenna pin ANT port ESD immunity rating is 4 kV (according to IEC 61000-4-2). A higher protection level could be required if the line is externally accessible on the application board. A higher protection level can be achieved with an external high pass filter, consists of a 15 pF capacitor (e.g. the Murata GRM1555C1H150JA01) and a 39 nH coil (e.g. Murata LQG15HN39NJ02) connected to the ANT port. The antenna detection functionality will be not provided implementing this high pass filter for ESD protection on the ANT port. Choose an antenna with optimal radiating characteristics for the best electrical performance and overall module functionality. An internal antenna, integrated on the application board, or an external antenna, connected to the application board through a proper 50 Ω connector, can be used. See section 2.4 and 2.2.1.1 for further details regarding antenna guidelines.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-36.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 37 of 118 The recommendations of the antenna producer for correct installation and deployment (PCB layout and matching circuitry) must be followed. If an external antenna is used, the PCB-to-RF-cable transition must be implemented using either a suitable 50 Ω connector, or an RF-signal solder pad (including GND) that is optimized for 50 Ω characteristic impedance. If antenna supervisor functionality is required, the antenna should have built in DC diagnostic resistor to ground to get proper antenna detection functionality (See section 2.4.3 Antenna detection functionality). 1.8 SIM interface An SIM card interface is provided on the board-to-board pins of the module. High-speed SIM/ME interface is implemented as well as automatic detection of the required SIM supporting voltage. Both 1.8 V and 3 V SIM types are supported: activation and deactivation with automatic voltage switch from 1.8 to 3 V is implemented, according to ISO-IEC 78-16-e specifications. The SIM driver supports the PPS (Protocol and Parameter Selection) procedure for baud-rate selection, according to the values determined by the SIM card. Table 15 describes the pins related to the SIM interface: Name Description Remarks VSIM SIM supply 1.80 V typical or 2.85 V typical automatically generated by the module SIM_CLK SIM clock 3.25 MHz clock frequency SIM_IO SIM data Internal 4.7 kΩ pull-up to VSIM SIM_RST SIM reset Table 15: SIM Interface pins A low capacitance (i.e. less than 10 pF) ESD protection device (e.g. Infineon ESD8V0L2B-03L or AVX USB0002RP or AVX USB0002DP) must be placed near the SIM card holder on each line (VSIM, SIM_IO, SIM_CLK, SIM_RST). SIM interface pins ESD sensitivity rating is 1 kV (HBM JESD22-A114F): higher protection level is required if the lines are connected to a SIM card holder/connector, so they are externally accessible on the application board. For more details about the general precautions for ESD immunity about SIM pins, see section 2.5.1. Figure 20 shows the minimal circuit connecting the LEON-G100 and the SIM card. This shows the VSIM supply connected to the VPP pin (contact C6) of the SIM card as well as VCC (contact C1). Providing VPP was a requirement for 5 V cards, but under 3GPP TS 51.011 specification [17], 3 V and 1.8 V SIM cards do not require VPP and the mobile equipment (ME) need not provide contact C6. If the ME provides contact C6, then it can either provide the same voltage as on VCC or it can leave the signal open, but it cannot connect VPP to GND.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-37.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 39 of 118 1.9 Serial communication 1.9.1 Asynchronous serial interface (UART) The UART interface is a 9-wire unbalanced asynchronous serial interface that provides an AT commands interface, GPRS data and CSD data, software upgrades. The UART interface provides RS-232 functionality conforming with ITU-T V.24 Recommendation [4], with CMOS compatible signal levels: 0 V for low data bit or ON state, and 2.85 V for high data bit or OFF state. An external voltage translator (Maxim MAX3237) is required to provide RS-232 compatible signal levels. For the detailed electrical characteristics refer to the LEON-G1 series Data Sheet [1]. LEON-G1 series modules are designed to operate as a GSM/GPRS modem, which represents the data circuit-terminating equipment (DCE) as described by the ITU-T V.24 Recommendation [4]. A customer application processor connected to the module through the UART interface represents the data terminal equipment (DTE). The signal names of the LEON-G100 UART interface conform to ITU-T V.24 Recommendation [4]. The UART interface includes the following lines: Name Description Remarks DSR Data set ready Module output, functionality of ITU-T V.24 Circuit 107 (Data set ready) RI Ring Indicator Module output, functionality of ITU-T V.24 Circuit 125 (Calling indicator) DCD Data carrier detect Module output, functionality of ITU-T V.24 Circuit 109 (Data channel received line signal detector) DTR Data terminal ready Module input, functionality of ITU-T V.24 Circuit 108/2 (Data terminal ready) Internal active pull-up to 2.85 V enabled. RTS Ready to send Module hardware flow control input, functionality of ITU-T V.24 Circuit 105 (Request to send) Internal active pull-up to 2.85 V enabled. CTS Clear to send Module hardware flow control output, functionality of ITU-T V.24 Circuit 106 (Ready for sending) TxD Transmitted data Module data input, functionality of ITU-T V.24 Circuit 103 (Transmitted data) Internal active pull-up to 2.85 V enabled. RxD Received data Module data output, functionality of ITU-T V.24 Circuit 104 (Received data) Table 17: UART pins UART interface pins ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the lines are externally accessible on the application board. A higher protection level can be achieved mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the lines connected to these pins if they are externally accessible on the application board. 1.9.1.1 UART features UART interface is controlled and operated with: AT commands according to 3GPP TS 27.007 [5] AT commands according to 3GPP TS 27.005 [6] AT commands according to 3GPP TS 27.010 [7] u-blox AT commands](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-39.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 40 of 118 All flow control handshakes are supported by the UART interface and can be set by appropriate AT commands (see u-blox AT Commands Manual [2], AT&K command): hardware flow control (RTS/CTS), software flow control (XON/XOFF), or no flow control. Autobauding is supported. It can be enabled or disabled by an AT command (see u-blox AT Commands Manual [2], AT+IPR command). Autobauding is enabled by default. Hardware flow control is enabled by default. For the complete list of supported AT commands and their syntax refer to the u-blox AT Commands Manual [2]. Autobauding result can be unpredictable with spurious data if idle-mode (power-saving) is entered and the hardware flow control is disabled. The following baud rates can be configured using AT commands: 2400 b/s 4800 b/s 9600 b/s 19200 b/s 38400 b/s 57600 b/s 115200 b/s (default value when autobauding is disabled) The following baud-rates are available with autobauding only: 1200 b/s 230400 b/s Automatic frame recognition is supported: this feature is enabled in conjunction with autobauding only, which is enabled by default. The frame format can be: 8N2 (8 data bits, No parity, 2 stop bits) 8E1 (8 data bits, even parity, 1 stop bit) 8O1 (8 data bits, odd parity, 1 stop bit) 8N1 (8 data bits, No parity, 1 stop bit) 7E1 (7 data bits, even parity, 1 stop bit) 7O1 (7 data bits, odd parity, 1 stop bit) The default frame configuration with fixed baud rate is 8N1, described in the Figure 21. D0 D1 D2 D3 D4 D5 D6 D7Start of 1-BytetransferStart Bit(Always 0)Possible Start ofnext transferStop Bit(Always 1)tbit = 1/(Baudrate)Normal Transfer, 8N1 Figure 21: UART default frame format (8N1) description](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-40.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 41 of 118 1.9.1.2 UART signal behavior (AT commands interface case) See Table 4 for a description of operating modes and states referred to in this section. At the module switch-on, before the initialization of the UART interface (each pin is first tristated and then set to its corresponding reset state reported in the pin description table in the LEON-G1 series Data Sheet [1] (see the power on sequence description in Figure 15). At the end of the boot sequence, the UART interface is initialized, the module is by default in active mode and the UART interface is enabled. The configuration and the behavior of the UART signals after the boot sequence are described below. For a complete description of data and command mode, refer to u-blox AT Commands Manual [2]. RxD signal behavior The module data output line (RxD) is set by default to OFF state (high level) at UART initialization. The module holds RxD in OFF state until no data is transmitted by the module. TxD signal behavior The module data input line (TxD) is set by default to OFF state (high level) at UART initialization. The TxD line is then held by the module in the OFF state if the line is not activated by the DTE: an active pull-up is enabled inside the module on the TxD input. CTS signal behavior The module hardware flow control output (CTS line) is set to the ON state (low level) at UART initialization. If the hardware flow control is enabled (for more details refer to u-blox AT Commands Manual [2], AT&K, AT\Q, AT+IFC commands) the CTS line indicates when the module is in active mode and the UART interface is enabled: the module drives the CTS line to the ON state or to the OFF state when it is either able or not able to accept data from the DTE (see section 1.9.1.3 for the complete description). If the hardware flow control is not enabled, the CTS line is always held in the ON state after UART initialization. When the power saving configuration is enabled and the hardware flow-control is not implemented in the DTE/DCE connection, data sent by the DTE can be lost: the first character sent when the module is in idle-mode will not be a valid communication character (see section 1.9.1.3 for the complete description). During the MUX mode, the CTS line state is mapped to FCon / FCoff MUX command for flow control issues outside the power saving configuration while the physical CTS line is still used as a power state indicator. For more details refer to Mux Implementation Application Note [15]. RTS signal behavior The hardware flow control input (RTS line) is set by default to the OFF state (high level) at UART initialization. The RTS line is then held by the module in the OFF state if the line is not activated by the DTE: an active pull-up is enabled inside the module on the RTS input. If the HW flow control is enabled (for more details refer to u-blox AT Commands Manual [2] AT&K, AT\Q, AT+IFC commands) the RTS line is monitored by the module to detect permission from the DTE to send data to the DTE itself. If the RTS line is set to OFF state, any on-going data transmission from the module is interrupted or any subsequent transmission forbidden until the RTS line changes to ON state. The DTE must be able to still accept a certain number of characters after the RTS line has been set to OFF state: the module guarantees the transmission interruption within 2 characters from RTS state change. If AT+UPSV=2 is set and HW flow control is disabled, the RTS line is monitored by the module to manage the power saving configuration:](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-41.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 42 of 118 When an OFF-to-ON transition occurs on the RTS input line, the module switches from idle-mode to active-mode after 20 ms and the module does not enter idle-mode until the RTS input line is held in the ON state If RTS is set to OFF state by the DTE, the module automatically enters idle-mode whenever possible as in the AT+UPSV=1 configuration (cyclic idle/active mode) For more details see section 1.9.1.3 and u-blox AT Commands Manual [2], AT+UPSV command. DSR signal behavior If AT&S0 is set, the DSR module output line is set by default to ON state (low level) at UART initialization and is then always held in the ON state. If AT&S1 is set, the DSR module output line is set by default to OFF state (high level) at UART initialization. The DSR line is then set to the OFF state when the module is in command mode and is set to the ON state when the module is in data mode. DTR signal behavior The DTR module input line is set by default to OFF state (high level) at UART initialization. The DTR line is then held by the module in the OFF state if the line is not activated by the DTE: an active pull-up is enabled inside the module on the DTR input. Module behavior according to DTR status depends on the AT command configuration (see u-blox AT Commands Manual [2], AT&D command). DCD signal behavior If AT&C0 is set, the DCD module output line is set by default to ON state (low level) at UART initialization and is then always held in the ON state. If AT&C1 is set, the DCD module output line is set by default to OFF state (high level) at UART initialization. The DCD line is then set by the module in accordance with the carrier detect status: ON if the carrier is detected, OFF otherwise. In case of voice call DCD is set to ON state when the call is established. For a data call there are the following scenarios: GPRS data communication: Before activating the PPP protocol (data mode) a dial-up application must provide the ATD*99***<context_number># to the module: with this command the module switches from command mode to data mode and can accept PPP packets. The module sets the DCD line to the ON state, then answers with a CONNECT to confirm the ATD*99 command. The DCD ON is not related to the context activation but with the data mode CSD data call: To establish a data call the DTE can send the ATD<number> command to the module which sets an outgoing data call to a remote modem (or another data module). Data can be transparent (non reliable) or non transparent (with the reliable RLP protocol). When the remote DCE accepts the data call, the module DCD line is set to ON and the CONNECT <communication baudrate> string is returned by the module. At this stage the DTE can send characters through the serial line to the data module which sends them through the network to the remote DCE attached to a remote DTE RI signal behavior The RI module output line is set by default to the OFF state (high level) at UART initialization. Then, during an incoming call, the RI line is switched from OFF state to ON state with a 4:1 duty cycle and a 5 s period (ON for 1 s, OFF for 4 s, see Figure 22), until the DTE attached to the module sends the ATA string and the module accepts the incoming data call. The RING string sent by the module (DCE) to the serial port at constant time intervals is not correlated with the switch of the RI line to the ON state.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-42.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 43 of 118 Figure 22: RI behavior during an incoming call The RI line can notify an SMS arrival. When the SMS arrives, the RI line switches from OFF to ON for 1 s (see Figure 23), if the feature is enabled by the proper AT command (refer to u-blox AT Commands Manual [2], AT+CNMI command). Figure 23: RI behavior at SMS arrival This behavior allows the DTE to remain in power saving mode until the DCE related event requests service. If more than one SMS arrives coincidently or in quick succession the RI line will be independently triggered, although the line will not be deactivated between each event. As a result, the RI line may remain in the ON state for more than 1 second. If an incoming call is answered within less than 1 second (with ATA or if auto-answering is set to ATS0=1) then the RI line will be set to OFF earlier. As a result: RI line monitoring cannot be used by the DTE to determine the number of received SMSes In case of multiple events (incoming call plus SMS received), the RI line cannot be used to discriminate between the two events, but the DTE must rely on the subsequent URCs and interrogate the DCE with the proper commands 1.9.1.3 UART and power-saving The AT+UPSV command controls the power saving configuration. When the power saving is enabled, the module automatically enters idle-mode whenever possible, otherwise the active-mode is maintained by the module. The AT+UPSV command sets the module power saving configuration, but also configures the UART behavior in relation to the power saving configuration. The conditions for the module entering idle-mode also depend on the UART power saving configuration. The following subsections and the Table 18 describe the different power saving configurations that can be set by the AT+UPSV command. For more details on the +UPSV command description, refer to u-blox AT commands Manual [2]. SMS arrives time [s] 0 RI ON RI OFF 1s SMS time [s] 0 RI ON RI OFF 1s 1stime [s]151050RI ONRI OFFCall incomes1stime [s]151050RI ONRI OFFCall incomes](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-43.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 45 of 118 Every subsequent character received during the active-mode, resets and restarts the timer; hence the active-mode duration can be extended indefinitely. The behavior of hardware flow-control output (CTS line) during normal module operations with power-saving and HW flow control enabled (cyclic idle-mode and active-mode) is illustrated in Figure 24. Figure 24: CTS behavior with power saving enabled: the CTS line indicates when the module is able (CTS = ON = low level) or not able (CTS = OFF = high level) to accept data from the DTE and communicate through the UART interface AT+UPSV=2: power saving enabled and controlled by the RTS line The module behavior is the same as for AT+UPSV=1 case if the RTS line is set to OFF by the DTE. When an OFF-to-ON transition occurs on the RTS input line, the module switches from idle-mode to active-mode after 20 ms and then the module does not enter the idle-mode until the RTS input line is held in the ON state. This configuration can only be enabled with the module HW flow control disabled. Even if HW flow control is disabled, if the RTS line is set to OFF by the DTE, the CTS line is set by the module accordingly to its power saving configuration (like for AT+UPSV=1 with HW flow control enabled). When the RTS line is set to OFF by the DTE, the timeout to enter idle-mode from the last data received at the serial port during the active-mode is the one previously set with the AT+UPSV=1 configuration or it is the default value. time [s] CTS ON CTS OFF max ~2.1 s UART disabled min ~11 ms UART enabled ~9.2 s (default) UART enabled Data input time [s] CTS ON CTS OFF max ~2.1 s UART disabled min ~11 ms UART enabled ~9.2 s (default) UART enabled](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-45.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 47 of 118 Figure 26 shows the case where in addition to the wake-up character further (valid) characters are sent. The wake up character wakes-up the DCE. The other characters must be sent after the “wake up time” of 20 ms. If this condition is met, the characters are recognized by the DCE. The DCE is allowed to re-enter idle-mode after 2000 GSM frames from the latest data reception. CTS OFFCTS ONActive mode is held for 2000 GSM frames (~9.2s) after the last data receivedtime Wake up time: up to 15.6 mstime TxD module inputWake up character Not recognized by DCEValid characters Recognized by DCE Figure 26: Wake-up via data reception with further communication The “wake-up via data reception” feature cannot be disabled. The “wake-up via data reception” feature can be used in both AT+UPSV=1 and AT+UPSV=2 case (when RTS line is set to OFF). In command mode, if autobauding is enabled and HW flow control is not implemented by the DTE, the DTE must always send a character to the module before the “AT” prefix set at the beginning of each command line: the first character will be ignored if the module is in active-mode, or it will represent the wake up character if the module is in idle-mode. In command mode, if autobauding is disabled, the DTE must always send a dummy “AT” to the module before each command line: the first character will not be ignored if the module is in active-mode (i.e. the module will reply “OK”), or it will represent the wake up character if the module is in idle-mode (i.e. the module will not reply). No wake-up character or dummy “AT” is required from the DTE during connected-mode since the module continues to be in active-mode and does not need to be woken-up. Furthermore in data mode a wake-up character or a dummy “AT” would affect the data communication. 1.9.1.4 UART application circuits Providing the full RS-232 functionality (using the complete V.24 link) For complete RS-232 functionality conforming to ITU-T Recommendation [4] in DTE/DCE serial communication, the complete UART interface of the module (DCE) must be connected to the DTE as described in Figure 27.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-47.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 50 of 118 It is highly recommended to provide on an application board a direct access to RxD and TxD lines of the module (in addition to access to these lines from an application processor). This enables a direct connection of PC (or similar) to the module for execution of Firmware upgrade over the UART. The module FW upgrade over UART (using the RxD and TxD pins) starts at the module switch-on or when the module is released from the reset state: it is suggested to provide access to the PWR_ON pin, or to provide access to the RESET_N pin, or to provide access to the enabling of the DC supply connected to the VCC pin, to start the module firmware upgrade over the UART. 1.9.1.5 MUX protocol (3GPP 27.010) The module has a software layer with MUX functionality complaint with 3GPP 27.010 [7]. This is a data link protocol (layer 2 of OSI model) using HDLC-like framing and operates between the module (DCE) and the application processor (DTE). The protocol allows simultaneous sessions over the UART. Each session consists of a stream of bytes transferring various kinds of data like SMS, CBS, GPRS, AT commands in general. This permits, for example, SMS to be transferred to the DTE when a data connection is in progress. The following channels are defined: Channel 0: control channel Channel 1 – 5: AT commands /data connection Channel 6: GNSS tunneling For more details refer to Mux implementation Application Note [15].](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-50.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 51 of 118 1.9.2 DDC (I2C) interface 1.9.2.1 Overview An I2C compatible Display Data Channel (DDC) interface for communication with u-blox GNSS receivers is available on LEON-G100 modules. This interface is intended exclusively to access u-blox GNSS receivers. Name Description Remarks SCL I2C bus clock line Fixed open drain. External pull-up required. SDA I2C bus data line Fixed open drain. External pull-up required. Table 19: DDC (I2C) pins DDC (I2C) interface pins ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the lines are externally accessible on the application board. A higher protection level can be achieved mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the lines connected to these pins if they are externally accessible on the application board. u-blox has implemented special features in LEON-G100 modules to ease the design effort required to integrate a u-blox wireless module with a u blox GNSS receiver. Combining a LEON-G100 module with a u-blox GNSS receiver allows designers full access to the GNSS receiver directly via the wireless module: it relays control messages to the GNSS receiver via a dedicated DDC (I2C) interface. A 2nd interface connected to the GNSS receiver is not necessary: AT commands via the UART serial interface of the wireless module allow full control of the GNSS receiver from any host processor. LEON-G1 series modules feature embedded u-blox GPS aiding functionalities for enhanced GNSS performance. These provide decreased Time To First Fix (TTFF) and allow faster position calculation with higher accuracy. For more details regarding the handling of the DDC (I2C) interface and the GPS aiding features refer to u-blox AT Commands Manual [2] (AT+UGPS, AT+UGPRF, AT+UGPIOC commands) and GNSS Implementation Application Note [3].](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-51.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 52 of 118 1.9.2.2 DDC application circuit General considerations The DDC (I2C) interface of the LEON-G100 modules is used only to connect the wireless module to a u-blox GNSS receiver: the DDC (I2C) interface is enabled by the AT+UGPS command only (for more details refer to u-blox AT Commands Manual [2]). The SDA and SCL lines must be connected to the DDC (I2C) interface pins of the u-blox GNSS receiver (i.e. the SDA2 and SCL2 pins of the u-blox GNSS receiver) on the application board. To be complaint with the I2C bus specifications, the module pads of the bus interface are open drain output and pull-up resistors must be used. Since the pull-up resistors are not mounted on the module, they must be mounted externally. Resistor values must conform to the I2C bus specifications [8]. If LEON-G100 modules are connected through the DDC bus to a u-blox GNSS receiver (only one device can be connected on the DDC bus), use a pull-up resistor of 4.7 k. Pull-up resistors must be connected to a supply voltage of 2.85 V (typical), since this is the voltage domain of the DDC pins (for detailed electrical characteristics see the LEON-G1 series Data Sheet [1]). DDC Slave-mode operation is not supported, the module can act as master only. Two lines, serial data (SDA) and serial clock (SCL), carry information on the bus. SCL is used to synchronize data transfers, and SDA is the data line. Since both lines are open drain outputs, the DDC devices can only drive them low or leave them open. The pull-up resistor pulls the line up to the supply rail if no DDC device is pulling it down to GND. If the pull-ups are missing, SCL and SDA lines are undefined and the DDC bus will not work. The signal shape is defined by the values of the pull-up resistors and the bus capacitance. Long wires on the bus will increase the capacitance. If the bus capacitance is increased, use pull-up resistors with nominal resistance value lower than 4.7 k, to match the I2C bus specifications [8] regarding rise and fall times of the signals. Capacitance and series resistance must be limited on the bus to match the I2C specifications [8] (1.0 µs is the maximum allowed rise time on the SCL and SDA lines): route connections as short as possible. If the pins are not used as DDC bus interface, they can be left floating on the application board. LEON-G100 modules support these GPS aiding types: Local aiding AssistNow Online AssistNow Offline AssistNow Autonomous The embedded GPS aiding features can be used only if the DDC (I2C) interface of the wireless module is connected to the u-blox GNSS receivers. The GPIO pins can handle: The power on/off of the GNSS receiver (“GNSS supply enable” function provided by GPIO2) The wake up from idle-mode when the GNSS receiver is ready to send data (“GNSS data ready” function provided by GPIO3) The RTC synchronization signal to the GNSS receiver (“GNSS RTC sharing” function provided by GPIO4) GPIO2 is by default configured to provide the “GNSS supply enable” function (parameter <gpio_mode> of AT+UGPIOC command set to 3 by default), to enable or disable the supply of the u-blox GNSS receiver connected to the wireless module by the AT+UGPS command. The pin is set as Output / High, to switch on the u-blox GNSS receiver, if the parameter <mode> of AT+UGPS command is set to 1 Output / Low, to switch off the u-blox GNSS receiver, if the parameter <mode> of AT+UGPS command is set to 0 (default setting)](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-52.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 55 of 118 1.10 Audio LEON-G1 series modules provide four analog and one digital audio interfaces: Two microphone inputs: First microphone input can be used for direct connection of the electret condenser microphone of a handset. This input is used when the main uplink audio path is “Handset Microphone” (refer to u-blox AT Commands Manual [2]; AT+USPM command: <main_uplink> parameter) Second microphone input can be used for direct connection of the electret condenser microphone of a headset. This input is used when the main uplink audio path is “Headset Microphone” (refer to u-blox AT Commands Manual [2]; AT+USPM command: <main_uplink> parameter) Two speaker outputs: First speaker output is a single ended low power audio output that can be used to directly connect the receiver (earpiece) of a handset or a headset. This output is used when the main downlink audio path is “Normal earpiece” or “Mono headset” (refer to u-blox AT Commands Manual [2]; AT+USPM command: <main_downlink> parameter). These two downlink path profiles use the same physical output but have different sets of audio parameters (refer to u-blox AT Commands Manual [2]: AT+USGC, AT+UDBF, AT+USTN commands) Second speaker output is a differential high power audio output that can be used to directly connect a speaker or a loud speaker used for ring-tones or for speech in hands-free mode. This output is used when audio downlink path is “Loudspeaker” (refer to u-blox AT Commands Manual [2]; AT+USPM command, <main_downlink> and <alert_sound> parameters) Headset detection input: If enabled, causes the automatic switch of uplink audio path to “Headset Microphone” and downlink audio path to “Mono headset”. Enabling/disabling the detection can be controlled by parameter <headset_indication> in AT+USPM command (refer to u-blox AT Commands Manual [2]) I2S digital audio interface: This path is selected when parameters <main_uplink> and <main_downlink> in AT+USPM command (refer to u-blox AT Commands Manual [2]) are respectively “I2S input line” and “I2S output line” Not all combinations of Input-Output audio paths are allowed. Check audio command AT+USPM in u-blox AT Commands Manual [2] for allowed combinations of audio path and for their switching during different use cases (speech/alert tones). The default values for audio parameters tuning commands (refer to u-blox AT Commands Manual [2]; AT+UMGC, AT+UUBF, AT+UHFP, AT+USGC, AT+UDBF, AT+USTN commands) are tuned for audio device connected as suggested above (i.e. Handset microphone connected on first microphone input, headset microphone on second microphone input). For a different connection, (i.e. connection of a Hands Free microphone) these parameters should be changed on the audio path corresponding to the connection chosen. 1.10.1 Analog audio interface 1.10.1.1 Uplink path (microphone inputs) The TX (uplink) path of the analog audio front-end on the module consists of two identical microphone circuits. Two electret condenser microphones can be directly connected to the two available microphone inputs. The main required electrical specifications for the electret condenser microphone are 2.2 k as maximum output impedance at 1 kHz and 2 V maximum standard operating voltage.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-55.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 56 of 118 LEON-G100 pins related to the uplink path (microphones inputs) are: First microphone input: MIC_BIAS1: single ended supply to the first microphone and represents the microphone signal input MIC_GND1: local ground for the first microphone Second microphone input: MIC_BIAS2: single ended supply to the second microphone and represents the microphone signal input MIC_GND2: local ground for the second microphone For a description of the internal function blocks see Figure 36. 1.10.1.2 Downlink path (speaker outputs) The RX (downlink) path of the analog audio front-end of the module consists of two speaker outputs available on the following pins: First speaker output: HS_P: low power single ended audio output. This pin is internally connected to the output of the single ended audio amplifier of the chipset Second speaker output: SPK_N/SPK_P: high power differential audio output. These two pins are internally connected to the output of the high power differential audio amplifier of the chipset See Figure 36 for a description of the internal function blocks. Warning: excessive sound pressure from headphones can cause hearing loss. Detailed electrical characteristics of the low power single-ended audio receive path and the high power differential audio receive path can be found in LEON-G1 series Data Sheet [1]. Table 21 lists the signals related to analog audio functions. Name Description Remarks HS_DET Headset detection input Internal active pull-up to 2.85 V enabled. HS_P First speaker output with low power single-ended analog audio This audio output is used when audio downlink path is “Normal earpiece“ or “Mono headset“ SPK_P Second speaker output with high power differential analog audio This audio output is used when audio downlink path is “Loudspeaker“. SPK_N Second speaker output with power differential analog audio output This audio output is used when audio downlink path is “Loudspeaker“. MIC_BIAS2 Second microphone analog signal input and bias output This audio input is used when audio uplink path is set as “Headset Microphone“. Single ended supply output and signal input for the second microphone. MIC_GND2 Second microphone analog reference Local ground of second microphone. Used for “Headset microphone” path. MIC_GND1 First microphone analog reference Local ground of the first microphone. Used for “Handset microphone” path MIC_BIAS1 First microphone analog signal input and bias output This audio input is used when audio uplink path is set as “Handset Microphone“. Single ended supply output and signal input for first microphone. Table 21: Analog Audio Signal Pins All audio lines on an application board must be routed in pairs, be embedded in GND (have the ground lines as close as possible to the audio lines), and maintain distance from noisy lines such as VCC and from components such as switching regulators.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-56.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 57 of 118 Audio pins ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the lines are externally accessible on the application board. A higher protection level can be achieved mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the lines connected to these pins if they are externally accessible on the application board. If the audio pins are not used, they can be left floating on the application board. 1.10.1.3 Handset mode Handset mode is the default audio operating mode of LEON-G1 series modules. In this mode the main uplink audio path is “Handset microphone”, the main downlink audio path is “Normal earpiece” (refer to u-blox AT Commands Manual [2]; AT+USPM command: <main_uplink>, <main_downlink> parameters). Handset microphone must be connected to inputs MIC_BIAS1/MIC_GND1 Handset receiver must be connected to output HS_P Figure 31 shows an example of an application circuit connecting a handset (with a 2.2 kΩ electret microphone and a 32 Ω receiver) to the LEON-G100 modules. The following actions should be done on the application circuit: Mount a series capacitor on the HS_P line to decouple the bias Mount a 10 µF ceramic capacitor (e.g. Murata GRM188R60J106M) if connecting a 32 Ω receiver, or a load with greater impedance (such as a single ended analog input of a codec). Otherwise if a 16 Ω receiver is connected to the line, a ceramic capacitor with greater nominal capacitance must be used: a 22 µF series capacitor (e.g. Murata GRM21BR60J226M) is required Mount a 82 nH series inductor (e.g. Murata LQG15HS82NJ02) on each microphone line and a 27 pF bypass capacitor (e.g. Murata GRM1555C1H270J) on all audio lines to minimize RF coupling and TDMA noise LEON-G100C1AUDIO HANDSET CONNECTORC2 C3J14321L1L237HS_P43MIC_GND144MIC_BIAS1C4D1 Figure 31: Handset connector application circuit Reference Description Part Number - Manufacturer C1, C2, C3 27 pF Capacitor Ceramic COG 0402 5% 25 V GRM1555C1H270JZ01 - Murata C4 10 µF Capacitor Ceramic X5R 0603 20% 6.3V GRM188R60J106M - Murata L1, L2 82 nH Multilayer inductor 0402 (self resonance frequency ~1 GHz) LQG15HS82NJ02 - Murata J1 Audio Handset Jack Connector, 4Ckt (4P4C) 52018-4416 - Molex D1 Varistor Array for ESD protection CA05P4S14THSG - EPCOS Table 22: Example of components for handset connection](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-57.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 58 of 118 1.10.1.4 Headset mode The audio path is automatically switched from handset mode to headset mode when a rising edge is detected by the module on HS_DET pin. The audio path returns to the handset mode when the line returns to low level. In headset mode the main uplink audio path is “Headset microphone”, the main downlink audio path is “Mono headset” (refer to u-blox AT Commands Manual [2]; AT+USPM command: <main_uplink>, <main_downlink> parameters). The audio path used in headset mode: Headset microphone must be connected to MIC_BIAS2/MIC_GND2 Headset receiver must be connected to HS_P Figure 32 shows an application circuit connecting a headset (with a 2.2 kΩ electret microphone and a 32 Ω receiver) to the LEON-G100 modules. Pin 2 & 5 are shorted in the headset connector, causing HS_DET to be pulled low. When the headset plug is inserted HS_DET is pulled up internally by the module, causing a rising edge for detection. Perform the following steps on the application board (as shown in Figure 32; the list of components to be mounted is shown in Table 23): Mount a series capacitor on the HS_P line to decouple the bias. 10 µF ceramic capacitor (e.g. Murata GRM188R60J106M) is required if a 32 Ω receiver or a load with greater impedance (as a single ended analog input of a codec) is connected to the line. 22 µF series capacitor (e.g. Murata GRM21BR60J226M) is required if a 16 Ω receiver is connected to the line Mount a 82 nH series inductor (e.g. Murata LQG15HS82NJ02) on each microphone line, and a 27 pF bypass capacitor (e.g. Murata GRM1555C1H270J) on all audio lines to minimize RF coupling and the TDMA noise LEON-G100C4AUDIO HEADSET CONNECTORC1 C2 C3J1253461L1L218HS_DET37HS_P42MIC_GND241MIC_BIAS2D1 Figure 32: Headset mode application circuit Reference Description Part Number - Manufacturer C1, C2, C3 27 pF Capacitor Ceramic COG 0402 5% 25 V GRM1555C1H270JZ01 - Murata C4 10 µF Capacitor Ceramic X5R 0603 20% 6.3V GRM188R60J106M - Murata L1, L2 82nH Multilayer inductor 0402 (self resonance frequency ~1 GHz) LQG15HS82NJ02 - Murata J1 Audio Headset 2.5 mm Jack Connector SJ1-42535TS-SMT - CUI, Inc. D1 Varistor Array for ESD protection CA05P4S14THSG - EPCOS Table 23: Example of components for headset jack connection](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-58.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 59 of 118 1.10.1.5 Hands-free mode Hands-free mode can be implemented using a loudspeaker and a dedicated microphone. Hands-free functionality is implemented using appropriate DSP algorithms for voice-band handling (echo canceller and automatic gain control), managed via software (Refer to u-blox AT Commands Manual [2]; AT+UHFP command). In this mode the main downlink audio path must be “Loudspeaker”, the main uplink audio path can be “Handset microphone” or “Headset microphone” (refer to u-blox AT Commands Manual [2]; AT+USPM command: <main_uplink>, <main_downlink> parameters). Use of an uplink audio path for hands-free makes it unavailable for another device (handset/headset). Therefore: Microphone can be connected to the input pins MIC_BIAS1/MIC_GND1 or MIC_BIAS2/MIC_GND2 High power loudspeaker must be connected to the output pins SPK_P/SPK_N The default parameters for audio uplink profiles “Handset microphone” and “Headset microphone” (refer to u-blox AT Commands Manual [2]; AT+UMGC, AT+UUBF, AT+UHFP) are for a handset and a headset microphone. To implement hands-free mode, these parameters should be changed on the audio path corresponding to the connection chosen. Procedure to tune parameters for hands-free mode (gains, echo canceller) can be found in LEON Audio Application Note [13]. When hands-free mode is enabled, the audio output signal on HS_P is disabled. The physical width of the high-power audio outputs lines on the application board must be wide enough to minimize series resistance. Figure 33 shows an application circuit for hands-free mode. In this example the LEON-G100 modules are connected to an 8 Ω speaker and a 2.2 kΩ electret microphone. Insert an 82 nH series inductor (e.g. Murata LQG15HS82NJ02) on each microphone line, and a 27 pF bypass capacitor (e.g. Murata GRM1555C1H270J) on all audio lines to minimize RF coupling and the TDMA noise. LEON-G100SPKC1 C2L2L1MICC3 C439SPK_N38SPK_P43MIC_GND144MIC_BIAS1 Figure 33: Hands free mode application circuit Reference Description Part Number - Manufacturer C1, C2, C3, C4 27 pF Capacitor Ceramic COG 0402 5% 25 V GRM1555C1H270JZ01 - Murata L1, L2 82nH Multilayer inductor 0402 (self resonance frequency ~1 GHz) LQG15HS82NJ02 - Murata SPK Loudspeaker MIC Active Elected Microphone Table 24: Example of components for hands-free connection](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-59.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 60 of 118 1.10.1.6 Connection to an external analog audio device MIC_BIAS1 / MIC_GND single ended analog audio inputs and the HS_P single ended analog audio output of LEON-G100 can be used to connect the module to an external analog audio device. If the external analog audio device is provided with a single ended analog audio input, the HS_P single ended output of the module must be connected to the single ended input of the external audio device by a DC-block 10 µF series capacitor (e.g. Murata GRM188R60J106M) to decouple the bias present at the module output (see HS_P common mode output voltage in the LEON-G1 series Data Sheet [1]). Use a suitable power-on sequence to avoid audio bump due to charging of the capacitor: the final audio stage should always be the last one enabled. If the external analog audio device is provided with a differential analog audio input, a proper single ended to differential circuit must be inserted from the HS_P single ended output of the module to the differential input of the external audio device. A simple application circuit is described in Figure 34: a DC-block 10 µF series capacitor (e.g. Murata GRM188R60J106M) is provided to decouple the bias present at the module output. A voltage divider is provided to correctly adapt the signal level from the module output to the external audio device input. The DC-block series capacitor acts as high-pass filter for audio signals, with cut-off frequency depending on both the values of capacitor and on the input impedance of the audio device. For example: in case of a single ended connection to 600 external device, the 10 µF capacitor will set the -3 dB cut-off frequency to 103 Hz. The high-pass filter has a low enough cut-off to not impact the audio signal frequency response. If the external analog audio device is provided with a single ended analog audio output, the MIC_BIAS1 single ended input of the module must be connected to the single ended output of the external audio device by a DC-block 10 µF series capacitor (e.g. Murata GRM188R60J106M) to decouple the bias present at the module input (see MIC_BIAS1 microphone supply characteristics in the LEON-G1 series Data Sheet [1]). If the external analog audio device is provided with a differential analog audio output, a proper differential to single ended circuit must be inserted from the differential output of the external audio device to the MIC_BIAS1 single ended input of the module. Figure 34 describes a simple application circuit: a DC-block 10 µF series capacitor (e.g. Murata GRM188R60J106M) is provided to decouple the bias present at the module input, and a voltage divider is provided to correctly adapt the signal level from the external audio device output to the module input. Use a suitable power-on sequence to avoid audio bump due to capacitor charging: the final audio stage should always be the last one enabled. Additional circuitry should be inserted depending on the external audio device characteristics. To enable the audio path corresponding to these input/output, refer to u-blox AT Commands Manual [2], AT+USPM command. To tune audio levels for the external device refer to u-blox AT Commands Manual [2], AT+USGC, AT+UMGC commands.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-60.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 62 of 118 I2S interface pins ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the lines are externally accessible on the application board. A higher protection level can be achieved mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the lines connected to these pins if they are externally accessible on the application board. The I2S interface can be can be used in two modes: PCM mode: I2Sx Normal I2S mode: I2Sy Beyond the supported transmission modality, the main difference between the PCM mode and the normal I2S mode is represented by the logical connection to the digital audio processing system integrated in the chipset firmware (see Figure 36): PCM mode provides complete audio processing functionality Normal I2S mode: digital filters, digital gains, side tone, some audio resources as tone generator, info tones (e.g. free tone, connection tone, low battery alarm), and ringer are not available The I2S interface is activated and configured using AT commands, see the u-blox AT Commands Manual [2] (AT+UI2S command). If the I2S interface is used in PCM mode, digital path parameters can be configured and saved as the normal analog paths, using appropriate path index as described in the u-blox AT Commands Manual [2]. Analog gain parameters of microphone and speakers are unused when digital path is selected. Refer to u-blox AT Commands Manual [2], AT+UI2S command for possible combinations of connections and settings. Figure 35 shows an application circuit for digital audio interface. LEON-G100 3.0V Digital Audio DeviceI2S_TXD (Output)I2S_CLK (Input)I2S_RXD (Input)I2S_WA (Input)I2S_RXDI2S_CLKI2S_TXDI2S_WA292827260 Ω0 ΩTPTP0 Ω0 ΩTPTPGNDGND Figure 35: Digital audio interface application circuit Any external signal connected to the digital audio interface must be tri-stated when the module is in power-down mode and must be tri-stated during the module power-on sequence (at least for 1500 ms after the start-up event). If the external signals connected to the digital audio interface cannot be tri-stated, insert a multi channel digital switch (e.g. Texas Instruments SN74CB3Q16244, TS5A3159, or TS5A63157) between the two-circuit connections and set to high impedance when the module is in power down mode and during the module power-on sequence. If I2S pins are not used, they can be left floating on the application board. For debug purposes, include a test point at each I2S pin also if the digital audio interface is not used.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-62.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 63 of 118 1.10.2.1 PCM mode In PCM mode I2S_TX and I2S_RX are respectively parallel to the analog front end I2S_RX and I2S_TX as internal connections to the voice processing system (see Figure 36), so resources available for analog path can be shared: Digital filters and digital gains are available in both uplink and downlink direction. They can be configured using AT commands; refer to the u-blox AT Commands Manual [2] Ringer tone and service tone are mixed on the TX path when active (downlink) The HF algorithm acts on I2S path Main features of the I2S interface in PCM mode: I2S runs in PCM - short alignment mode (configurable with AT commands) Module functions as I2S master (I2S_CLK and I2S_WA signals generated by the module) I2S_WA signal always runs at 8 kHz I2S_WA toggles high for 1 or 2 CLK cycles of synchronism (configurable), then toggles low for 16 CLK cycles of sample width. Frame length can be 1 + 16 = 17 bits or 2 + 16 = 18 bits I2S_CLK frequency depends on frame length. Can be 17 x 8 kHz = 136 kHz or 18 x 8 kHz = 144 kHz I2S_TX, I2S_RX data are 16 bit words with 8 kHz sampling rate, mono. Data are in 2’s complement notation. MSB is transmitted first When I2S_WA toggles high, first synchronization bit is always low. Second synchronism bit (present only in case of 2 bit long I2S_WA configuration) is MSB of the transmitted word (MSB is transmitted twice in this case) I2S_TX changes on I2S_CLK rising edge, I2S_RX changes on I2S_CLK falling edge 1.10.2.2 Normal I2S mode Normal I2S mode supports: 16 bits word Mono interface 8 kHz frequency Main features of I2S interface in Normal I2S mode: I2S_WA signal always runs at 8 kHz and the channel can be either high or low I2S_TX data 16 bit words with 32 bit frame and 2, dual mono (the word can be written on 2 channels). Data are in 2’s complement notation. MSB is transmitted first. The MSB is first transmitted; the bits change on I2S_CLK rising or falling edge (configurable) I2S_RX data are read on the I2S_CLK edge opposite to I2S_TX writing edge I2S_CLK frequency depends by the number of bits and number of channels so is 16 x 2 x 8 kHz = 256 kHz The modes are configurable through a specific AT command (refer to u-blox AT Commands Manual [2]) and the following parameters can be set: I2S_TX word can be written while I2S_WA is high, low or both MSB can be 1 bit delayed or non-delayed on I2S_WA edge I2S_TX data can change on rising or falling edge of I2S_CLK signal I2S_RX data read on the opposite front of I2S_CLK signal](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-63.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 65 of 118 The circular buffer is a 3000 word buffer to store and mix the voice-band samples from Midi synthesizer. The buffer has a circular structure, so that when the write pointer reaches the end of the buffer, it is wrapped to the begin address of the buffer. Two different sample-based sample rate converters are used: an interpolator, required to convert the sample-based voice-band processing sampling rate of 8 kHz to the analog audio front-end output rate of 47.6 kHz; a decimator, required to convert the circular buffer sampling rate of 47.6 kHz to the I2Sx TX or the uplink path sample rate of 8 kHz. 1.10.3.1 Audio codecs The following speech codecs are supported by firmware on the DSP: GSM Half Rate (TCH/HS) GSM Full Rate (TCH/FS) GSM Enhanced Full Rate (TCH/EFR) 3GPP Adaptive Multi Rate (AMR) (TCH/AFS+TCH/AHS) 1.10.3.2 Echo cancelation and noise reduction LEON-G1 series modules support algorithms for echo cancellation, noise suppression and automatic gain control. Algorithms are configurable with AT commands (refer to the u-blox AT Commands Manual [2]). 1.10.3.3 Digital filters and gains Audio parameters such as digital filters, digital gain, side-tone gain (feedback from uplink to downlink path) and analog gain are available for uplink and downlink audio paths. These parameters can be modified by dedicated AT commands and be saved in 2 customer profiles in the non-volatile memory of the module (refer to the u-blox AT Commands Manual [2]). 1.10.3.4 Ringer mode LEON-G100 modules support polyphonic ring tones. The ringer tones are generated by a built-in generator on the chipset and then amplified by the internal amplifier. The synthesizer output is only mono and cannot be mixed with TCH voice path (the two are mutually exclusive). To perform in-band alerting during TCH with voice path open, only Tone Generator can be used. The analog audio path used in ringer mode can be the high power differential audio output (refer to u-blox AT Commands Manual [2]; AT+USPM command, <main_downlink> and <alert_sound> parameters for alert sounds routing). In this case the external high power loudspeaker must be connected to the SPK_P/SPK_N output pins of the module as shown in the application circuit (Figure 33) described in section 1.10.1.5. 1.11 ADC input One Analog to Digital Converter input is available (ADC1) and is configurable using u-blox AT command (see u-blox AT Commands Manual [2], +UADC AT command). The resolution of this converter is 12-bit with a single ended input range. Name Description Remarks ADC1 ADC input Resolution: 12 bits. Table 27: ADC pin ADC1 pin ESD sensitivity rating is 1 kV (HBM JESD22-A114F). A higher protection level could be required if the line is externally accessible on the application board. A higher protection level can be achieved](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-65.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 66 of 118 mounting an ESD protection (e.g. EPCOS CA05P4S14THSG varistor array) on the line connected to this pin if it is externally accessible on the application board. If the ADC1 pin is not used, it can be left floating on the application board. The electrical behavior of the measurement circuit in voltage mode can be modeled by a circuit equivalent to that shown in Figure 37. This includes a resistor (Req), voltage source (Ueq), analog preamplifier (with typical gain G=0.5), and a digital amplifier (with typical gain gADC=2048 LSB/V). LEON-G100ADC1UeqReqUsigRsigUadcG5gADC Figure 37: Equivalent network for ADC single-ended measurement The ADC software driver takes care of the parameters shown in Figure 37 (Req, Ueq, G, gADC): the voltage measured by ADC1 is Uadc and its value expressed in mV is given by the AT+UADC=0 response (for more details on the AT command refer to u-blox AT Commands Manual [2]). The detailed electrical specifications of the Analog to Digital Converter input (Input voltage span, Input resistance in measurement mode Req, Internal voltage Ueq): are reported in the LEON-G1 series Data Sheet [1]. As described in the ADC equivalent network shown in Figure 37, one part of the whole ADC circuit is outside the module: the (Usig) and the (Rsig) are characteristics of the application board because they represent the Thévenin's equivalent of the electrical network developed on the application board. If an external voltage divider is implemented to increase the voltage range, check the input resistance in measurement mode (Req) of ADC1 input and all the electrical characteristics. If the Thévenin's equivalent of the voltage source (Usig) has a significant internal resistance (Rsig) compared to the input resistance in measurement mode (Req) of the ADC, this should be taken into account and corrected to properly associate the AT+UADC=0 response to the voltage source value, implementing the ADC calibration procedure suggested in the section 1.11.1 below. If the customer implements the calibration procedure on the developed application board, the influence of the internal series resistance (Rsig) of the voltage source (Usig) is taken into account in the measurement: the AT+UADC=0 response can be correctly associated to the value of the voltage source applied on the application board.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-66.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 68 of 118 1.12 General Purpose Input/Output (GPIO) LEON-G1 series modules provide some pins which can be configured as general purpose input or output, or to provide special functions via u-blox AT commands (for further details refer to u-blox AT Commands Manual [2], AT+UGPIOC, AT+UGPIOR, AT+UGPIOW, AT+UGPS, AT+UGPRF, AT+USPM). For each pin the GPIO configuration is saved in the non volatile memory. For more details refer to u-blox AT commands manual [2]. LEON-G1 series modules provide 5 general purpose input/output pins: GPIO1, GPIO2, GPIO3, GPIO4, HS_DET. The available functions are described below: GNSS supply enable: GPIO2 is by default configured by AT+UGPIOC command to enable or disable the supply of the u-blox GNSS receiver connected to the wireless module. The GPIO1, GPIO3, GPIO4 or HS_DET pins can be configured to provide the “GNSS supply enable” function, alternatively to the default GPIO2 pin, setting the parameter <gpio_mode> of AT+UGPIOC command to 3. The pin configured to provide the “GNSS supply enable” function is set as o Output / High, to switch on the u-blox GNSS receiver, if the parameter <mode> of AT+UGPS command is set to 1 o Output / Low, to switch off the u-blox GNSS receiver, if the parameter <mode> of AT+UGPS command is set to 0 (default setting) The pin configured to provide the “GNSS supply enable” function must be connected to the active-high enable pin (or the active-low shutdown pin) of the voltage regulator that supplies the u-blox GNSS receiver on the application board. GNSS data ready: GPIO3 is by default configured by AT+UGPIOC command to sense when the u-blox GNSS receiver connected to the wireless module is ready to send data by the DDC (I2C) interface. Only the GPIO3 pin can be configured to provide the “GNSS data ready” function, setting the parameter <gpio_mode> of AT+UGPIOC command to 4 (default setting). The pin configured to provide the “GNSS data ready” function is set as o Input, to sense the line status, waking up the wireless module from idle-mode when the u-blox GNSS receiver is ready to send data by the DDC (I2C) interface, if the parameter <mode> of AT+UGPS command is set to 1 and the parameter <GPS_IO_configuration> of AT+UGPRF command is set to 16 o Tri-state with an internal active pull-down enabled, otherwise (default setting) The pin must be connected to the data ready output of the u-blox GNSS receiver (i.e. the pin TxD1 of the u-blox GNSS receiver) on the application board. GNSS RTC sharing: GPIO4 is by default configured by AT+UGPIOC command to provide a synchronization timing signal to the u-blox GNSS receiver connected to the wireless module. Only the GPIO4 pin can be configured to provide the “GNSS RTC sharing” function, setting the parameter <gpio_mode> of AT+UGPIOC command to 5 (default setting). The pin configured to provide the “GNSS RTC sharing” function is set as o Output, to provide a synchronization time signal to the u-blox GNSS receiver for RTC sharing if the parameter <mode> of AT+UGPS command is set to 1 and the parameter <GPS_IO_configuration> of AT+UGPRF command is set to 32 o Output / Low, otherwise (default setting)](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-68.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information System description Page 73 of 118 1.14 Approvals For the complete list of all the certification schemes approvals of LEON-G1 series modules and the corresponding declarations of conformity, refer to the u-blox web-site (http://www.u-blox.com). 1.14.1 Product certification approval overview Product certification approval is the process of certifying that a product has passed all tests and criteria required by specifications, typically called “certification schemes” that can be divided into three distinct categories: Regulatory certification o Country specific approval required by local government in most regions and countries, as: CE (Conformité Européenne) marking for European Union FCC (Federal Communications Commission) approval for United States Industry certification o Telecom industry specific approval verifying the interoperability between devices and networks: GCF (Global Certification Forum), partnership between European device manufacturers and network operators to ensure and verify global interoperability between devices and networks PTCRB (PCS Type Certification Review Board), created by United States network operators to ensure and verify interoperability between devices and North America networks Operator certification o Operator specific approval required by some mobile network operator, as: AT&T network operator in United States Even if LEON-G100 modules are approved under all major certification schemes, the application device that integrates LEON-G100 modules must be approved under all the certification schemes required by the specific application device to be deployed in the market. The required certification scheme approvals and relative testing specifications differ depending on the country or the region where the device that integrates LEON-G100 modules must be deployed, on the relative vertical market of the device, on type, features and functionalities of the whole application device, and on the network operators where the device must operate. The certification of the application device that integrates a LEON-G100 module and the compliance of the application device with all the applicable certification schemes, directives and standards are the sole responsibility of the application device manufacturer. LEON-G100 modules are certified according to all capabilities and options stated in the Protocol Implementation Conformance Statement document (PICS) of the module. The PICS, according to 3GPP TS 51.010-2 [9], is a statement of the implemented and supported capabilities and options of a device. The PICS document of the application device integrating a LEON-G100 module must be updated from the module PICS statement if any feature stated as supported by the module in its PICS document is not implemented or disabled in the application device, as for the following cases: o if any RF band is disabled by AT+UBANDSEL command o if the automatic network attach is disabled by AT+COPS command o if the module’s GPRS multi-slot class is changed by AT+UCLASS command](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-73.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Design-in Page 77 of 118 2 Design-in 2.1 Design-in checklist This section provides a design-in checklist. 2.1.1 Schematic checklist The following are the most important points for a simple schematic check: DC supply must provide a nominal voltage at VCC pin above the minimum normal operating range limit. DC supply must be capable to provide 2.5 A current bursts with maximum 400 mV voltage drop at VCC pin. VCC supply should be clean, with very low ripple/noise: suggested passive filtering parts can be inserted. Connect only one DC supply to VCC: different DC supply systems are mutually exclusive. Do no leave PWR_ON floating: add a pull-up resistor to a proper supply (i.e. V_BCKP). Check that voltage level of any connected pin does not exceed the corresponding operating range. Capacitance and series resistance must be limited on each SIM signal to match the SIM specifications. Insert the suggested low capacitance ESD protection and passive filtering parts on each SIM signal. Check UART signals direction, since the signal names follow the ITU-T V.24 Recommendation [4]. Add a proper pull-up resistor to a proper supply on each DDC (I2C) interface line, if the interface is used. Capacitance and series resistance must be limited on each line of the DDC (I2C) interface. Insert the suggested passive filtering parts on each used analog audio line. Check the digital audio interface specifications to connect a proper device. For debug purposes, add a test point on each I2S pin and on GPIO1 also if they are not used. Use transistors with at least an integrated resistor in the base pin or otherwise put a 10 kΩ resistor on the board in series to the GPIO when those are used to drive LEDs. To avoid an increase of module current consumption in power down mode, any external signals connected to the module digital pins (UART interface, HS_DET, GPIOs) must be set low or tri-stated when the module is in power down mode. Any external signal connected to the UART interface, I2S interfaces and GPIOs must be tri-stated when the module is in power-down mode, when the external reset is forced low and during the module power-on sequence (at least for 3 s after the start-up event), to avoid latch-up of circuits and let a proper boot of the module. Provide proper precautions for ESD immunity as required on the application board. All the not used pins can be left floating on the application board. 2.1.2 Layout checklist The following are the most important points for a simple layout check: Check 50 Ω impedance of ANT line. Follow the recommendations of the antenna producer for correct antenna installation and deployment (PCB layout and matching circuitry). Ensure no coupling occurs with other noisy or sensitive signals (primarily MIC signals, audio output signals, SIM signals). VCC line should be wide and short. Route VCC supply line away from sensitive analog signals. Avoid coupling of any noisy signals to microphone inputs lines.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-77.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Design-in Page 84 of 118 2.2.2 Footprint and paste mask Figure 42 and Figure 43 describe the footprint and provide recommendations for the paste mask for LEON-G100 modules. These are recommendations only and not specifications. The copper and solder masks have the same size and position. 29.5 mm [1161.4 mil]18.9 mm [744.1 mil]0.8 mm [31.5 mil]1.1 mm [43.3 mil]1.55 mm [61.0 mil]1.0 mm [39.3 mil] 0.8 mm [31.5 mil] Figure 42: LEON-G100 footprint 21.3 mm [838.6 mil]18.9 mm [744.1 mil]Stencil: 120 µm17.1 mm [673.2 mil]0.6 mm [23.6 mil]0.8 mm [31.5 mil] Figure 43: LEON-G100 paste mask To improve the wetting of the half vias, reduce the amount of solder paste under the module and increase the volume outside of the module by defining the dimensions of the paste mask to form a T-shape (or equivalent) extending beyond the Copper mask. The solder paste should have a total thickness of 120 µm. The paste mask outline needs to be considered when defining the minimal distance to the next component. The exact geometry, distances, stencil thicknesses and solder paste volumes must be adapted to the specific production processes (e.g. soldering etc.) of the customer. The bottom layer of LEON-G100 shows some unprotected copper areas for GND and VCC signals, plus GND keep-out for internal RF signals routing. Consider “No-routing” areas for the LEON-G100 footprint as follows: 1. Ground copper and signals keep-out below LEON-G100 on Application Motherboard due to VCC area, RF ANT pin and exposed GND pad on module bottom layer (see Figure 44). 2. Signals Keep-Out below module on Application Motherboard due to GND opening on LEON-G100 bottom layer for internal RF signals (see Figure 45).](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-84.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Design-in Page 91 of 118 2.4.3 Antenna detection functionality The internal antenna detect circuit is based on ADC measurement at ANT pin: the RF port is DC coupled to the ADC unit in the baseband chip which injects a DC current (30 µA for 250 µs) on ANT and measures the resulting DC voltage to evaluate the resistance from ANT pad to GND. The antenna detection is performed by the measurement of the resistance from ANT pad to GND (DC element of the GSM antenna), that is forced by the AT+UANTR command: refer to u-blox AT Commands Manual [2] for more details on how to access to this feature. To achieve good antenna detection functionality, use an RF antenna with built-in resistor from ANT signal to GND, or implement an equivalent solution with a circuit between the antenna cable connection and the radiating element as shown in Figure 50. Figure 50: Module Antenna Detection circuit and antenna with diagnostic resistor Examples of components for the antenna detection diagnostic circuit are reported in the following table: Description Part Number - Manufacturer DC Blocking Capacitor Murata GRM1555C1H220JA01 or equivalent RF Choke Inductor Murata LQG15HS68NJ02, LQG15HH68NJ02 or equivalent Resistor for Diagnostic 15kΩ 5%, various Manufacturers Table 32: Example of components for the antenna detection diagnostic circuit The DC impedance at RF port for some antennas may be a DC open (e.g. linear monopole) or a DC short to reference GND (e.g. PIFA antenna). For those antennas, without the diagnostic circuit Figure 50, the measured DC resistance will be always on the extreme of measurement range (respectively open or short), and there will be no mean to distinguish from defect on antenna path with similar characteristic (respectively: removal of linear antenna or RF cable shorted to GND for PIFA antenna). Furthermore, any other DC signal injected to the RF connection from ANT connector to radiating element will alter the measurement and produce invalid results for antenna detection. Antenna AssemblyDiagnostic CircuitApplication BoardLEON-G100ANTADCCurrent SourceRF ChokeDC BlockingFront-End RF ModuleRF ChokeDC BlockingRadiating ElementZo=50 OhmResistor for DiagnosticCoaxial Antenna CableInternal Resistor](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-91.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Design-in Page 93 of 118 2.5 ESD immunity test precautions 2.5.1 ESD immunity test overview The immunity of devices integrating LEON-G100 modules to Electro-Static Discharge (ESD) phenomenon is part of the Electro-Magnetic Compatibility (EMC) conformity, which is required for products bearing the CE marking, compliant with the R&TTE Directive (99/5/EC), with the EMC Directive (89/336/EEC) and with the Low Voltage Directive (73/23/EEC) issued by the Commission of the European Community. Compliance with these directives implies conformity to the following European Norms for device ESD immunity: ESD testing standard CENELEC EN 61000-4-2 [10] and the radio equipment standards ETSI EN 301 489-1 [11], ETSI EN 301 489-7 [12], which requirements are summarized in Table 33. The ESD immunity test is performed at the enclosure port, defined by ETSI EN 301 489-1 [11] as the physical boundary through which the electromagnetic field radiates. If the device implements an integral antenna, the enclosure port is defined as all insulating and conductive surfaces housing the device. If the device implements a removable antenna, the antenna port can be separated from the enclosure port. The antenna port includes the antenna element and its interconnecting cable surfaces. The applicability of the ESD immunity test to the whole device depends on the device classification as defined by the ETSI EN 301 489-1 [11]. Applicability of the ESD immunity test to the relative device ports or the relative interconnecting cables to auxiliary equipments, depends on device accessible interfaces and manufacturer requirements, as defined by ETSI EN 301 489-1 [11]. Contact discharges are performed at conductive surfaces, while air discharges are performed at insulating surfaces. Indirect contact discharges are performed on the measurement setup horizontal and vertical coupling planes as defined in CENELEC EN 61000-4-2 [10]. For the definition of integral antenna, removable antenna, antenna port, device classification see the ETSI EN 301 489-1 [11], while for the definition of contact and air discharges see CENELEC EN 61000-4-2 [10] Application Category Immunity Level All exposed surfaces of the radio equipment and ancillary equipment in a representative configuration Contact Discharge 4 kV Air Discharge 8 kV Table 33: EMC / ESD immunity requirements as defined by CENELEC EN 61000-4-2, ETSI EN 301 489-1, ETSI EN 301 489-7 2.5.2 ESD immunity test of u-blox LEON-G1 series reference design Although Electro-Magnetic Compatibility (EMC) certification is required for customized devices integrating a LEON-G1 series module for R&TTED and European Conformance CE mark, EMC certification (including ESD immunity) has been successfully performed on the u-blox LEON-G1 series modules reference design according to CENELEC EN 61000-4-2 [10], ETSI EN 301 489-1 [11] and ETSI EN 301 489-7 [12] European Norms. The EMC / ESD immunity approved u-blox reference design consists of a LEON-G1 series module soldered onto a motherboard which provides supply interface, SIM card, headset and communication port. An external antenna is connected to an SMA connector provided on the motherboard for the GSM antenna. Since an external antenna is used, the antenna port can be separated from the enclosure port. The reference design is not enclosed in a box so that the enclosure port is not indentified with physical surfaces. Therefore, some test cases cannot be applied. Only the antenna port is identified as accessible for direct ESD exposure. u-blox LEON-G1 series reference design implement all the ESD precautions described in section 2.5.3.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-93.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Design-in Page 94 of 118 Table 34 reports the u-blox LEON-G1 series reference design ESD immunity test results, according to test requirements stated in the CENELEC EN 61000-4-2 [10], ETSI EN 301 489-1 [11] and ETSI EN 301 489-7 [12]. Category Application Immunity Level Remarks Contact Discharge to coupling planes (indirect contact discharge) Enclosure +4 kV / -4 kV Contact Discharges to conducted surfaces (direct contact discharge) Enclosure port Not Applicable Test not applicable to u-blox reference design because it does not provide enclosure surface. The test is applicable only to equipments providing conductive enclosure surface. Antenna port +4 kV / -4 kV Test applicable to u-blox reference design because it provides antenna with conductive & insulating surfaces. The test is applicable only to equipments providing antenna with conductive surface. Air Discharge at insulating surfaces Enclosure port Not Applicable Test not applicable to the u-blox reference design because it does not provide an enclosure surface. The test is applicable only to equipments providing insulating enclosure surface. Antenna port +8 kV / -8 kV Test applicable to u-blox reference design because it provides antenna with conductive & insulating surfaces. The test is applicable only to equipments providing antenna with insulating surface. Table 34: Enclosure ESD immunity level of u-blox LEON-G1 series modules reference design 2.5.3 ESD application circuits The application circuits described in this section are recommended and should be implemented in any device that integrates a LEON-G1 series module, according to the application board EMC / ESD classification (see ETSI EN 301 489-1 [11]), to satisfy the requirements for ESD immunity test summarized in Table 34. Antenna interface The ANT pin of LEON-G1 series modules provides ESD immunity up to ±4 kV for direct Contact Discharge and up to ±8 kV for Air Discharge as specified in the LEON-G1 series Data Sheet [1]: no further precaution to ESD immunity test is needed, as implemented in the EMC / ESD approved LEON-G1 series modules reference design. The antenna interface application circuit implemented in the EMC / ESD approved reference designs of LEON-G1 series modules is described in Figure 39 and/or Figure 50, which makes available the support of the antenna detection functionality: even if an external high pass filter, e.g. consisting of a series 15 pF capacitor (Murata GRM1555C1H150JA01) and a shunt 39 nH coil (Murata LQG15HN39NJ02), may be connected to the ANT pin, it is not required for EMC / ESD immunity purpose so that antenna detection functionality can be used and at the same time good EMC / ESD immunity can be available. RESET_N pin A series Schottky diode is integrated in LEON-G100 modules as protection on the RESET_N pin. The external circuit must be able to cause a current flow through the series diode to determine the RESET_N state. Sensitive interface is the reset line (RESET_N pin): A 47 pF bypass capacitor (e.g. Murata GRM1555C1H470JA01) have to be mounted on the line termination connected to the RESET_N pin to avoid a module reset caused by an electrostatic discharge applied to the application board enclosure](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-94.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Design-in Page 96 of 118 Maximum ESD sensitivity rating of SIM interface pins is 1 kV (Human Body Model according to JESD22-A114). Higher protection level could be required if SIM interface pins are externally accessible on the application board. The following precautions are suggested to achieve higher protection level: A low capacitance (i.e. less than 10 pF) ESD protection device (e.g. Tyco Electronics PESD0402-140, AVX USB0002RP or USB0002DP) should be mounted on each SIM interface line, close to accessible points (i.e. close to the SIM card holder) The SIM interface application circuit implemented in the EMC / ESD approved reference designs of LEON-G1 series modules is described in Figure 20 and Table 16 (section 1.8). Other pins and interfaces All the module pins that are externally accessible on the device integrating LEON-G1 series module should be included in the ESD immunity test since they are considered to be a port as defined in ETSI EN 301 489-1 [11]. Depending on applicability, to satisfy ESD immunity test requirements according to ESD category level, all the module pins that are externally accessible should be protected up to ±4 kV for direct Contact Discharge and up to ±8 kV for Air Discharge applied to the enclosure surface. The maximum ESD sensitivity rating of all the other pins of the module is 1 kV (Human Body Model according to JESD22-A114). Higher protection level could be required if the related pin is externally accessible on the application board. The following precautions are suggested to achieve higher protection level: A general purpose ESD protection device (e.g. EPCOS CA05P4S14THSG or EPCOS CT0402S14AHSG varistor) should be mounted on the related line, close to accessible point](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-96.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Feature description Page 97 of 118 3 Feature description 3.1 Network indication The GPIO1, or GPIO2, GPIO3, GPIO4 and HS_DET can be changed from their default settings and be configured to indicate network status (i.e. no service, registered home network, registered visitor network, voice or data call enabled), by means of the AT+UGPIOC command. For the detailed description, refer to section 1.12 and to u-blox AT Commands Manual [2], GPIO commands. 3.2 Antenna detection Antenna presence is detected by evaluating the resistance from the ANT pin to GND by means of an internal antenna detection circuit. The external antenna assembly must be provided with a built-in resistor (diagnostic circuit) to be detected. The antenna detection feature can be enabled through the +UANTR AT command. For more details regarding feature description and diagnostic circuit design-in refer to section 2.4.3, and to the u-blox AT Commands Manual [2]. 3.3 Jamming detection In real network situations modules can experience various kind of out-of-coverage conditions: limited service conditions when roaming to networks not supporting the specific SIM, limited service in cells which are not suitable or barred due to operators’ choices, no cell condition when moving to poorly served or highly interfered areas. In the latter case, interference can be artificially injected in the environment by a noise generator covering a given spectrum, thus obscuring the operator’s carriers entitled to give access to the GSM service. The Jamming Detection Feature detects such “artificial” interference and reports the start and stop of such condition to the client, which can react appropriately by e.g. switching off the radio transceiver in order to reduce the power consumption and monitoring the environment at constant periods. The feature consists in detecting, at radio resource level, an anomalous source of interference and signaling it to the client with an unsolicited indication when the detection is entered or released. The jamming condition occurs when: The module has lost synchronization with the serving cell and cannot select any other cell The band scan reveals at least n carriers with power level equal or higher than threshold On all such carriers, no synchronization is possible The number of minimum disturbing carriers and the power level threshold can be configured by the client by using the AT+UCD command [2]. The jamming condition is cleared when any of the above mentioned statements does not hold. The congestion (i.e. jamming) detection feature can be enabled and configured by the +UCD AT command (for more details refer to the u-blox AT Commands Manual [2]). 3.4 Firewall The firewall feature allows the LEON-G100 user to reject incoming connections originated from IP addresses different from the specified list and inserted in a black list.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-97.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Feature description Page 98 of 118 3.5 TCP/IP Via the AT commands it is possible to access the TCP/IP functionalities over the GPRS connection. For more details about AT commands see the u-blox AT Commands Manual [2]. 3.5.1 Multiple IP addresses and sockets Using LEON-G100’s embedded TCP/IP or UDP/IP stack, only 1 IP instance (address) is supported. The IP instance supports up to 16 sockets. Using an external TCP/IP stack (on the application processor), it is possible to have 3 IP instances (addresses). 3.6 FTP LEON-G1 series modules support the File Transfer Protocol functionalities via AT commands. Files are read and stored in the local file system of the module. For more details about AT commands see the u-blox AT Commands Manual [2]. 3.7 HTTP HTTP client is implemented in LEON. HEAD, GET, POST, DELETE and PUT operations are available. The file size to be uploaded / downloaded depends on the free space available in the local file system (FFS) at the moment of the operation. Up to 4 HTTP client contexts can be used simultaneously. For more details about AT commands see the u-blox AT Commands Manual [2]. 3.8 SMTP LEON-G1 series modules support SMTP client functionalities. It is possible to specify the common parameters (e.g. server data, authentication method, etc.), for sending an email to a SMTP server. E-mails can be sent with or without attachments. Attachments are stored in the local module file system. For more details about AT commands see the u-blox AT Commands Manual [2]. 3.9 AssistNow clients and GNSS integration LEON-G1 series modules feature embedded AssistNow clients for customers using u-blox GNSS receivers. AssistNow A-GPS provides better GNSS performance and faster Time-To-First-Fix. The clients can be enabled and disabled with an AT command (see the u-blox AT Commands Manual [2]). The LEON-G100 module acts as a stand-alone AssistNow client, making AssistNow available with no additional requirements for resources or software integration on an external host micro controller. Full access to u-blox GNSS receivers is available via the LEON-G100 wireless modules, through a dedicated DDC (I2C) interface, while the available GPIOs can handle the positioning chipset / module power-on/off. This means that the wireless module and the positioning chipset / module can be controlled through a single serial port from any host processor. For information about implementing u-blox GNSS with LEON-G100 modules, including using u-blox’ AssistNow Assisted GPS (A-GPS) service, see the GNSS Integration Application Note [3].](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-98.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Feature description Page 101 of 118 been triggered and the GNSS receiver calculates the position, a database self-learning mechanism has been implemented so that these positions are sent to the server to update the database and maintain its accuracy. The use of hybrid positioning requires a connection via the DDC (I2C) bus between the LEON-G100 module and the u-blox GNSS receiver (see section 1.9.2). Refer to GNSS application note [3] for the complete description of the feature. u-blox is extremely mindful of user privacy. When a position is sent to the CellLocateTM server u-blox is unable to track the SIM used or the specific device. 3.11 Firmware (upgrade) Over AT (FOAT) Firmware upgrades are available to LEON-G100 modules by means of AT commands. 3.11.1 Overview This feature allows the upgrade of module Firmware over UART, using AT commands. The AT+UFWUPD command triggers a reboot followed by an upgrade procedure at specified baud rate (refer to u-blox AT Commands Manual [2] for more details) The Xmodem-1k protocol is used for downloading the new Firmware image via a terminal application A special boot loader on the module performs Firmware installation, security verifications and module reboot Firmware authenticity verification is performed via a security signature during the download. Firmware is then installed, overwriting the current version. In case of power loss during this phase, the boot loader detects a fault at the next wake-up, and restarts the Firmware download from the Xmodem-1k handshake. After completing the upgrade, the module is reset again and wakes-up in normal boot 3.11.2 FOAT procedure The application processor must proceed in the following way: Send the AT+UFWUPD command through the UART, specifying the file type and the desired baud rate Reconfigure the serial communication at the selected baud rate, without flow control with the Xmodem-1k protocol Send the new FW image via Xmodem-1k](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-101.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Feature description Page 102 of 118 3.12 Smart temperature management Wireless modules – independent of the specific model – always have a well-defined operating temperature range. This range should be respected to guarantee full device functionality and long life span. Nevertheless, there are environmental conditions that can affect operating temperature, e.g. if the device is located near a heating/cooling source, if there is/is not air circulating, etc. The module itself can also influence the environmental conditions; such as when it is transmitting at full power. In this case its temperature increases very quickly and can raise the temperature nearby. The best solution is always to properly design the system where the module is integrated. Even so, an extra check/security mechanism embedded into the module is a good solution to prevent operation of the device outside of the specified range. 3.12.1 Smart Temperature Supervisor (STS) The Smart Temperature Supervisor is activated and configured by a dedicated AT+USTS command. For more details refer to the u-blox AT Commands Manual [2]. The wireless module measures the internal temperature (Ti) and its value is compared with predefined thresholds to identify the actual working temperature range. Temperature measurement is done inside the wireless module: the measured value could be different from the environmental temperature (Ta). Warningareat-1 t+1 t+2t-2Valid temperature rangeSafeareaDangerousarea Dangerousarea Warningarea Figure 52: Temperature range and limits The entire temperature range is divided into sub-regions by limits (see Figure 52) named t-2, t-1, t+1 and t+2. Within the first limit, (t-1 < Ti < t+1), the wireless module is in the normal working range, the Safe Area In the Warning Area, (t-2 < Ti < t.1) or (t+1 < Ti < t+2), the wireless module is still inside the valid temperature range, but the measured temperature approaches the limit (upper or lower). The module sends a warning to the user (through the active AT communication interface), which can take, if possible, the necessary actions to return to a safer temperature range or simply ignore the indication. The module is still in a valid and good working condition The device working outside the valid temperature range, (Ti < t-2) or (Ti > t+2), represents a dangerous working condition. This condition is indicated and the device shuts down to avoid damage For security reasons the shutdown is suspended in case an emergency call in progress. In this case the device will switch off at call termination. The user can decide at anytime to enable/disable the Smart Temperature Supervisor feature. If the feature is disabled there is no embedded protection against disallowed temperature conditions. Figure 53 shows the flow diagram implemented in the LEON-G100 modules for the Smart Temperature Supervisor.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-102.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Feature description Page 104 of 118 3.12.2 Threshold definitions When the wireless module application operates at extreme temperatures with Smart Temperature Supervisor activated, the user should note that outside the valid temperature range the device will automatically shut down as described above. The input for the algorithm is always the temperature measured within the wireless module (Ti, internal). This value can be higher than the working ambient temperature (Ta, ambient), since (for example) during transmission at maximum power a significant fraction of DC input power is dissipated as heat This behavior is partially compensated by the definition of the upper shutdown threshold (t+2) that is slightly higher than the declared environmental temperature limit. Table 36 defines the temperature thresholds. Symbol Parameter Temperature Remarks t-2 Low temperature shutdown –40 °C Equal to the absolute minimum temperature rating for the wireless module t-1 Low temperature warning –30 °C 10°C above t-2 t+1 High temperature warning +85 °C 15°C below t+2. The higher warning area for upper range ensures that any countermeasures used to limit the thermal heating will become effective, even considering some thermal inertia of the complete assembly. t+2 High temperature shutdown +100 °C Equal to the internal temperature Ti measured in the worst case operating condition at typical supply voltage when the ambient temperature Ta equals the absolute maximum temperature rating Table 36: thresholds definition for Smart Temperature Supervisor 3.13 In-Band modem (eCall / ERA-GLONASS) Not supported by LEON-G100-06S version. The LEON-G100 module supports an In-Band modem solution for eCall and ERA-GLONASS emergency call applications over cellular networks, implemented according to 3GPP TS 26.267 [18], BS EN 16062:2011 [19] and ETSI TS 122 101 [20] specifications. eCall (European) and ERA-GLONASS (Russian) are initiatives to combine mobile communications and satellite positioning to provide rapid assistance to motorists in the event of a collision, implementing automated emergency response system based the first on GPS the latter on GLONASS positioning system. When activated, the in-vehicle systems (IVS) automatically initiate an emergency call carrying both voice and data (including location data) directly to the nearest Public Safety Answering Point (PSAP) to determine whether rescue services should be dispatched to the known position. Figure 54: eCall and ERA-GLONASS automated emergency response systems diagram flow](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-104.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Feature description Page 105 of 118 3.14 Power saving The power saving configuration is by default disabled, but it can be enabled using the AT+UPSV command. When power saving is enabled, the module automatically enters the low power idle-mode whenever possible, reducing current consumption. During low power idle-mode, the module is not ready to communicate with an external device by means of the application interfaces, since it is configured to reduce power consumption. It can be woken up from idle-mode to active-mode by the connected application processor, by the connected u-blox positioning receiver or by network activities, as described in Table 4. During idle-mode, the module processor core runs with the RTC 32 kHz reference clock, which is generated by the internal 32 kHz oscillator. For the complete description of the AT+UPSV command, refer to the u-blox AT Commands Manual [2]. For the definition and the description of LEON-G1 modules operating modes, including the events forcing transitions between the different operating modes, refer to section 1.4. For the description of current consumption in idle and active operating modes, refer to sections 1.5.3.2, 1.5.3.3. For the description of the UART settings related to module power saving configuration, refer to section 1.9.1.3.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-105.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Handling and soldering Page 106 of 118 4 Handling and soldering No natural rubbers, no hygroscopic materials nor materials containing asbestos are employed. 4.1 Packaging, shipping, storage and moisture preconditioning For information pertaining to reels and tapes, Moisture Sensitivity levels (MSD), shipment and storage information, as well as drying for preconditioning see the LEON-G1 series Data Sheet [1]. LEON-G100 modules are Electro-Static Discharge (ESD) sensitive devices. Ensure ESD precautions are implemented during handling of the module. 4.2 Soldering 4.2.1 Soldering paste Use of "No Clean" soldering paste is strongly recommended, as it does not require cleaning after the soldering process has taken place. The paste listed in the example below meets these criteria. Soldering Paste: OM338 SAC405 / Nr.143714 (Cookson Electronics) Alloy specification: 95.5% Sn / 3.9% Ag / 0.6% Cu (95.5% Tin / 0.6 % Silver / 0.6% Copper) 95.5% Sn / 4.0% Ag / 0.5% Cu (95.5% Tin / 4.0 % Silver / 0.5% Copper) Melting Temperature: 217°C Stencil Thickness: 120 µm for base boards The final choice of the soldering paste depends on the approved manufacturing procedures. The paste-mask geometry for applying soldering paste should meet the recommendations in section 2.2.2 The quality of the solder joints on the connectors (’half vias’) should meet the appropriate IPC specification. 4.2.2 Reflow soldering A convection type-soldering oven is strongly recommended over the infrared type radiation oven. Convection heated ovens allow precise control of the temperature and all parts will be heated up evenly, regardless of material properties, thickness of components and surface color. Consider the "IPC-7530 Guidelines for temperature profiling for mass soldering (reflow and wave) processes, published 2001". Reflow profiles are to be selected according to the following recommendations. Failure to observe these recommendations can result in severe damage to the device! Be aware that IPC/JEDEC J-STD-020 applies to integrated circuits, cannot be properly applied to module devices.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-106.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Handling and soldering Page 107 of 118 Preheat phase Initial heating of component leads and balls. Residual humidity will be dried out. This preheat phase will not replace prior baking procedures. Temperature rise rate: max 3°C/s If the temperature rise is too rapid in the preheat phase it may cause excessive slumping. Time: 60 – 120 s If the preheat is insufficient, rather large solder balls tend to be generated. Conversely, if performed excessively, fine balls and large balls will be generated in clusters. End Temperature: 150 - 200°C If the temperature is too low, non-melting tends to be caused in areas containing large heat capacity. Heating/ reflow phase The temperature rises above the liquidus temperature of 217°C. Avoid a sudden rise in temperature as the slump of the paste could become worse. Limit time above 217°C liquidus temperature: 40 - 60 s Peak reflow temperature: 245°C Cooling phase A controlled cooling avoids negative metallurgical effects (solder becomes more brittle) of the solder and possible mechanical tensions in the products. Controlled cooling helps to achieve bright solder fillets with a good shape and low contact angle. Temperature fall rate: max 4°C / s To avoid falling off, modules should be placed on the topside of the motherboard during soldering. The final soldering temperature chosen at the factory depends on additional external factors like choice of soldering paste, size, thickness and properties of the base board, etc. Exceeding the maximum soldering temperature and the maximum liquidus time limit in the recommended soldering profile may permanently damage the module. Preheat Heating Cooling[°C] Peak Temp. 245°C [°C]250 250Liquidus Temperature217 217200 20040 - 60 sEnd Temp.max 4°C/s150 - 200°C150 150max 3°C/s60 - 120 s100 Typical Leadfree 100Soldering Profile50 50050 100 150 200 250 300Elapsed time [s] Figure 55: Recommended soldering profile LEON-G1 series modules must not be soldered with a damp heat process.](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-107.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Product testing Page 111 of 118 Components assembly on the device; it should be verified that: o Communication with host controller can be established o The interfaces between module and device are working o Overall RF performance test of the device including antenna Dedicated tests can be implemented to check the device. For example, the measurement of module current consumption when set in a specified status can detect a short circuit if compared with a “Golden Device” result. Module AT commands is used to perform functional tests (communication with host controller, check SIM card interface, check communication between module and GNSS, GPIOs, ADC input, etc.) and to perform RF performance tests. 5.2.1 ‘Go/No go’ tests for integrated devices A ‘Go/No go’ test is to compare the signal quality with a “Golden Device” in a position with excellent GSM network coverage and after having dialed a call (refer to u-blox AT Commands Manual [2], AT+CSQ command: <rssi>, <ber> parameters). These kind of test may be useful as a ‘go/no go’ test but not for RF performance measurements. This test is suitable to check the communication with host controller and SIM card, the audio and power supply functionality and verify if components at antenna interface are well soldered. 5.2.2 Functional tests providing RF operation Refer to u-blox AT Commands Manual [2], for AT+UTEST command syntax description. Refer to End user test Application Note [16], for AT+UTEST command user guide, limitations and examples of use. Overall RF performance test of the device including antenna can be performed with basic instruments like standard spectrum analyzer and signal generator using an AT interface and AT+UTEST command. The AT+UTEST command gives a simple interface to set the module in Rx and Tx test modes ignoring GSM signalling protocol. The command can set the module: To transmit in a single time slot a GSM burst in a specified channel and power level In receiving mode in a specified channel to returns the measured power level](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-111.png)
![LEON-G1 series - System Integration Manual UBX-13004888 - R01 Advance Information Related documents Page 116 of 118 Related documents [1] u-blox LEON-G1 series Data Sheet, Docu No UBX-13004887 [2] u-blox AT Commands Manual, Docu No UBX-13002752 [3] GNSS Implementation Application Note, Docu No UBX-13001849 [4] ITU-T Recommendation V.24, 02-2000. List of definitions for interchange circuits between data terminal equipment (DTE) and data circuit-terminating equipment (DCE). http://www.itu.int/rec/T-REC-V.24-200002-I/en [5] 3GPP TS 27.007 - AT command set for User Equipment (UE) (Release 1999) [6] 3GPP TS 27.005 - Use of Data Terminal Equipment - Data Circuit terminating; Equipment (DTE - DCE) interface for Short Message Service (SMS) and Cell Broadcast Service (CBS) (Release 1999) [7] 3GPP TS 27.010 - Terminal Equipment to User Equipment (TE-UE) multiplexer protocol (Release 1999) [8] The I2C-bus specification and user manual - Rev. 5 - 9 October 2012 - NXP Semiconductors, http://www.nxp.com/documents/user_manual/UM10204.pdf [9] 3GPP TS 51.010-2 – Technical Specification Group GSM/EDGE Radio Access Network; Mobile Station (MS) conformance specification; Part 2: Protocol Implementation Conformance Statement (PICS) [10] CENELEC EN 61000-4-2 (2001): "Electromagnetic compatibility (EMC) - Part 4-2: Testing and measurement techniques - Electrostatic discharge immunity test". [11] ETSI EN 301 489-1 V1.8.1: “Electromagnetic compatibility and Radio spectrum Matters (ERM); ElectroMagnetic Compatibility (EMC) standard for radio equipment and services; Part 1: Common technical requirements” [12] ETSI EN 301 489-7 V1.3.1 “Electromagnetic compatibility and Radio spectrum Matters (ERM); ElectroMagnetic Compatibility (EMC) standard for radio equipment and services; Part 7: Specific conditions for mobile and portable radio and ancillary equipment of digital cellular radio telecommunications systems (GSM and DCS)“ [13] LEON Audio Application Note, Docu No UBX-13001890 [14] Firmware Update Application Note, Docu No UBX-13001845 [15] Mux implementation Application Note in Wireless Modules, Docu No UBX-13001887 [16] End user test Application Note, Docu No UBX-13001922 [17] 3GPP TS 51.011 - Specification of the Subscriber Identity Module - Mobile Equipment (SIM-ME) interface [18] 3GPP TS 26.267 V10.0.0 – eCall Data Transfer; In-band modem solution; General description (Rel. 10) [19] BS EN 16062:2011 – Intelligent transport systems – eSafety – eCall high level application requirements [20] ETSI TS 122 101 V8.7.0 – Service aspects; Service principles (3GPP TS 22.101 v.8.7.0 Rel. 8) Part of the documents mentioned above can be downloaded from u-blox web-site (http://www.u-blox.com).](https://usermanual.wiki/u-blox/LEONG100N/User-Guide-2146472-Page-116.png)
