MobileTek Communication L218 GSM/GPRS+GNSS Module User Manual 001
Shanghai MobileTek Communication Ltd. GSM/GPRS+GNSS Module 001
15_L218 UserMan,r1
L218 Hardware Design GSM/GPRS+GNSS Series Version: V1.1 Date: 2016-12-02 Shanghai Mobiletek Communication Ltd. Notice Some features of the product and its accessories described herein rely on the software installed, capacities and settings of local network, and therefore may not be activated or may be limited by local network operators or network service providers. Thus, the descriptions herein may not exactly match the product or its accessories which you purchase. Shanghai Mobiletek Communication Ltd reserves the right to change or modify any information or specifications contained in this manual without prior notice and without any liability. Copyright This document contains proprietary technical information which is the property of Shanghai Mobiletek Communication Ltd. copying of this document and giving it to others and the using or communication of the contents thereof, are forbidden without express authority. Offenders are liable to the payment of damages. All rights reserved in the event of grant of patent or the registration of a utility model or design. All specification supplied herein are subject to change without notice at any time. DISCLAIMER ALL CONTENTS OF THIS MANUAL ARE PROVIDED “AS IS”. EXCEPT AS REQUIRED BY APPLICABLE LAWS, NO WARRANTIES OF ANY KIND, EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE, ARE MADE IN RELATION TO THE ACCURACY, RELIABILITY OR CONTENTS OF THIS MANUAL. TO THE MAXIMUM EXTENT PERMITTED BY APPLICABLE LAW, IN NO EVENT SHALL SHANGHAI MOBILETEK COMMUNICATION LTD BE LIABLE FOR ANY SPECIAL, INCIDENTAL, INDIRECT, OR CONSEQUENTIAL DAMAGES, OR LOSS OF PROFITS, BUSINESS, REVENUE, DATA, GOODWILL SAVINGS OR ANTICIPATED SAVINGS REGARDLESS OF WHETHER SUCH LOSSES ARE FORSEEABLE OR NOT. Version History Date Version Description of change 2016-09-28 V1.0 Initial 2016-12-02 V1.1 Modify the figure and table. Add the packing instructions Author Ren xue Summary This document is intended for products: L218 module. This document describes the hardware interface of the L218 module, can help user to quickly understand L218 interface specifications, electrical and mechanical details, with the help of this document users can use L218 module to design and set-up various types wireless terminals. Intended audience This document applicable to: Systems Design Engineer Structural Engineer Hardware Engineer Software Engineer Test Engineer Introduction This document contains contents as below: Chapter 1 Overview 2 Pin definitions Content Introduce L218 module basic technical SPEC. and reference standard. Introduce L218 module pin names and functions. 3 Hardware interface 4 Module structure, size, manufacturing 5 Electrical, reliability and RF Introduce L218 module hardware interface. Introduce L218 module structure, size, manufacturing. 6 Manufacturing Introduce L218 module notice of production. 7 Package information Introduce L218 module Package information. 8 Related documents List L218 module related documents. Introduce L218 module electrical, reliability and RF. CONTENTS INTRODUCTION ........................................................................................ 8 1.1 Key Features................................................................................................................................... 8 1.2 Module System Diagram ............................................................................................................... 9 APPLICATION INTERFACE .................................................................... 10 2.1 PIN Assignment ........................................................................................................................... 10 2.2 PIN Description ............................................................................................................................ 11 2.3 Functional Diagram .................................................................................................................... 12 INTERFACE CIRCUIT REFERENCE DESIGN ........................................ 13 3.1 Power ............................................................................................................................................ 13 3.1.1 Power supply .......................................................................................................................... 13 3.1.2 Power monitor ........................................................................................................................ 15 3.1.3 Power on ................................................................................................................................ 15 3.1.4 Power off ................................................................................................................................ 17 3.1.5 Reset ....................................................................................................................................... 17 3.1.6 Power saving mode ................................................................................................................ 18 3.1.7 RTC power ............................................................................................................................. 19 3.2 Audio ......................................................................................................................................... 20 3.2.1 Audio channel ........................................................................................................................ 20 3.2.2 TDD noise .............................................................................................................................. 21 3.3 UART Communication ............................................................................................................ 21 3.4 SIM Card Interface ................................................................................................................. 26 3.5 PWM Interface......................................................................................................................... 29 3.6 NETWORK Status Indicator ................................................................................................. 30 3.7 ADC Interface .......................................................................................................................... 31 3.8 GPS and BT Function.............................................................................................................. 31 3.9 Antenna Interface .................................................................................................................... 31 3.10 USB Interface ........................................................................................................................... 34 3.10.1 Pin description ..................................................................................................................... 34 3.10.2 Electrical characteristics ....................................................................................................... 34 3.10.3 USB interface applied .......................................................................................................... 34 4 MECHANICAL DIMENSIONS .................................................................... 35 5 ELECTRICAL CHARACTERISTICS .......................................................... 36 5.1 Absolute Maximum Ratings ................................................................................................... 36 5.2 Digital Interface Characteristics ............................................................................................ 36 5.3 VSIM Characteristics .............................................................................................................. 37 5.4 Current Consumption ............................................................................................................. 37 5.5 ESD ........................................................................................................................................... 37 5.6 RF performance ....................................................................................................................... 38 6 MANUFACTURING .................................................................................... 40 6.1 L218 Top And Bottom view ..................................................................................................... 40 6.2 Soldering ................................................................................................................................... 40 6.3 The Moisture Sensitivity Level (MSL) ................................................................................... 41 6.4 Baking Requirements .............................................................................................................. 41 7. PACKAGE AND STORAGE INFORMATION.......................................... 43 7.1 Package information ................................................................................................................... 43 7.1.1 Tape and reel information ................................................................................................... 43 7.1.2 Assemble and carrier information ...................................................................................... 43 7.2 Bagged storage conditions .......................................................................................................... 44 8 RELATED DOCUMENTS ........................................................................... 45 1 INTRODUCTION L218 is a quad-band GSM/GPRS+GNSS module, working frequency: GSM/GPRS850/900/1800/1900 MHz. With a tiny package of 14.5mm x 18.5mm x 2.3mm, L218 fits all the applications, such as M2M, smart phone, PDA, etc. It is a 47-pin SMT pad module, which provides rich hardware interfaces. It supports voice, SMS and data transmission with low power consumption. 1.1 Key Features Table 1-1: Main Feature GSM quad-band: 850/1900 MHz GSM 2/2+ standard – Class 4(2 W @ 850 MHz) – Class 1(1 W @ 1900MHz) AT command (GSM 07.07 ,07.05 and Enhanced AT command set) Power supply: 3.4 ~4.2V(Recommended 3.8V) Operating temperature: -40~+85℃ Storage temperature: -45~+90℃ weight: 1g Data Transmission SMS Voice GNSS Coding schemes CS 1, 2, 3, 4 PPP‐stack Support pass‐through Point to Point MO and MT SMS status report Text and PDU Half Rate(HR) Full Rate(FR) Text and PDU mode Enhanced Full Rate(EFR) Adaptive-negotiation Multi-code Rate(AMR) Receiver type: 33 tracking / 99 captured Maximum update rate: 10 Hz Sensitivity ‐‐ Tracking: ‐165dBm -- Reacquisition: ‐160dBm ‐‐ Cold starts: ‐148dBm Time‐To‐First‐Fix ‐‐ Cold start: 31s(typical) ‐‐ Warm start: 26s ‐‐ Hot starts: <1s ‐‐ EPO Assist: 13s (CTTFF) Accuracy ‐‐ Automatic Position: 2.5m CEP ‐‐ Speed: 0.1m/s Interface 47 SMT pads(Stamps Holes) One analog audio One serial interfaces One SIM card interface (3V/ 1.8V) One ADC interface GPIO interface USB interface GSM antenna pad GPS antenna pad 1.2 Module System Diagram Following figure: List main function of module GSM Baseband and RF Power Management Antenna Interface Other interfaces Figure 1-1:Module function diagram 2 APPLICATION INTERFACE SIM_SCLK SIM_IO USB_DP USB_DM USB_VBUS VCC_RF_GPS GND GPS_RF GND RESERVED MICP MICN 2.1 PIN Assignment 47 46 45 44 43 42 41 40 39 38 37 36 SIM_RST 35 SPKP VSIM 34 SPKN SIM_DET 33 VRTC TXD1 32 RESETB RXD1 31 PWRKEY DTR1 30 ADC RING1 29 NETLIGHT RTS1 28 STATUS DSR1 27 GND CTS1 10 26 VBAT DCD1 11 25 VBAT L218 LCC TOP 24 23 22 21 20 19 18 17 16 15 14 13 12 GND GPIO_MB_0 GND GND RF_ANT GND GND BT_ANT GND VIO28 PWM0 GPS_UARTTXD RESERVED Interfaces as below: Figure 1-1: L218 Pin out diagram (TOP View) Analog voice: One MIC inputs, one speaker output. USB: USB interface. SIM card: support 1.8V and 3V. Reset: Support RESETB pin to reset the module. GPIO:PIN 23 for normal general purpose in/out, and some other pins can be configured as GPIO pin (detail information in the following table). Serial port:Contain one full functional serial interface, CTS and RTS etc. should be NC when not used. RF: GSM,GPS 2.2 PIN Description L218 PIN description as below: Table 2-1: PIN description PIN NO. PIN name Type* SIM_RST I/O VSIM POWER SIM_DET Reset Function Description PD SIM signal SIM signal I/O PD SIM signal TXD1 PU Request to Send, For AT command, firmware upgrades and data transmission. RXD1 PU Receive data, For AT command, firmware upgrades and data transmission. DTR1 PD Data terminal ready (Control module wake or sleep) RING1 PD Ring indicator RTS1 PU Request to Send DSR1 PD Data Set Ready 10 CTS1 PU Clear to send 11 DCD1 PD Data carrier detect 12 REVERSED I/O PD General purpose input/output 13 GPS_UARTTXD I/O PD GPS NEMA Output 14 PWM0 I/O PD PWM output 15 VIO28 POWER VDDIO 2.8V output, max current is 20mA 16 GND GND GND 17 RF ANT I/O RF Antenna 18 GND GND GND 19 GND GND GND 20 RF_ANT GSM Antenna 21 GND GND GND 22 GND GND GND 23 GPIO_MB_0 I/O 24 GND GND GND 25 VBAT POWER 26 VBAT POWER Power supply. The power supply range is from 3.4V to 4.2V. Recommended voltage is 3.8V. 27 GND GND GND 28 STATUS Running status indicator 29 NETLIGHT I/O PD 30 ADC AI 31 PWRKEY AI 32 RESETB PD General purpose input/output Net status indicator Analog to digital conversion interface,Max voltage is 2.8V. PWRKEY should be pulled low at least 1 second and then released to power on/down the module Reset signal,internal pulled up to1.8V. RTC voltage, input 2.8V, maximum current of 2mA. External button battery or a large capacitor, If no use can be set NC 33 VRTC POWER 34 SPKN AO 35 SPKP AO 36 MICN AI 37 MICP AI 38 REVERSED POWER MIC Bias output 39 GND GND GND 40 GPS_RF FM Antenna 41 GND GND GND 42 VCC_RF_GPS POWER GPS Power Output 43 USB_VBUS USB Power 44 USB_DM I/O USB Differential data D- 45 USB_DP I/O USB Differential data D+ 46 SIM_IO I/O PD SIM signal 47 SIM1_SCLK I/O PD SIM signal Differential audio output. Differential input, with internal bias voltage. * Type I , O , I/O can be configured as general GPIO, its status is PU or PD when reset. * The high level of the digital signal is 2.8V (min:2.6V, max3.0V). 2.3 Functional Diagram Main function of module PINs listed as below SIM card interface Audio interface Antenna interface Other interfaces Figure 3-2: Function diagram 3 INTERFACE CIRCUIT REFERENCE DESIGN 3.1 Power 3.1.1 Power supply VBAT is the main power source of L218 module., from 3.4V to 4.2V, and 3.8V is the recommended voltage. In GSM system, RF signal works in burst transmit, a continuous 577us (1/8 of a TDMA period) burst will be found at intervals of 4.615ms. In burst period, peak current is necessary to make sure operating voltage won’t drop to the base one. Because when module is working under the base voltage, the burst will cause VBAT has instantaneous large current, which the peak value could reach 2A or above and lead to the Vdrop about 350mV. Figure 3-1:Module burst current and voltage waveforms It is recommended to use a large capacitor close to VBAT PIN. The capacitor is the bigger the better to improve power stability. 470uF or more low-ESR aluminum electrolytic capacitors is recommended for CA. If the lithium battery directly connected, 220uF or 100uF tantalum capacitor (low ESR) is recommended for CB. The capacitors of 33pF and 10pF in parallel can effectively remove high-frequency interference. The capacitors should close to the VBAT pin of module. Figure 3-2: VBAT input (Reference circuit) It is strongly recommended to add a 5.1V / 500mW Zener diode to VBAT pin in parallel, Zener diode should close to the VBAT pin. Recommended parts list as below: Table 4-1: Recommended Zener diode Vendor Factory Model Power Encapsulation On semi JCST Prisemi ROHM SIG Vishay Crownpo MMSZ5231BT1G MMSZ5231B PZ5D4V2H HDZMV4Z015.1B SIG1Z5T1G MMSZ4689-V CDZ55C5V1SM 500mW 500mW 500mW 500mW 500mW 500mW 500mW SOD123 SOD123 SOD523 UMD2 SOD323 SOD123 0805 NOTE: TVS must has a good GND nearest to interface. VRWM value cannot be too high, normally it is the 1/3 added one based on its own voltage value If the power supply is over 4.2V, voltage conversion is required, LDO or Buck chipset can do that function. 1、 As the LDO efficiency is closely related to the input/output dropout voltage value, the greater the voltage difference, the lower the efficiency, and at the same time, the problem of heat radiation will be detected, there is a demand of the small dropout voltage between DC input and LDO output. For instance, the voltage difference between 5V input and 4.1V output is acceptable. The reference power supply circuit design with LDO is shown as figure below: Figure 3-3:LDO (Reference circuit) 2、Buck circuit can enhance the conversion rate if the differential value is great. But meanwhile, the EMI issue caused by DCDC will be concerned. Figure 3-4:DC-DC (Reference circuit) 3、PMOS control circuit for power switch. If want to control VBAT under the circumstance that there is no need of power conversion, for example, lithium-ion battery is the direct power supply, PMOS control circuit can be the choice. Figure 3-5:PMOS (Reference circuit) 3.1.2 Power monitor To monitor the power supply voltage, you can use " AT+CBC " command. For details, you can refer to AT command manual. 3.1.3 Power on Module to normal boot mode is through lower PWRKEY pin at least 1 second. After successful boot PWRKEY pin can be released. NETLIGHT signal can be used to determine whether module boot. When NETLIGHT start according to certain frequency output pulse signal, if connect lights, lights flashing, suggests that successful boot module. If no output pulse signal, has been as low level, no boot mod. Recommend the following boot circuit (PWRKEY came on the module VBAT). The reference circuit is as follows: 1、With triode control boot Figure 3-6: Use triode control boot 2、Use key boot Figure 3-7: Use key to boot Module on the mains electricity cannot be earlier than the external MCU with electricity, prevent module on the electric moment, external MCU serial port is in unstable condition, cause the module into the mode of the error. To ensure stable operation of external MCU, then control module is powered on. Boot sequence diagram below: Figure 3-8: Boot sequence Also pay attention to the external MCU and module connection interface level anomaly, especially the main UART port, could affect the module of the boot sequence, when switched on. For example, external MCU IO interface is in a state of output, the module of UART0 mouth U0RTS signal (output pin) forced to lower or higher, the module may not be able to normal boot. 3.1.4 Power off It is a safe way to turn off the module by driving the PWRKEY to a low level voltage for a certain time. The power down scenario is illustrated below. Figure 3-9 Shutdown sequence Note: As logout network time is related to the local mobile network, it is recommended to delay about 12 seconds before disconnecting the power supply or restarting the module. 3.1.5 Reset The hardware reset reference design as below (Key reset and MCU reset L218 Module): Figure 3-10: Recommend the reset circuit: Key reset and MCU reset L218 Module Note: 1, Only use under emergency, such as no AT response, PWRKEY failure. 2, Don’t connect RESETB PIN to MCU directly. Table 5-2:Electronic characteristic of the RESET pin PIN name Symbol VIH VIL RESETB Low power time RESETB Reset timing sequence: Min 2.4 -105 Typ ---- Max -0.6 -- Unit ms Figure 3-11: Reset timing sequence 3.1.6 Power saving mode When L218 is in sleep mode, the following methods can wake up the module: (1) Pull down DTR pin. The serial port will be active after DTR pin is pulled to low level for about 50ms. (2) Receive a voice or data call from network. (3) Receive a SMS from network. When L218 is in wake up mode, the following methods can sleep the module: Pull up DTR pin. (1) Pull up DTR pin. Figure 3-12:DTR circuit 3.1.7 RTC power When VBAT disconnect, users need to save the real time clock, the VRTC pin can't hung up. It need an external large capacitor or batteries. When external large capacitor, the recommended value of 100uF, to keep the real time clock for 1 minute. RTC power using external large capacitor or battery to RTC power supply inside the module. Modules contain a 1.5 K current-limiting resistance. Button cell or super capacitor can be used to give the RTC power supply. Below are several to RTC power supply circuit of reference: External capacitor of power supply Figure 3-13:External capacitor to the RTC power supply Non-chargeable Backup battery Figure 3-14:Non-rechargeable battery Rechargeable battery Figure 3-15:Rechargeable battery The VRTC power typical value of 2.8 V, consumption flow about 3uA when VBAT disconnect. 3.2 Audio Table 6-3:Audio interface pin definition NO. PIN name MICN MICP SPKN SPKP PIN NO. 36 37 34 35 Description Audio differential input negative Audio differential input positive Audio differential output negative Audio differential output positive 3.2.1 Audio channel 1、 The difference signal SPKN, SPKP of audio, directly connected to the speaker device. Figure 3-16: Receiver circuit 2、 MIC need add external MICBIAS power, external microphone can be directly connected MICP and MICN. Figure 3-17: MIC (Reference circuit) 3.2.2 TDD noise Electret microphone (with embedded double frequency filtering capacitor, 10pFand 47pF) is suggested to use on hand handle or hand free microphone to stop RF interference and TDD noise from the beginning. If double frequency filtering capacitor is not selected, TDD noise may be heard during conversation. Please consult to capacitor provider to choose the most suitable capacitor value to filter high-frequency noise out in GSM850/GSM900/DCS1800/PCS1900MHz. The order of noise severity in GSM band depends on application design. For instance, TDD noise is relatively serious in GSM900 or DCS1800 in different conditions. Users choose their desired filter capacitor according to their situation. The place of nearing audio element or interface is better for filter capacitor, wire layout must be shortest as it could be, through filter capacitor first. The place far away from audio element or layout is better for antenna to avoid disturbing. Power layout and audio layout cannot be paralled, and keep them in distance. TDD noise can be affected by GND. If GND layout is not suitable, noise will disturb MIC and speaker. Add some large capacitors or series magnetic beads during schematic diagram designing to avoid conductive interference. Differential audio layout must abide the rules of differential signal layout. 3.3 UART Communication 3.3.1 Serial pin definition Modules provide 2 groups of UART serial port, including UART1 support full serial port function, main effect for the AT communications, data services, software upgrades, etc. UART2 provides only the TX and RX, can be used as the AT communication, debug, etc. Module called a DCE device (Data Communication Equipment), according to the traditional DCE - DTE (Data Terminal Equipment) connection. Adaptive baud rate support range 4800bps to 115200bps. Table 7-4:Serial pin definition: Interface Serial port PIN name PIN NO. DCD1 RTS1 RING1 DTR1 CTS1 TXD1 RXD1 DSR1 11 10 Description Data carrier detect DTE request data Ringing indicating DTE is ready Clear to send Data sent Data reception Data Set Ready 3.3.2 Serial port characteristics Main serial port: 7 signal lines. Including cable TXD and RXD, hardware flow control line RTS and CTS, and other line of DTR, DCD and RI. 8 data bits,No parity,One stop bit. Hardware flow control off by default, if use hardware flow control, use the "AT + ICF = 0" open flow control function. AT command transfer, GPRS data transmission. Support a fixed baud rate is as follows: 2400,4800, 9600, 14400, 19200, 28800, 38400, 57600, 115200. The default configuration module for adaptive baud rate. Adaptive support the following baud rate:4800,9600,19200,38400,57600,115200bps. The baud rate is fixed or adaptive baud rate synchronization settings. And send a command string "A-T" when serial ready after module will reply "OK". The host controller by sending "AT" command to the module, the module will automatically detect and identify the host controller's current baud rate. Adaptive baud rate function can make the host controller don't need to know the current baud rate and the module of communication will be finished. Adaptive baud rate function open by default. Adaptive baud rate operating configuration: Serial interface is configured to 8 bits of data bits, parity bits, one stop bit (the factory configuration). Adaptive baud rate mode, if there is no first synchronization module boot, such as "RDY", "+ CFUN: 1" and "+ CPIN: READY" URC information will not be reported. DTE in switching to a new baud rate, will first through the "AT" set up the new baud rate, before module detection and synchronous new baud rate, the module will use previous messages URC baud rate. DTE when switch to the new baud rate, the equipment is likely to receive unrecognized characters. Baud rates, is not recommended in a fixed mode switch to the adaptive baud rate model Note: the default module is adaptive baud rate (AT + IPR = 0), in the baud rate adaptive mode, after power on the URC information "RDY" will not back to the master machine. In the module boot after 2 ~ 3 seconds, can send the module AT commands. Master need to first send the "AT" the baud rate of character to the module to detect a master, and continue to send 1 ~ 5 "AT" string until module returns "OK". Then send a "AT + IPR = x & W" command to the module set the baud rate of a fixed, and save the configuration, after completed the configuration, each module after boot, will return to a URC information via a serial port "RDY". To further understand, please refer to the document [AT_DOCUMENT] "AT + IPR" in the chapter. 3.3.3 Serial port connection The main serial port connection mode is more flexible, as follows are three common ways of connection. 1、Full-featured serial connection as shown in the figure below, this way is mainly used in the modem mode dial (PPP) Figure 3-18: Full-featured serial connection 2、Three wire system without hardware flow control of the serial port is as follows Figure 3-19: Serial port three line connection 3、Three wire system with hardware flow control of the serial port is as follows: L218 DCE Client(DET) Serial Port Serial Port TXD1 TXD RXD1 RXD RTS1 RTS CTS1 CTS DTR1 DTR DCD1 DCD RING1 RING GND GND Figure 3-20: Serial flow control connection 3.3.4 Serial level matching Module serial port is COMS VIO28 level signal, connected to the external MCU, it should pay attention to the matching of IO level. Normal job requirements input level lower than 3.0V, the default rate is 115200 bps. When external MCU serial level of 3.3V, it is recommended to use the following reference circuit. If the external MCU level is 3.0 V, please change the resistance of 5.6 K to 14 K. Figure 3-21: Resistor level matching (Reference circuit) If the external host MCU serial level is 5V, can use the transistor voltage conversion circuit or use special voltage conversion circuit, the reference is as follows: 1、 Use triode to do level transformation Figure 3-22: 5V TXD level matching (Reference circuit) Figure 3-23: 5V RXD level matching (Reference circuit) 2、Use FAIRCHILD to convert the chip NC7WZ07: Figure 3-24: Chip level matching (Reference circuit) 3.4 SIM Card Interface SIM card interface support GSM Phase1 specification function, also support the function of the GSM Phase 2 + specification and FAST 64 kbps SIM CARDS (for SIM application toolkit). SIM card supports 1.8V and 3.0V power supply through the internal power supply of the module. 3.4.1 SIM Interface Table 8-5:SIM card interface pin definition: NO. PIN name PIN NO. SIM_IO SIM_SCLK SIM_RST SIM_DET VSIM 46 47 Description SIM card data I/O SIM card clock SIM card reset SIM card insert detection pin SIM power supply, according to the type of SIM card automatically select the output voltage, 3.0V 10% or 1.8V 10%, the output current of about 10mA. Below is a SIM card interface reference circuit, using 8 pin SIM gets stuck. SIM_DET pins for Molex SIM booth detection. When cato is inserted into the booth, SIM_DET into a low level. At this time whether or not a SIM card inside the cato, SIM_DET level from high to low make initialization module produces a SIM card. By default, the SIM card detection is off, you can use the "AT + ESIMS = 1" to open or "AT + ESIMS = 0" to close the function. Learn more about the content of the AT command, please refer to the document [AT_DOCUMENT]. When sending the " AT+CPIN?" the order, if not SIM card into the booth, can appear the URC information below: +CPIN: NOT READY If the SIM card has been done into the booth, SIM initialized, the URC information will appear as below: Call Ready Figure 3-25: 8-pin SIM card (Reference circuit) Figure 3-26: 6-pin SIM card (Reference circuit) SIM card each signal need to increase the ESD protection devices used for ESD protection. In circuit design, in order to ensure the good performance of SIM card and is not damaged, in circuit design advice follow the following principles: 1. SIM gets stuck close to the module put, keep SIM card signal wiring less than 100 mm. 2. SIM card signal cable wiring away from the RF line and VBAT power line. 3. SIM gets-stuck and module of SIM_GND wiring to short and thick. SIM_VDD and SIM_GND wiring width ensure that not less than 0.5 mm, and between SIM_VDD and GND bypass capacitor does not exceed 1uf, and close to put SIM gets-stuck. 4. In order to prevent and SIM_DATA SIM_CLK signal crosstalk mutually, both wiring can't stand too close to, and between two linear increase shielding. In addition, SIM_RST signal also need to protect. 5. In order to ensure good ESD performance, it is recommended that the SIM card pin increase TVS diode. Choose the TVS diode parasitic capacitor is not more than 50 pf, for example: WILL ESDA6V8AV6 (http://www.willsemi.com).Series between the module and SIM card need to 22 ohm resistance to suppress stray EMI and ESD protection. SIM card of peripheral devices should be placed near the SIM holder. 6. Suggest SIM_DATA, SIM_RST SIM_CLK and SIM_VDD online parallel 33 pf capacitor is used to filter out radio frequency interference, and close to put SIM gets-stuck. 3.4.2 SIM gets stuck (Reference Figure) SIM card connector 8 pin recommended Molex 91228. Please visit the http://www.molex.com website for more information! Figure 3-27:Molex 91228 SIM gets stuck Table 9-6:PIN description (Molex SIM gets stuck) PIN name Signal Description C1 C2 C3 C4 C5 C6 C7 SIM_VDD SIM_RST SIM_CLK SIM_PRESENCE GND VPP SIM_DATA C8 SIM_DETECT SIM card power supply pin SIM card reset SIM card clock SIM card detect pin GND Not connected SIM card data input/output Card SIM in position detection, the pin is directly connected to the ground, with the use of SIM_PRESENCE. When the SIM card tray is inserted, C4 and C8 are short circuit. 6 pins SIM booth is recommended to use Amphenol company C707 m006 10 5122.Please visit http://www.amphenol.com for more information! Figure 3-28:Amphenol C707 10M006 5122 SIM gets stuck Table 10-7:PIN description (Amphenol SIM gets stuck) PIN name C1 C2 C3 C5 C6 C7 Signal SIM_VDD SIM_RST SIM_CLK GND VPP SIM_DATA Description SIM card power supply pin SIM card reset SIM card clock GND Not connected SIM card data input/output 3.5 PWM Interface Table 11-8:PWM Pin definition PIN NO. 14 PIN name PWM0 Description PWM signal, Reusable for GPIO2 PWM can provide the frequency range of 0~2KHz, the user can set the output frequency, duty cycle through the AT+SPWM command, please refer to the AT document. PWM pin can be used to drive buzzer. NOTE: Make sure the PWM pin keep low level when module in the boot process. Buzzer volume can be set by "AT + CRSL". The reference circuit as follows: Figure 3-29:PWM (Reference circuit) 3.6 NETWORK Status Indicator Table 12-9:NETLIGHT pin definition PIN NO. PIN name Description 29 NETLIGHT Network status indicator The NETLIGHT signal can be used to drive network status LED, the working state of this pin in the following table: Table 13-10:working state of NETLIGHT Light status off 64ms on/ 800ms off 64ms on/ 3000ms off 64ms on/ 300ms off Work status Power off No Network Register to network GPRS Data Communication Reference circuit: Figure 3-30:NETLIGHT (Reference circuit) 3.7 ADC Interface L218 provides an ADC channel, the user can use the AT command "AT + CADC" to read voltage value on ADC pin. Note: the ADC sampling the voltage cannot be more than 2.8 V, otherwise easy to cause damage to the ADC. About the AT commands related information please refer to the document [AT_DOCUMENT]. In order to improve the accuracy of ADC, the layout of ADC should be surrounded by ground. Table 14-11:ADC interface pin definition PIN NO. 30 PIN name Description ADC Analog sampling Table 15-12:ADC Parameter Item Min Typ. Max Units Input voltage range ADC resolution ADC sampling rate ADC precision 10 10 2.8 1.0833 30 bits MHz mV 3.8 GPS Function L218 supports GPS, users only need external matching GPS antenna can be convenient to use this feature. Can use AT commands through the serial port to the GPS operation, in order to realize positioning, and other functions. 3.9 Antenna Interface L218 interface provides three antenna, GSM antenna interface RF_ANT respectively, and the GPS antenna interface GPS_RF ANT_RF antenna and interface. GPS antenna, GSM antenna, RF antenna working in choose all needs to choose frequency band input impedance of 50 ohm, standing wave coefficient is less than 2 antenna products. As far as possible away from two kinds of antenna is placed. Each port antenna and other port isolation ratio should be greater than 30 dB. L218 provides three antenna interfaces, pin definition as below: Table 16-13:Antenna interface pin definition PIN NO. 40 20 17 PIN name GPS-ANT RF_ANT RF-ANT Description GPS antenna interface GSM antenna interface RF antenna interface 3.9.1 GSM antenna reference circuit For the peripheral circuit design of the antenna interface, in order to better adjust the RF performance, the proposed reservation matching circuit. Antenna connection reference circuit as shown below. Where C101, C102 default is not posted, only 0 ohm R101 resistance, the line needs to be controlled by 50 ohm. Figure 3-31: RF reference circuit (GSM/BT) Component placement and RF routing takes note: Matching circuit must be placed near the antenna RF ANT foot to the antenna RF cable must be 50 ohm impedance control RF_ANT PIN to antenna RF line must be far away from the high speed signal lines and strong interference sources, to avoid any signal lines cross or parallel and adjacent layer 3.9.2 GPS antenna reference circuit For the outside of the antenna interface circuit design, in order to better adjust the RF performance, suggest the reserved matching circuit. GPS antenna can be divided into passive and active antenna, the antenna connection reference circuit as shown in the figure below. a. Passive antenna Matching circuits of C1 and C2 default don't stick, Resistor R1 only 0 ohm, need to get the line control according to 50 ohms. Figure 3-32: GPS passive antenna (Reference circuit) b. Active antenna Active antenna is integrated with built-in LNA, need plus 2.8 V to 2.8 V, suggest 3.3 V power supply. Matching circuits of C1 and C2 default don't stick, R1 resistor only 0 ohm, need to get the line control according to 50 ohms. Figure 3-33: GPS active antenna (Reference circuit) Component placement and RF routing takes note: Matching circuit must be placed near the antenna RF _ANT foot to the antenna RF cable must be 50 ohm impedance control RF_ANT PIN to antenna RF line must be far away from the high speed signal lines and strong interference sources, to avoid any signal lines cross or parallel and adjacent layer Gain and directivity Antenna directivity refers to the intensity of the electromagnetic field while the electromagnetic wave is in all directions. Gain is the collection of the efficiency and directivity of the antenna. It is recommended that antenna gain is less than or equal to 3dBi. Figure 5-1 RF cable 3.10 USB Interface 3.10.1 Pin description This product has a high speed USB1.1 interface, support full - speed mode, a main processor (AP) and mainly through the USB interface for data transmission between modules. USB interface are defined as follows. Table 17-14:USB interface pin definition: NO. PIN name VBUS_VBUS USB_DM USB_DP PIN NO. 43 44 45 Description USB Power USB Differential data D‐ USB Differential data D+ 3.10.2 Electrical characteristics The USB interface module accords with USB1.1 specification and electrical properties. Support full - speed working mode. Main processor (AP) and the module of data between the interaction is mainly completed through the USB interface. 3.10.3 USB interface applied USB bus is mainly used for data transmission, software upgrades, detection module program. Work under the mode of high - speed USB line, if you need to ESD design, must satisfy the junction capacitor value of ESD protection devices < 5 pf, or larger junction capacitor will cause waveform distortion, affect the bus communication. Differential difference of the data line impedance should be controlled in 90 ohm + / - 10%. 4 Mechanical Dimensions Mechanical dimensions of Module: Figure 4-1: L218 top view, side view, and bottom view(mm) Figure 4-2: L218 Recommended Pad(mm) 5 ELECTRICAL CHARACTERISTICS 5.1 Absolute Maximum Ratings The following table shows the absolute maximum state in abnormal situation, more than the limit value will likely result in permanent damage to the module. Table 5-1: Absolute Maximum Ratings Parameter VBAT Peak current Digital signal input voltage Analog input voltage Working temperature Storage temperature Min 3.3 -0.3 -0.3 -0.3 -40 -45 Typ. 3.6 25 25 Max 4.4 3.1 3.1 +85 +90 Unit ℃ ℃ 5.2 Digital Interface Characteristics Table 5-2: Digital Interface Characteristics Parameter Description VIH VIL VOH VOL VIH Input high level Input high level Input high level Input high level Input high level Min 2.1 2.5 2.1 Typ. Max 3.1 0.7 3.1 0.3 3.1 Unit * Apply to the GPIO, I2C, UART, PCM digital interface, etc. 5.3 VSIM Characteristics Table 5-3: SIM card interface characteristics Parameter Description VO Output voltage IO Output current Min 1.65 2.8 Typ. 1.8 3.0 Max 1.95 3.2 60 Unit mA 5.4 Current Consumption Table 5-4: Current consumption Parameter Bottom current Working current Peak current Conditions Min Typ. Max Unit Shutdown mode Sleep mode Standby mode Voice (maximum power) Data transfer mode GPRS(1Rx,4Tx) Data transfer mode GPRS(3Rx,2Tx) Maximum power burst current Data transfer mode GPRS(3Rx,2Tx) ----- 0.07 10.6 280 ----- mA mA mA mA -- 495 -- mA -- 413 -- mA -- -- 2.0 -- 413 -- mA 5.5 ESD In the use of the module, due to the human body static electricity, electric charge and friction between the two kinds of static electricity generated by various means of discharge to the module, may cause some damage, so ESD protection must pay attention, whether in the development, production assembly, testing process, especially in product design, should be taken to prevent ESD protection measures. Such as circuit design in the interface or vulnerable to the ESD point to increase the ESD protection, the production of anti-static gloves, etc.. Because the module is not specifically designed for electrostatic discharge protection, so in the production, assembly and operation module must pay attention to the electrostatic protection. The performance of the module test parameters in the following table: ESD performance parameters (temperature: 25, humidity: 45%) Table 5-5: ESD performance parameters PIN VBAT GND RXD, TXD RF_ANT MIC_P/N RCV_P/N PWRKEY RESETB Contact discharge Air discharge ±5KV ±5KV ±1KV ±5KV ±10KV ±10KV ±6KV ±10KV ±2KV ±6KV ±3KV ±6KV 5.6 RF performance RF output power Following table lists the conducted output power of modules, compliant with 3GPP TS 05.05 SPEC. Table 5-6: GSM850 conducted output power PCL -5 10 11 12 13 14 15 16 17 18 Output power (dBm) Nominal 32.5 30.8 29 27 25 23 21 19 17 15 13 11 Table 5-7: PCL -0 Tolerance (dB) for conditions Normal ±0.4 ±1 ±1 ±1 ±1 ±1 ±1 ±1 ±1 ±1 ±1.5 ±1.5 ±1.5 ±1.5 Extreme ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±5 PCS1900 conducted output power Output power (dBm) Nominal 29.5 27.5 26 24 22 20 18 Tolerance (dB) for conditions Normal ±0.4 ±1 ±1 ±1 ±1 ±1 ±1 Extreme ±2 ±2 ±2 ±2 ±2 ±2 ±2 7 10 11 12 13 14 15 ±1 ±1 ±1.5 ±1.5 ±1.5 ±1.5 ±1.5 ±1.5 ±2 16 14 12 10 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±5 ±5 Module conduction receiver sensitivity The following table lists the module's conduction reception sensitivity and is tested under static conditions. Table 5-8: Conduction sensitivity Band Receiving sensitivity (Typ.) GSM850 PCS1900 ≦-108dBm ≦-108dBm Module frequency band The following table lists the module's working frequency bands, compliant with the TS 3GPP 5.05 specification. Table 5-9: Module frequency band Band Receiving sensitivity (Typ.) GSM850 PCS1800 869 ~ 894MHz 1930 ~ 1990MHz Receiving sensitivity (Max)) 824 1850 849MHz 1910MHz 6 MANUFACTURING This chapter describes the related information. 6.1 L218 Top And Bottom view Figure 6-1: L218 top and bottom view 6.2 Soldering Figure 6-2:Recommend reflow temperature profile 6.3 The Moisture Sensitivity Level (MSL) L218 module complies with the humidity level 3. At a temperature of <30 degrees and relative humidity of <60% of the environmental conditions, dry pack to perform J-STD-020C specification according to IPC / JEDEC standard. At a temperature of < 40 degrees and a relative humidity of < 90% of the environmental conditions, in the case of unopened shelf life of at least six months. After unpacking, Table29 shows the module shelf life at different times corresponding to the level of humidity. Table 6-1: Moisture sensitivity level and floor life The Moisture Sensitivity Level (MSL) Floor Life(out of bag) at factory ambient≦ +30 /60%RH 1 RH ℃ condition Unlimited at ≦ +30 /85% 2a 5a 1 Year 4 weeks 168 hours 72 hours 48 hours 24 hours Mandatory bake before use. After bake, it must be reflowed within the time limit specified on the label. After unpacking, <30 degrees in temperature and relative humidity <60% environmental conditions, 168 hours in the SMT patch. If not meet the above conditions need to be baked. NOTES: For product handling, storage, processing, IPC / JEDEC J-STD-020C must be followed 6.4 Baking Requirements Due to the humidity sensitive characteristics of the L218 module, the L218 is a vacuum packaging, which can be stored for 6 months without damage to the package, and the ambient temperature is less than 40 C and the relative humidity is less than 90%. To meet one of the following conditions, the process of reflow soldering should be performed before the full bake, or the module may cause permanent damage to the process. 1、Vacuum packing damage or leakage 2、The module is exposed in the air for 168 hours or more 3、The module is exposed in air for 168 hours, not meet the temperature <30 degrees and relative humidity of the environment conditions <60% Table 6-2: Baking requirements Baking temperature 40°C±5°C 120°C±5°C Humidity Baking time <5% <5% 192 Hours 4 Hours 7. Package and Storage information 7.1 Package information L218 module adopts by tape and reel. Shipping whit the coil packaging and vacuum sealing anti-static bag to seal it. 7.1.1 Tape and reel information There are 500 L218 module assembled in a tape reel, below figure show the detail information. Figure 7-1:Tape and reel information 7.1.2 Assemble and carrier information L218 packing diagram is as follows, every 4 volumes of material packed in a case between each volume of material has a bubble mat do isolation protection. Specific as shown in the figure below: Figure 7-2:Package and ship information 7.2 Bagged storage conditions L218 shipments in the form of vacuum sealing anti-static bag. Module of storage need to follow the following conditions: Environment below 40 Degrees Celsius temperature, air humidity is less than 90% of cases, the module can be in vacuum sealed bags for 12 months. Conditions set the storage environment Suggestions with reference to the following form. Table 7-1: Storage conditions (less than 90% humidity of the air vacuum sealed packaging) Max. Min. Typ. Unit Parameter Storage temperature -45 25 90 ℃ When on the vacuum bags, if meet the following conditions, the module can be directly for reflow soldering (furnace temperature setting reference 6.2 furnace temperature curve) or other high temperature process: Module temperature below 30 degrees c, the air humidity is less than 60%, factory within 72 hours to complete the SMT. The humidity is less than 10%. If the module is in the following conditions, to be baked before SMT: When the environment temperature is 23 degrees Celsius (allow upper and lower volatility of 5 degrees Celsius), humidity index greater than 10%. When open vacuum bags, module temperature below 30 degrees Celsius, air humidity is less than 60%, but the factory have not finished the SMT within 72 hours. When open the vacuum bags, module storage air humidity is more than 10%. If modules need baking, please under 125 degrees Celsius (allowing fluctuations of 5 degrees Celsius) up and down bake for 48 hours. 8 RELATED DOCUMENTS Table 8-1:Related documents NO. Documents [1] AT_DOCUMENT ITU-T Draft new recommendation V.25ter: [2] [3] GSM 07.07: [4] GSM 07.10: [5] GSM 07.05: [6] GSM 11.14: [7] GSM 11.11: Note Serial asynchronous automatic dialing and control Digital cellular telecommunications (Phase 2+); AT command set for GSM Mobile Equipment (ME) Support GSM 07.10 multiplexing protocol Digital cellular telecommunications (Phase 2+); Use of Data Terminal Equipment – Data Circuit terminating Equipment (DTE – DCE) interface for Short Message Service (SMS) and Cell Broadcast Service (CBS) Digital cellular telecommunications system (Phase 2+); Specification of the SIM Application Toolkit for the Subscriber Identity Module – Mobile Equipment (SIM – ME) interface Digital cellular telecommunications system (Phase 2+); Specification of the Subscriber Identity Module – Mobile Equipment (SIM – ME) interface FCC Statement NOTE: This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures: ---Reorient or relocate the receiving antenna. ---Increase the separation between the equipment and receiver. ---Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. ---Consult the dealer or an experienced radio/TV technician for help. FCC Caution: Changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. IMPORTANT NOTE: This module is intended for OEM integrator. The OEM integrator is still responsible for the FCC compliance requirement of the end product, which integrates this module. 20cm minimum distance has to be able to be maintained between the antenna and the users for the host this module is integrated into. Under such configuration, the FCC radiation exposure limits set forth for an population/uncontrolled environment can be satisfied. Any changes or modifications not expressly approved by the manufacturer could void the user’s authority to operate this equipment. FCC Radiation Exposure Statement This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated minimum distance 20cm between the radiator and your body as well as kept minimum 20cm from radio antenna depending on the Mobile status of this module usage. This module should NOT be installed and operating simultaneously with other radio. The manual of the host system, which uses L218, must include RF exposure warning statement to advice user should keep minimum 20cm from the radio antenna of L218module depending on the status. LABEL OF THE END PRODUCT: The final end product must be labelled in a visible area with the following "Contains TX FCC ID: 2AHSAL218". If the size of the end product is smaller than 8x10cm, then additional FCC part 15.19 statement is required to be available in the users manual: This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. USERS MANUAL OF THE END PRODUCT: In the users manual of the end product, the end user has to be informed to keep at least 20cm separation with the antenna while this end product is installed and operated. The end user has to be informed that the FCC radio-frequency exposure guidelines for an uncontrolled environment can be satisfied. The end user has to also be informed that any changes or modifications not expressly approved by the manufacturer could void the user’s authority to operate this equipment. If the size of the end product is smaller than 8x10cm, the additional FCC part 15.19 statement is required to be available in the users manual: This device complies with Part 15 of FCC rules. Operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. The module is only certified with the installed antenna. Any change of the antenna will void the certification. The host device including this RF module need to undergo separate certification. This module is intended for OEM integrator only and the OEM integrators and instructed to ensure that the end user has no manual instructions to remove or install the device. The OEM integrator is still responsible for the FCC compliance requirement of the end product, which integrates this module. EU Regulatory Conformance Hereby, we (Shanghai MobileTek Communication Ltd.) declared that this device is in compliance with the essential requirements and other relevant provisions of Directive 1999/5/EC.
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