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SC20 Hardware Design Smart LTE Module Series Rev: SC20_Hardware_Design_V1.4 Date: 2017-10-17 www.quectel.com Smart LTE Module Series SC20 Hardware Design Our aim is to provide customers with timely and comprehensive service. For any assistance, please contact our company headquarters:

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http://quectel.com/support/technical.htm Or email to: support@quectel.com GENERAL NOTES QUECTEL OFFERS THE INFORMATION AS A SERVICE TO ITS CUSTOMERS. THE INFORMATION PROVIDED IS BASED UPON CUSTOMERS REQUIREMENTS. QUECTEL MAKES EVERY EFFORT TO ENSURE THE QUALITY OF THE INFORMATION IT MAKES AVAILABLE. QUECTEL DOES NOT MAKE ANY WARRANTY AS TO THE INFORMATION CONTAINED HEREIN, AND DOES NOT ACCEPT ANY LIABILITY FOR ANY INJURY, LOSS OR DAMAGE OF ANY KIND INCURRED BY USE OF OR RELIANCE UPON THE INFORMATION. ALL INFORMATION SUPPLIED HEREIN IS SUBJECT TO CHANGE WITHOUT PRIOR NOTICE. COPYRIGHT THE INFORMATION CONTAINED HERE IS PROPRIETARY TECHNICAL INFORMATION OF QUECTEL WIRELESS SOLUTIONS CO., LTD. TRANSMITTING, REPRODUCTION, DISSEMINATION AND EDITING OF THIS DOCUMENT AS WELL AS UTILIZATION OF THE CONTENT ARE FORBIDDEN WITHOUT PERMISSION. OFFENDERS WILL BE HELD LIABLE FOR PAYMENT OF DAMAGES. ALL RIGHTS ARE RESERVED IN THE EVENT OF A PATENT GRANT OR REGISTRATION OF A UTILITY MODEL OR DESIGN. Copyright Quectel Wireless Solutions Co., Ltd. 2017. All rights reserved. SC20_Hardware_Design Confidential / Released 1 / 122 Smart LTE Module Series SC20 Hardware Design About the Document History Revision Date Author Description 1.0 1.1 1.2 1.3 2016-04-12 Tony GAO Initial 2016-05-04 Mark ZHANG 1. Updated RF Receiving Sensitivity 2. Updated Operation Temperature 2016-07-22 Sea BAI Added Chapters 2.4, 3.6~3.22, 4, 5 and 9 2016-08-19 Sea BAI Updated Charging Parameters in Table 41 1.4 2017-10-17 Sea BAI/

Beny ZHU/

Jenson WU 1. Modified the name of SC20-CE to SC20-CE R1.1 2. Added the frequency bands of SC20-E, SC20-A, SC20-AU and SC20-J modules

(Tables 2, 3, 4 and 5) 3. Added descriptions of Wi-Fi 5GHz frequency band (Tables 27, 28 and 35) 4. Updated SC20 module operating frequencies

(Table 33) 5. Updated reference circuit design for GNSS passive antenna (Figure 37) 6. Updated antenna requirements (Table 38) 7. Added the current consumption of SC20-E, SC20-A, SC20-AU and SC20-J (Tables 44, 45, 46 and 47) 8. Updated RF output power (Table 48) 9. Added the RF receiving sensitivity of SC20-A, SC20-AU and SC20-J SC20-E,

(Tables 50, 51, 52 and 53) SC20_Hardware_Design Confidential / Released 2 / 122 Smart LTE Module Series SC20 Hardware Design Contents About the Document..................................................................................................................................................2 Contents........................................................................................................................................................................3 Table Index...................................................................................................................................................................6 Figure Index................................................................................................................................................................. 8 1 2 3 Introduction....................................................................................................................................................... 10 Safety Information.................................................................................................................................10 1.1. Product Concept...............................................................................................................................................13 General Description..............................................................................................................................13 2.1. Key Features......................................................................................................................................... 16 2.2. Functional Diagram.............................................................................................................................. 19 2.3. Evaluation Board...................................................................................................................................20 2.4. 3.5. 3.5.1. 3.5.2. 3.4.1. 3.4.2. 3.4.3. Application Interfaces.....................................................................................................................................21 General Description..............................................................................................................................21 3.1. Pin Assignment..................................................................................................................................... 22 3.2. Pin Description......................................................................................................................................23 3.3. Power Supply........................................................................................................................................ 34 3.4. Power Supply Pins.....................................................................................................................34 Decrease Voltage Drop.............................................................................................................34 Reference Design for Power Supply.......................................................................................35 Turn on and off Scenarios...................................................................................................................36 Turn on Module Using the PWRKEY......................................................................................36 Turn off Module...........................................................................................................................38 VRTC Interface......................................................................................................................................38 3.6. Power Output.........................................................................................................................................39 3.7. Battery Charge and Management......................................................................................................40 3.8. USB Interface........................................................................................................................................ 41 3.9. 3.10. UART Interfaces....................................................................................................................................43

(U)SIM Interfaces..................................................................................................................................45 3.11. 3.12. SD Card Interface.................................................................................................................................47 3.13. GPIO Interfaces.................................................................................................................................... 49 I2C Interfaces........................................................................................................................................ 51 3.14. 3.15. ADC Interfaces......................................................................................................................................52 3.16. Motor Drive Interface............................................................................................................................52 LCM Interface........................................................................................................................................53 3.17. 3.18. Touch Panel Interface.......................................................................................................................... 55 3.19. Camera Interfaces................................................................................................................................56 3.19.1. Rear Camera Interface..............................................................................................................56 3.19.2. Front Camera Interface.............................................................................................................58 3.19.3. Design Considerations.............................................................................................................. 60 3.20. Sensor Interfaces..................................................................................................................................61 SC20_Hardware_Design Confidential / Released 3 / 122 Smart LTE Module Series SC20 Hardware Design 3.21. Audio Interfaces....................................................................................................................................62 3.21.1. Reference Circuit Design for Microphone..............................................................................63 3.21.2. Reference Circuit Design for Receiver Interface.................................................................. 63 3.21.3. Reference Circuit Design for Headphone Interface............................................................. 64 3.21.4. Reference Circuit Design for Loudspeaker Interface...........................................................64 3.21.5. Audio Interface Design Considerations..................................................................................65 3.22. Emergency Download Interface.........................................................................................................65 4 Wi-Fi and BT...................................................................................................................................................... 66 4.1. Wi-Fi Overview......................................................................................................................................66 4.1.1. Wi-Fi Performance..................................................................................................................... 66 BT Overview.......................................................................................................................................... 68 BT Performance......................................................................................................................... 69 4.2.1. 4.2. 5 GNSS....................................................................................................................................................................70 GNSS Performance..............................................................................................................................70 GNSS RF Design Guidance............................................................................................................... 70 5.1. 5.2. 6 7 Antenna Interface.............................................................................................................................................72 Main/Rx-diversity Antenna Interfaces................................................................................................72 6.1. 6.1.1. Operating Frequency.................................................................................................................72 Reference Design of Main and Rx-diversity Antenna Interfaces....................................... 74 6.1.2. Reference Design of RF Layout.............................................................................................. 74 6.1.3. 6.2. Wi-Fi/BT Antenna Interface.................................................................................................................76 GNSS Antenna Interface.....................................................................................................................77 6.3. Recommended Circuit for Passive Antenna..........................................................................78 Recommended Circuit for Active Antenna............................................................................. 78 Antenna Installation..............................................................................................................................79 Antenna Requirement................................................................................................................79 Recommended RF Connector for Antenna Installation.......................................................80 6.3.1. 6.3.2. 6.4.1. 6.4.2. 6.4. Electrical, Reliability and Radio Characteristics.....................................................................................82 Absolute Maximum Ratings................................................................................................................ 82 7.1. Power Supply Ratings..........................................................................................................................82 7.2. Charging Performance Specifications...............................................................................................83 7.3. Operating Temperature........................................................................................................................84 7.4. Current Consumption...........................................................................................................................84 7.5. RF Output Power..................................................................................................................................99 7.6. RF Receiving Sensitivity....................................................................................................................101 7.7. Electrostatic Discharge......................................................................................................................105 7.8. 8 Mechanical Dimensions...............................................................................................................................106 Mechanical Dimensions of the Module...........................................................................................106 Recommended Footprint...................................................................................................................108 Top and Bottom Views of the Module............................................................................................. 109 8.1. 8.2. 8.3. 9 Storage, Manufacturing and Packaging..................................................................................................110 SC20_Hardware_Design Confidential / Released 4 / 122 Smart LTE Module Series SC20 Hardware Design 9.1. 9.2. 9.3. Storage................................................................................................................................................. 110 Manufacturing and Soldering............................................................................................................111 Packaging.............................................................................................................................................113 10 Appendix A References............................................................................................................................... 115 11 Appendix B GPRS Coding Schemes........................................................................................................119 12 Appendix C GPRS Multi-slot Classes...................................................................................................... 120 13 Appendix D EDGE Modulation and Coding Schemes.........................................................................122 SC20_Hardware_Design Confidential / Released 5 / 122 Smart LTE Module Series SC20 Hardware Design Table Index TABLE 1: SC20-CE R1.1 FREQUENCY BANDS........................................................................................................ 13 TABLE 2: SC20-E FREQUENCY BANDS..................................................................................................................... 14 TABLE 3: SC20-A FREQUENCY BANDS..................................................................................................................... 14 TABLE 4: SC20-AU FREQUENCY BANDS.................................................................................................................. 15 TABLE 5: SC20-J FREQUENCY BANDS......................................................................................................................15 TABLE 6: SC20 KEY FEATURES...................................................................................................................................16 TABLE 7: I/O PARAMETERS DEFINITION...................................................................................................................23 TABLE 8: PIN DESCRIPTION......................................................................................................................................... 23 TABLE 9: POWER DESCRIPTION.................................................................................................................................39 TABLE 10: PIN DEFINITION OF USB INTERFACE.................................................................................................... 41 TABLE 11: USB TRACE LENGTH INSIDE THE MODULE........................................................................................ 43 TABLE 12: PIN DEFINITION OF UART INTERFACES............................................................................................... 43 TABLE 13: PIN DEFINITION OF (U)SIM INTERFACES............................................................................................. 45 TABLE 14: PIN DEFINITION OF SD CARD INTERFACE.......................................................................................... 47 TABLE 15: SD CARD TRACE LENGTH INSIDE THE MODULE.............................................................................. 48 TABLE 16: PIN DEFINITION OF GPIO INTERFACES................................................................................................49 TABLE 17: PIN DEFINITION OF I2C INTERFACES................................................................................................... 51 TABLE 18: PIN DEFINITION OF ADC INTERFACES................................................................................................. 52 TABLE 19: PIN DEFINITION OF MOTOR DRIVE INTERFACE.................................................................................52 TABLE 20: PIN DEFINITION OF LCM INTERFACE....................................................................................................53 TABLE 21: PIN DEFINITION OF TOUCH PANEL INTERFACE.................................................................................55 TABLE 22: PIN DEFINITION OF REAR CAMERA INTERFACE............................................................................... 57 TABLE 23: PIN DEFINITION OF FRONT CAMERA INTERFACE.............................................................................58 TABLE 24: MIPI TRACE LENGTH INSIDE THE MODULE........................................................................................ 60 TABLE 25: PIN DEFINITION OF SENSOR INTERFACES.........................................................................................61 TABLE 26: PIN DEFINITION OF AUDIO INTERFACES............................................................................................. 62 TABLE 27: Wi-Fi TRANSMITTING PERFORMANCE................................................................................................. 66 TABLE 28: Wi-Fi RECEIVING PERFORMANCE......................................................................................................... 67 TABLE 29: BT DATA RATE AND VERSION..................................................................................................................68 TABLE 30: BT TRANSMITTING AND RECEIVING PERFORMANCE..................................................................... 69 TABLE 31: GNSS PERFORMANCE.............................................................................................................................. 70 TABLE 32: PIN DEFINITION OF MAIN/RX-DIVERSITY ANTENNA INTERFACES................................................72 TABLE 33: SC20 MODULE OPERATING FREQUENCIES....................................................................................... 72 TABLE 34: PIN DEFINITION OF Wi-Fi/BT ANTENNA INTERFACE..........................................................................76 TABLE 35: Wi-Fi/BT FREQUENCY................................................................................................................................ 77 TABLE 36: PIN DEFINITION OF GNSS ANTENNA INTERFACE..............................................................................77 TABLE 37: GNSS FREQUENCY.................................................................................................................................... 78 TABLE 38: ANTENNA REQUIREMENTS.......................................................................................................................79 TABLE 39: ABSOLUTE MAXIMUM RATINGS..............................................................................................................82 TABLE 40: SC20 MODULE POWER SUPPLY RATINGS.......................................................................................... 82 TABLE 41: CHARGING PERFORMANCE SPECIFICATIONS..................................................................................83 SC20_Hardware_Design Confidential / Released 6 / 122 Smart LTE Module Series SC20 Hardware Design TABLE 42: OPERATING TEMPERATURE....................................................................................................................84 TABLE 43: SC20-CE R1.1 CURRENT CONSUMPTION............................................................................................84 TABLE 44: SC20-E CURRENT CONSUMPTION........................................................................................................ 87 TABLE 45: SC20-A CURRENT CONSUMPTION........................................................................................................ 91 TABLE 46: SC20-AU CURRENT CONSUMPTION..................................................................................................... 93 TABLE 47: SC20-J CURRENT CONSUMPTION.........................................................................................................97 TABLE 48: RF OUTPUT POWER...................................................................................................................................99 TABLE 49: SC20-CE R1.1 RF RECEIVING SENSITIVITY...................................................................................... 101 TABLE 50: SC20-E RF RECEIVING SENSITIVITY................................................................................................... 102 TABLE 51: SC20-A RF RECEIVING SENSITIVITY................................................................................................... 102 TABLE 52: SC20-AU RF RECEIVING SENSITIVITY................................................................................................ 103 TABLE 53: SC20-J RF RECEIVING SENSITIVITY....................................................................................................104 TABLE 54: ELECTROSTATIC DISCHARGE CHARACTERISTICS ( TEMPERATURE: 25C, HUMIDITY: 45%)

............................................................................................................................................................................................105 TABLE 55: REEL PACKAGING.....................................................................................................................................114 TABLE 56: RELATED DOCUMENTS........................................................................................................................... 115 TABLE 57: TERMS AND ABBREVIATIONS................................................................................................................ 115 TABLE 58: DESCRIPTION OF DIFFERENT CODING SCHEMES.........................................................................119 TABLE 59: GPRS MULTI-SLOT CLASSES................................................................................................................ 120 TABLE 60: EDGE MODULATION AND CODING SCHEMES................................................................................. 122 SC20_Hardware_Design Confidential / Released 7 / 122 Smart LTE Module Series SC20 Hardware Design Figure Index FIGURE 1: FUNCTIONAL DIAGRAM............................................................................................................................ 20 FIGURE 2: PIN ASSIGNMENT (TOP VIEW)................................................................................................................ 22 FIGURE 3: VOLTAGE DROP SAMPLE......................................................................................................................... 34 FIGURE 4: STAR STRUCTURE OF THE POWER SUPPLY.....................................................................................35 FIGURE 5: REFERENCE CIRCUIT OF POWER SUPPLY........................................................................................35 FIGURE 6: TURN ON THE MODULE USING DRIVING CIRCUIT........................................................................... 36 FIGURE 7: TURN ON THE MODULE USING KEYSTROKE.....................................................................................37 FIGURE 8: TIMING OF TURNING ON MODULE........................................................................................................ 37 FIGURE 9: TIMING OF TURNING OFF MODULE...................................................................................................... 38 FIGURE 10: RTC POWERED BY COIN CELL............................................................................................................ 38 FIGURE 11: RTC POWERED BY CAPACITOR........................................................................................................... 39 FIGURE 12: REFERENCE DESIGN FOR BATTERY CHARGING CIRCUIT......................................................... 40 FIGURE 13: USB INTERFACE REFERENCE DESIGN (OTG IS NOT SUPPORTED).........................................42 FIGURE 14: USB INTERFACE REFERENCE DESIGN (OTG IS SUPPORTED).................................................. 42 FIGURE 15: REFERENCE CIRCUIT WITH LEVEL TRANSLATOR CHIP (FOR UART1).................................... 44 FIGURE 16: RS232 LEVEL MATCH CIRCUIT (FOR UART1)...................................................................................44 FIGURE 17: REFERENCE CIRCUIT FOR (U)SIM INTERFACE WITH AN 8-PIN (U)SIM CARD CONNECTOR

..............................................................................................................................................................................................46 FIGURE 18: REFERENCE CIRCUIT FOR (U)SIM INTERFACE WITH A 6-PIN (U)SIM CARD CONNECTOR46 FIGURE 19: REFERENCE CIRCUIT FOR SD CARD INTERFACE.........................................................................48 FIGURE 20: REFERENCE CIRCUIT FOR MOTOR CONNECTION........................................................................ 53 FIGURE 21: REFERENCE CIRCUIT DESIGN FOR LCM INTERFACE.................................................................. 54 FIGURE 22: REFERENCE DESIGN FOR BACKLIGHT DIRVING CIRCUIT......................................................... 55 FIGURE 23: REFERENCE CIRCUIT DESIGN FOR TP INTERFACE......................................................................56 FIGURE 24: REFERENCE CIRCUIT DESIGN FOR REAR CAMERA INTERFACE............................................. 58 FIGURE 25: REFERENCE CIRCUIT DESIGN FOR FRONT CAMERA INTERFACE...........................................59 FIGURE 26: REFERENCE CIRCUIT DESIGN FOR MICROPHONE INTERFACE...............................................63 FIGURE 27: REFERENCE CIRCUIT DESIGN FOR RECEIVER INTERFACE...................................................... 63 FIGURE 28: REFERENCE CIRCUIT DESIGN FOR HEADPHONE INTERFACE................................................. 64 FIGURE 29: REFERENCE CIRCUIT DESIGN FOR LOUDSPEAKER INTERFACE.............................................64 FIGURE 30: REFERENCE CIRCUIT DESIGN FOR EMERGENCY DOWNLOAD INTERFACE........................ 65 FIGURE 31: REFERENCE CIRCUIT DESIGN FOR MAIN AND RX-DIVERSITY ANTENNA INTERFACES.... 74 FIGURE 32: MICROSTRIP LINE DESIGN ON A 2-LAYER PCB.............................................................................. 75 FIGURE 33: COPLANAR WAVEGUIDE LINE DESIGN ON A 2-LAYER PCB........................................................75 FIGURE 34: COPLANAR WAVEGUIDE LINE DESIGN ON A 4-LAYER PCB (LAYER 3 AS REFERENCE GROUND)...........................................................................................................................................................................75 FIGURE 35: COPLANAR WAVEGUIDE LINE DESIGN ON A 4-LAYER PCB (LAYER 4 AS REFERENCE GROUND)...........................................................................................................................................................................76 FIGURE 36: REFERENCE CIRCUIT DESIGN FOR Wi-Fi/BT ANTENNA...............................................................77 FIGURE 37: REFERENCE CIRCUIT DESIGN FOR GNSS PASSIVE ANTENNA.................................................78 FIGURE 38: REFERENCE CIRCUIT DESIGN FOR GNSS ACTIVE ANTENNA....................................................79 SC20_Hardware_Design Confidential / Released 8 / 122 Smart LTE Module Series SC20 Hardware Design FIGURE 39: DIMENSIONS OF THE U.FL-R-SMT CONNECTOR (UNIT: MM)...................................................... 80 FIGURE 40: MECHANICALS OF UF.L-LP CONNECTORS.......................................................................................81 FIGURE 41: SPACE FACTOR OF MATED CONNECTORS (UNIT: MM)................................................................ 81 FIGURE 42: MODULE TOP AND SIDE DIMENSIONS............................................................................................ 106 FIGURE 43: MODULE BOTTOM DIMENSIONS (TOP VIEW).................................................................................107 FIGURE 44: RECOMMENDED FOOTPRINT (TOP VIEW)......................................................................................108 FIGURE 45: TOP VIEW OF THE MODULE................................................................................................................109 FIGURE 46: BOTTOM VIEW OF THE MODULE.......................................................................................................109 FIGURE 47: RECOMMENDED STENCIL DESIGN FOR LGA PADS.....................................................................111 FIGURE 48: REFLOW SOLDERING THERMAL PROFILE..................................................................................... 112 FIGURE 49: TAPE DIMENSIONS.................................................................................................................................113 FIGURE 50: REEL DIMENSIONS................................................................................................................................ 113 SC20_Hardware_Design Confidential / Released 9 / 122 Smart LTE Module Series SC20 Hardware Design 1 Introduction This document defines the SC20 module and describes its air interface and hardware interface which are connected with customers application. This document can help customers quickly understand module interface specifications, electrical and mechanical details as well as other related information of SC20 module. Associated with application note and user guide, customers can use SC20 module to design and set up mobile applications easily. 1.1. Safety Information The following safety precautions must be observed during all phases of operation, such as usage, service or repair of any cellular terminal or mobile incorporating SC20 module. Manufacturers of the cellular terminal should send the following safety information to users and operating personnel, and incorporate these guidelines into all manuals supplied with the product. If not so, Quectel assumes no liability for customers failure to comply with these precautions. Full attention must be given to driving at all times in order to reduce the risk of an accident. Using a mobile while driving (even with a handsfree kit) causes distraction and can lead to an accident. You must comply with laws and regulations restricting the use of wireless devices while driving. Switch off the cellular terminal or mobile before boarding an aircraft. Make sure it is switched off. The operation of wireless appliances in an aircraft is forbidden, so as to prevent interference with communication systems. Consult the airline staff about the use of wireless devices on boarding the aircraft, if your device offers an Airplane Mode which must be enabled prior to boarding an aircraft. Switch off your wireless device when in hospitals,clinics or other health care facilities. These requests are designed to prevent possible interference with sensitive medical equipment. SC20_Hardware_Design Confidential / Released 1-10 / 122 Smart LTE Module Series SC20 Hardware Design Cellular terminals or mobiles operating over radio frequency signal and cellular network cannot be guaranteed to connect in all conditions, for example no mobile fee or with an invalid (U)SIM card. While you are in this condition and need emergent help, please remember using emergency call. In order to make or receive a call, the cellular terminal or mobile must be switched on and in a service area with adequate cellular signal strength. Your cellular terminal or mobile contains a transmitter and receiver. When it is ON, it receives and transmits radio frequency energy. RF interference can occur if it is used close to TV set, radio, computer or other electric equipment. In locations with potentially explosive atmospheres, obey all posted signs to turn off wireless devices such as your phone or other cellular terminals. Areas with potentially explosive atmospheres include fuelling areas, below decks on boats, fuel or chemical transfer or storage facilities, areas where the air contains chemicals or particles such as grain, dust or metal powders, etc. Please do not discard. Maybe wireless devices have an impact on the environment so please do not arbitrarily discarded. Operation frequency for 2G/WCDMA/LTE, BT , BLE , WiFi 2.4GHz , WiFi 5GHz, WiFi 5.8GHz and GPS. related output power range levels and Bluetooth Bluetooth LE 802.11a/b/g/n (HT20/40/80) GSM 900 DCS1800 WCDMA B1 WCDMA B8 LTE B1 LTE B3 LTE B7 LTE B8 LTE B28 2402MHz - 2480 MHz @ 8.96dBm 2402MHz - 2480MHz @ 6.92dBm 2412MHz - 2472 MHz @ 16.82dBm 5150MHz - 5250 MHz @ 17.26dBm 5250MHz - 5350 MHz @ 17.07dBm 5470MHz - 5725 MHz @ 16.36dBm 5725MHz - 5850 MHz @ 13.4dBm 880MHz - 915MHz @ 35dBm 1710MHz - 1785MHz @ 32dBm 1920MHz - 1980MHz @ 25dBm 880MHz - 915MHz @ 25 dBm 1920MHz - 1980MHz @ 25dBm 1710MHz - 1785MHz @ 25dBm 2500MHz - 2570MHz @ 25dBm 880MHz - 915MHz @ 25dBm 703MHz 748 MHz @ 25dBm SC20_Hardware_Design Confidential / Released 1-11 / 122 Smart LTE Module Series SC20 Hardware Design LTE B40 GPS Receiver 2300MHz - 2400MHz @25dBm 1575.42MHz The device is restricted to indoor use only when operating in the 5150 to 5350 MHz frequency range. SC20_Hardware_Design Confidential / Released 1-12 / 122 Smart LTE Module Series SC20 Hardware Design 2 Product Concept 2.1. General Description SC20 is a series of Smart LTE module based on Qualcomm platform and Android operating system, and provides industrial grade performance. It supports worldwide LTE-FDD, LTE-TDD, DC-HSDPA, HSPA+, HSDPA, HSUPA, WCDMA, TD-SCDMA, CDMA, EDGE and GPRS coverage, and also supports short-range wireless communication via Wi-Fi 802.11a/b/g/n and BT4.1 LE. Additionally, SC20 integrates GPS/GLONASS/BeiDou satellite positioning systems. Due to multiple speech and audio and video codecs as well as the built-in high performance AdrenoTM 304 graphics processing unit, it enables smooth play of 720P videos. The module also offers multiple audio and video input/output interfaces as well as abundant GPIO interfaces. SC20 module contains five variants: SC20-CE R1.1, SC20-E, SC20-A, SC20-AU and SC20-J. The following tables show the supported frequency bands and network standards of SC20. Table 1: SC20-CE R1.1 Frequency Bands Type LTE-FDD LTE-TDD WCDMA TD-SCDMA CDMA GSM Wi-Fi 802.11a/b/g/n BT4.1 LE GNSS Frequency B1/B3/B5/B8 B38/B39/B40/B41 B1/B8 B34/B39 BC0 900/1800MHz 2400MHz~2482MHz 5180MHz~5825MHz 2402MHz~2480MHz GPS: 1575.42MHz1.023MHz GLONASS: 1597.5MHz~1605.8MHz SC20_Hardware_Design Confidential / Released 2-13 / 122 Smart LTE Module Series SC20 Hardware Design BeiDou: 1561.098MHz2.046MHz Table 2: SC20-E Frequency Bands Type LTE-FDD LTE-TDD WCDMA GSM Wi-Fi 802.11a/b/g/n BT4.1 LE GNSS Table 3: SC20-A Frequency Bands Type LTE-FDD WCDMA GSM Wi-Fi 802.11a/b/g/n BT4.1 LE GNSS Frequency B1/B3/B5/B7/B8/B20 B38/B40/B41 B1/B5/B8 850/900/1800/1900MHz 2400MHz~2482MHz 5180MHz~5825MHz 2402MHz~2480MHz GPS: 1575.42MHz1.023MHz GLONASS: 1597.5MHz~1605.8MHz BeiDou: 1561.098MHz2.046MHz Frequency B2/B4/B5/B7/B12/B13/B25/B26 B1/B2/B4/B5/B8 850/1900MHz 2400MHz~2482MHz 5180MHz~5825MHz 2402MHz~2480MHz GPS: 1575.42MHz1.023MHz GLONASS: 1597.5MHz~1605.8MHz BeiDou: 1561.098MHz2.046MHz SC20_Hardware_Design Confidential / Released 2-14 / 122 Smart LTE Module Series SC20 Hardware Design Table 4: SC20-AU Frequency Bands Type LTE-FDD LTE-TDD WCDMA GSM Wi-Fi 802.11a/b/g/n BT4.1 LE GNSS Table 5: SC20-J Frequency Bands Type LTE-FDD LTE-TDD WCDMA Wi-Fi 802.11a/b/g/n BT4.1 LE GNSS Frequency B1/B3/B5/B7/B8/B28 B40 B1/B2/B5/B8 850/900/1800/1900MHz 2400MHz~2482MHz 5180MHz~5825MHz 2402MHz~2480MHz GPS: 1575.42MHz1.023MHz GLONASS: 1597.5MHz~1605.8MHz BeiDou: 1561.098MHz2.046MHz Frequency B1/B3/B8/B18/B19/B26 B41 B1/B6/B8/B19 2400MHz~2496MHz 5180MHz~5825MHz 2402MHz~2480MHz GPS: 1575.42MHz1.023MHz GLONASS: 1597.5MHz~1605.8MHz BeiDou: 1561.098MHz2.046MHz SC20 is an SMD type module, which can be embedded into applications through its 210-pin pads including 146 LCC signal pads and 64 other pads. With a compact profile of 40.5mm 40.5mm 2.8mm, SC20 can meet almost all requirements for M2M applications such as CPE, wireless POS, smart metering, router, data card, automotive, smart phone, digital signage, alarm panel, security and industry PDA, etc. SC20_Hardware_Design Confidential / Released 2-15 / 122 Smart LTE Module Series SC20 Hardware Design 2.2. Key Features The following table describes the detailed features of SC20 module. Table 6: SC20 Key Features Feature Details Applications Processor Modem DSP Memory ARM Cortex-A7 microprocessor cores (quad-core) up to 1.1GHz 512KB L2 cache QDSP6 v5 core up to 691.2MHz 768KB L2 cache 8GB EMMC+8Gb LPDDR3 Operating System Android 6.0 Power Supply Transmitting Power LTE Features UMTS Features TD-SCDMA Features CDMA2000 Features Supply voltage: 3.5V~4.2V Typical supply voltage: 3.8V Class 4 (33dBm2dB) for GSM850 and EGSM900 Class 1 (30dBm2dB) for DCS1800 and PCS1900 Class E2 (27dBm3dB) for GSM850 and EGSM900 8-PSK Class E2 (26dBm3dB) for DCS1800 and PCS1900 8-PSK Class 3 (24dBm+1/-3dB) for WCDMA bands Class 3 (24dBm+3/-1dB) for CDMA BC0 Class 2 (24dBm+1/-3dB) for TD-SCDMA bands Class 3 (23dBm2dB) for LTE-FDD bands Class 3 (23dBm2dB) for LTE-TDD bands Support 3GPP R8 Cat.4 FDD and TDD Support 1.4 to 20 MHz RF bandwidth Support DL 2 x 2 MIMO FDD: Max 150Mbps (DL)/Max 50Mbps (UL) TDD: Max 130Mbps (DL)/Max 35Mbps (UL) Support 3GPP R8 DC-HSDPA/HSPA+/HSDPA/HSUPA/WCDMA Support 16-QAM, 64-QAM and QPSK modulation DC-HSDPA: Max 42Mbps (DL) HSUPA: Max 5.76Mbps (UL) WCDMA: Max 384Kbps (DL)/Max 384Kbps (UL) Support CCSA Release 3 Max 4.2Mbps (DL)/Max 2.2Mbps (UL) Support 3GPP2 CDMA2000 1X Advanced, CDMA2000 1x EV-DO Rev.A EVDO: Max 3.1Mbps (DL)/Max 1.8Mbps (UL) 1X Advanced: Max 307.2Kbps (DL)/Max 307.2Kbps (UL) SC20_Hardware_Design Confidential / Released 2-16 / 122 Smart LTE Module Series SC20 Hardware Design R99:

CSD: 9.6kbps, 14.4kbps GPRS:

Support GPRS multi-slot class 33 (33 by default) Coding scheme: CS-1, CS-2, CS-3 and CS-4 Max 85.6Kbps (UL)/Max 107Kbps (DL) EDGE:

Support EDGE multi-slot class 33 (33 by default) Support GMSK and 8-PSK for different MCS (Modulation and Coding Scheme) Downlink coding schemes: CS 1-4 and MCS 1-9 Uplink coding schemes: CS 1-4 and MCS 1-9 Max 236.8Kbps (UL)/Max 296Kbps (DL) Support 2.4GHz and 5GHz frequency bands Support 802.11a/b/g/n, maximally up to 150Mbps Support AP mode GSM Features WLAN Features Bluetooth Feature BT4.1 LE GNSS Features GPS/GLONASS/BeiDou SMS LCM Interface Camera Interfaces Video Codec Audio Interfaces Text and PDU mode Point-to-point MO and MT SMS cell broadcast SMS storage: ME by default 4-lane MIPI_DSI, up to 1.5Gbps per lane Support WVGA (2-lane MIPI_DSI), up to 720p (4-lane MIPI_DSI) 24bit color depth Use MIPI_CSI, up to 1.5Gbps per lane Support two cameras:

2-lane MIPI_CSI for rear camera, max pixel up to 8MP 1-lane MIPI_CSI for front camera, max pixel up to 2MP Video encoding:

H.264 BP/MP 720p @30fps MPEG-4 SP/H.263 P0 WVGA @30fps VP8 WVGA @30fps Video decoding:

H.264 BP/MP/HP 1080P @30fps MPEG-4 SP/ASP 1080P @30fps DivX 4x/5x/6x 1080P @30fps H.263 P0 WVGA @30fps VP8 1080P @30 fps

(HEVC) H.265 MP 8 bit 1080P @30fps Audio input:

2 groups of analog microphone input, integrating internal bias voltage SC20_Hardware_Design Confidential / Released 2-17 / 122 Smart LTE Module Series SC20 Hardware Design Audio output:

Class AB stereo headphone output Class AB earpiece differential output Class D speaker differential amplifier output Audio Codec HR, FR, EFR, AMR, AMR-WB USB Interface

(U)SIM Interfaces UART Interfaces Compliant with USB 2.0 specification; the data transfer rate can reach up to 480Mbps Used for AT command communication, data transmission, software debugging and firmware upgrade Support USB OTG (Need additional 5V power supply chip) USB Driver: Support Windows XP, Windows Vista, Windows 7/8/8.1 2 groups of (U)SIM interfaces Support USIM/SIM card: 1.8V, 2.95V Support Dual SIM Dual Standby (supported by default) 2 UART interfaces: UART1 and UART2 UART1: 4-wire UART interface with RTS/CTS hardware flow control;

baud rate up to 4Mbps UART2: 2-wire UART interface used for debugging Motor Drive Interface Drive ERM motor SD Card Interface I2C Interfaces ADC Interfaces Support SD 3.0, 4-bit SDIO Support hot-plug 3 groups of I2C Used for peripherals such as camera, sensor, touch panel, etc. Support 3 ADC interfaces Used for input voltage sense, battery temperature detection and general purpose ADC Real Time Clock Supported Antenna Interfaces Main antenna, DRX antenna, GNSS antenna and Wi-Fi/BT antenna Physical Characteristics Temperature Range Size: (40.50.15) (40.50.15) (2.80.2)mm Package: LCC Weight: approx. 9.8g Operating temperature range: -35C~+65C 1) Extended temperature range: -40C~+75C 2) Firmware Upgrade Over USB interface RoHS All hardware components are fully compliant with EU RoHS directive SC20_Hardware_Design Confidential / Released 2-18 / 122 Smart LTE Module Series SC20 Hardware Design NOTES 1. 2. 1) Within operation temperature range, the module is 3GPP compliant. 2) Within extended temperature range, the module remains the ability to establish and maintain a voice, SMS, data transmission, emergency call, etc. There is no unrecoverable malfunction. There are also no effects on radio spectrum and no harm to radio network. Only one or more parameters like Pout might reduce in their value and exceed the specified tolerances. When the temperature returns to the normal operating temperature levels, the module will meet 3GPP specifications again. 2.3. Functional Diagram The following figure shows a block diagram of SC20 and illustrates the major functional parts. Power management Radio frequency Baseband LPDDR3+EMMC flash Peripheral interfaces

--USB interface

--UART interfaces

--(U)SIM interfaces

--SD card interface

--GPIO interfaces

--I2C interfaces

--ADC interfaces

--LCM (MIPI) interface

--TP interface

--CAM (MIPI) interface

--Audio interfaces SC20_Hardware_Design Confidential / Released 2-19 / 122 Smart LTE Module Series SC20 Hardware Design Figure 1: Functional Diagram 2.4. Evaluation Board In order to help customers develop applications with SC20 conveniently, Quectel supplies the evaluation board (SMART EVB), USB to RS232 converter cable, USB data cable, power adapter, battery, earphone, antenna and other peripherals to control or to document [1]. the module. For more details, please refer test SC20_Hardware_Design Confidential / Released 2-20 / 122 Smart LTE Module Series SC20 Hardware Design 3 Application Interfaces 3.1. General Description SC20 is equipped with 146-pin 1.0mm pitch SMT pads plus 64-pin ground/reserved pads that can be embedded into cellular application platform. The following chapters provide the detailed description of pins/interfaces listed below. Power supply VRTC interface USB interface UART interfaces SD card interface GPIO interfaces I2C interfaces ADC interfaces Motor drive interface LCM interface

(U)SIM interfaces TP interface Camera interfaces Sensor interfaces Audio interfaces Emergency download interface SC20_Hardware_Design Confidential / Released 3-21 / 122 Smart LTE Module Series SC20 Hardware Design 3.2. Pin Assignment The following figure shows the pin assignment of SC20 module. Figure 2: Pin Assignment (Top View) SC20_Hardware_Design Confidential / Released 3-22 / 122 Smart LTE Module Series SC20 Hardware Design 3.3. Pin Description The following tables show the SC20s pin definition. Table 7: I/O Parameters Definition Type IO DI DO PI PO AI AO OD Description Bidirectional Digital input Digital output Power input Power output Analog input Analog output Open drain Table 8: Pin Description Power Supply Pin Name Pin No. I/O Description DC Characteristics Comment VBAT_BB 1, 2 PI VBAT_RF 145, 146 PI VRTC 126 PI/PO Power supply for modules baseband part. Power supply for modules RF part. Power supply for internal RTC circuit. Vmax=4.2V Vmin=3.5V Vnorm=3.8V Vmax=4.2V Vmin=3.5V Vnorm=3.8V VOmax=3.2V VI=2.0V~3.25V LDO5_1V8 111 PO 1.8V output power supply Vnorm=1.8V IOmax=20mA It must be able to provide sufficient current up to 3.0A. It is suggested to use a zener diode for voltage stabilization. If unused, keep this pin open. Power supply for external GPIOs pull up circuits and level conversion circuit. SC20_Hardware_Design Confidential / Released 3-23 / 122 LDO6_1V8 125 PO 1.8V output power supply Vnorm=1.8V IOmax=100mA LDO17_2V85 129 PO 2.85V output power supply Vnorm=2.85V IOmax=300mA Smart LTE Module Series SC20 Hardware Design Power supply for peripherals. 2.2uF~4.7uF capacitor is recommended to be applied to the LDO6_1V8 pin. If unused, keep this pin open. Power supply for peripherals. 2.2uF~4.7uF capacitor is recommended to be applied to the LDO17_2V85 pin. If unused, keep this pin open. SD_LDO11 38 PO Power supply for SD card. Vnorm=2.95V IOmax=600mA SD_LDO12 32 PO 1.8V/2.95V output power supply Vnorm=2.95V IOmax=50mA Power supply for SDs pull up circuits. GND 3, 7, 12, 15, 27, 51, 62, 69, 76, 78, 85, 86, 88, 89, 120, 122, 130, 132, 135, 140, 143, 144, 147~150, 160~178, 180~182, 184~186, 188~189, 192~193, 198~200, 201~208, GND SC20_Hardware_Design Confidential / Released 3-24 / 122 Smart LTE Module Series SC20 Hardware Design 209 Audio Interfaces Pin Name Pin No. I/O Description DC Characteristics Comment 4 5 6 8 9 10 11 136 137 138 139 MIC1P MIC_GND MIC2P EARP EARN SPKP SPKN HPH_R HPH_GND HPH_L HS_DET USB Interface AI AI AO AO AO AO AO AI AO AI Microphone positive input for channel 1 MIC reference ground Microphone positive input for channel 2 Earpiece positive output Earpiece negative output Speaker positive output Speaker negative output Headphone right channel output Headphone virtual ground Headphone left channel output Headset insertion detection High level by default. Pin Name Pin No. I/O Description DC Characteristics Comment USB_VBUS 141, 142 PI USB power supply USB_DM USB_DP USB_ID 13 14 16 IO IO AI USB differential data bus (minus) USB differential data bus (plus) USB ID detection Vmax=6.3V Vmin=4.35V Vnorm=5.0V Used for USB 5V power input and USB detection. Compliant with USB 2.0 standard specification. Require differential impedance of 90. High level by default. SC20_Hardware_Design Confidential / Released 3-25 / 122 Smart LTE Module Series SC20 Hardware Design

(U)SIM Interfaces Pin Name Pin No. I/O Description DC Characteristics Comment USIM2_ DETECT 17 DI

(U)SIM2 card hot-plug detection VILmax=0.63V VIHmin=1.17V Active Low. External pull-up resistor is required. If unused, keep this pin open. USIM2_RST 18 USIM2_CLK 19 DO DO

(U)SIM2 card reset signal

(U)SIM2 card clock signal USIM2_DATA 20 IO

(U)SIM2 card data signal USIM2_VDD 21 PO

(U)SIM2 card power supply VOLmax=0.4V VOHmin=

0.8USIM2_VDD VOLmax=0.4V VOHmin=

0.8USIM2_VDD VILmax=

0.2USIM2_VDD VIHmin=

0.7USIM2_VDD VOLmax=0.4V VOHmin=

0.8USIM2_VDD For 1.8V (U)SIM:

Vmax=1.85V Vmin=1.75V For 2.95V (U)SIM:

Vmax=3.1V Vmin=2.8V USIM1_ DETECT 22 DI

(U)SIM1 card hot-plug detection VILmax=0.63V VIHmin=1.17V USIM1_RST 23 USIM1_CLK 24 DO DO

(U)SIM1 card reset signal

(U)SIM1 card clock signal USIM1_DATA 25 IO

(U)SIM1 card data signal VOLmax=0.4V VOHmin=

0.8USIM1_VDD VOLmax=0.4V VOHmin=

0.8USIM1_VDD VILmax=

0.2USIM1_VDD VIHmin=

0.7USIM1_VDD Either 1.8V or 2.95V

(U)SIM card is supported by the module automatically. Active low. External pull-up resistor is required. If unused, keep this pin open. SC20_Hardware_Design Confidential / Released 3-26 / 122 Smart LTE Module Series SC20 Hardware Design VOLmax=0.4V VOHmin=

0.8USIM1_VDD For 1.8V (U)SIM:

Vmax=1.85V Vmin=1.75V For 2.95V (U)SIM:

Vmax=3.1V Vmin=2.8V Either 1.8V or 2.95V

(U)SIM card is supported by the module automatically USIM1_VDD 26 PO

(U)SIM1 card power supply UART Interfaces Pin Name Pin No. I/O Description DC Characteristics Comment UART1_TX UART1_RX 34 35 DO UART1 transmit data VOLmax=0.45V VOHmin=1.35V DI UART1 receive data VILmax=0.63V VIHmin=1.17V UART1_CTS 36 UART1_RTS 37 DI DO UART1 clear to send VILmax=0.63V VIHmin=1.17V UART1 request to send VOLmax=0.45V VOHmin=1.35V UART2_RX 93 DI UART2_TX 94 DO SD Card Interface UART2 receive data. Debug port by default. UART2 transmit data. Debug port by default. VILmax=0.63V VIHmin=1.17V VOLmax=0.45V VOHmin=1.35V 1.8V power domain. If unused, keep this pin open. 1.8V power domain. If unused, keep this pin open. 1.8V power domain. If unused, keep this pin open. 1.8V power domain. If unused, keep this pin open. 1.8V power domain. If unused, keep this pin open. 1.8V power domain. If unused, keep this pin open. Pin Name Pin No. I/O Description DC Characteristics Comment SD_CLK 39 DO High speed digital clock signal of SD card 1.8V SD card:

VOLmax=0.45V VOHmin=1.4V 2.95V SD card:

VOLmax=0.37V SC20_Hardware_Design Confidential / Released 3-27 / 122 Smart LTE Module Series SC20 Hardware Design VOHmin=2.2V 1.8V SD card:

VILmax=0.58V VIHmin=1.27V VOLmax=0.45V VOHmin=1.4V 2.95V SD card:

VILmax=0.73V VIHmin=1.84V VOLmax=0.37V VOHmin=2.2V 1.8V SD card:

VILmax=0.58V VIHmin=1.27V VOLmax=0.45V VOHmin=1.4V 2.95V SD card:

VILmax=0.73V VIHmin=1.84V VOLmax=0.37V VOHmin=2.2V SD_CMD 40 IO Command signal of SD card SD_DATA0 41 SD_DATA1 42 SD_DATA2 43 SD_DATA3 SD_DET 44 45 IO IO IO IO DI High speed bidirectional digital signal lines of SD card SD card insertion detection VILmax=0.63V VIHmin=1.17V Active low Touch Panel (TP) Interface Pin Name Pin No. I/O Description DC Characteristics Comment 30 31 47 48 TP_INT TP_RST TP_I2C_SCL TP_I2C_SDA LCM Interface VILmax=0.63V VIHmin=1.17V VOLmax=0.45V VOHmin=1.35V DI Interrupt signal of TP DO Reset signal of TP OD I2C clock signal of TP OD I2C data signal of TP 1.8V power domain. 1.8V power domain. Active low. 1.8V power domain. 1.8V power domain. SC20_Hardware_Design Confidential / Released 3-28 / 122 Pin Name Pin No. I/O Description DC Characteristics Comment Smart LTE Module Series SC20 Hardware Design VOLmax=0.45V VOHmax=VBAT_BB VOLmax=0.45V VOHmin=1.35V VILmax=0.63V VIHmin=1.17V 1.8V power domain. Active low. 1.8V power domain. PWM LCD_RST LCD_TE MIPI_DSI_ CLKN MIPI_DSI_ CLKP MIPI_DSI_ LN0N MIPI_DSI_ LN0P MIPI_DSI_ LN1N MIPI_DSI_ LN1P MIPI_DSI_ LN2N MIPI_DSI_ LN2P MIPI_DSI_ LN3N MIPI_DSI_ LN3P 29 49 50 52 53 54 55 56 57 58 59 60 61 DO Adjust the backlight brightness. PWM control signal. DO LCD reset signal DI AO AO AO AO AO AO AO AO AO AO LCD tearing effect signal MIPI DSI clock signal

(negative) MIPI DSI clock signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) Camera Interfaces Pin Name Pin No I/O Description DC Characteristics Comment MIPI_CSI0_ CLKN MIPI_CSI0_ CLKP 63 64 AI AI MIPI CSI clock signal

(negative) MIPI CSI clock signal

(positive) SC20_Hardware_Design Confidential / Released 3-29 / 122 Smart LTE Module Series SC20 Hardware Design MIPI_CSI0_ LN0N MIPI_CSI0_ LN0P MIPI_CSI0_ LN1N MIPI_CSI0_ LN1P MIPI_CSI1_ CLKN MIPI_CSI1_ CLKP MIPI_CSI1_ LN0N MIPI_CSI1_ LN0P 65 66 67 68 70 71 72 73 CAM0_MCLK 74 CAM1_MCLK 75 CAM0_RST 79 CAM0_PWD 80 CAM1_RST 81 CAM1_PWD 82 CAM_I2C_ SCL CAM_I2C_ SDA 83 84 Keypad Interfaces AI AI AI AI AI AI AI AI DO DO DO DO DO DO OD OD MIPI CSI data signal

(negative) MIPI CSI data signal

(positive) MIPI CSI data signal

(negative) MIPI CSI data signal

(positive) MIPI CSI clock signal

(negative) MIPI CSI clock signal

(positive) MIPI CSI data signal

(negative) MIPI CSI data signal

(positive) Clock signal of rear camera VOLmax=0.45V VOHmin=1.35V Clock signal of front camera VOLmax=0.45V VOHmin=1.35V Reset signal of rear camera VOLmax=0.45V VOHmin=1.35V Power down signal of rear camera VOLmax=0.45V VOHmin=1.35V Reset signal of front camera VOLmax=0.45V VOHmin=1.35V Power down signal of front camera VOLmax=0.45V VOHmin=1.35V I2C clock signal of camera I2C data signal of camera 1.8V power domain. 1.8V power domain. SC20_Hardware_Design Confidential / Released 3-30 / 122 Smart LTE Module Series SC20 Hardware Design Pin Name Pin No I/O Description DC Characteristics Comment PWRKEY 114 DI Turn on/off the module KEY_VOL_ UP KEY_VOL_ DOWN 95 96 SENSOR_I2C Interface DI Volume up DI Volume down VILmax=0.63V VIHmin=1.17V VILmax=0.63V VIHmin=1.17V VILmax=0.63V VIHmin=1.17V Pull-up to 1.8V internally, active low. If unused, keep this pin open. If unused, keep this pin open. Pin Name Pin No. I/O Description DC Characteristics Comment SENSOR_I2C _SCL SENSOR_I2C _SDA 91 92 ADC Interfaces OD OD I2C clock signal for external sensor I2C data signal for external sensor 1.8V power domain. 1.8V power domain. Pin Name Pin No. I/O Description DC Characteristics Comment ADC 128 AI General purpose ADC VBAT_SNS 133 AI Input voltage sense 134 AI Battery temperature detection VBAT_ THERM RF Interface Maximum voltage not exceeding 1.7V Maximum input voltage is 4.5V. Pin Name Pin No. I/O Description DC Characteristics Comment ANT_MAIN ANT_DRX ANT_GNSS 87 131 121 IO AI AI Main antenna Diversity antenna GNSS antenna ANT_WIFI/BT 77 IO Wi-Fi/BT antenna GPIO Interfaces 50 impedance Pin Name Pin No. I/O Description DC Characteristics Comment SC20_Hardware_Design Confidential / Released 3-31 / 122 Smart LTE Module Series SC20 Hardware Design GPIO_23 GPIO_32 GPIO_31 GPIO_92 GPIO_88 GPIO_89 GPIO_69 GPIO_68 GPIO_97 GPIO_110 GPIO_0 GPIO_98 GPIO_94 GPIO_36 GPIO_65 GPIO_96 GPIO_58 GPIO_99 GPIO_95 GPIO_11 GPIO_10 GPIO_9 GPIO_8 GPIO_16 GPIO_17 33 90 97 98 99 100 101 102 103 104 105 106 107 108 109 110 112 113 115 116 117 118 119 123 124 IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO GPIO SC20_Hardware_Design Confidential / Released 3-32 / 122 Smart LTE Module Series SC20 Hardware Design Other Interfaces Pin Name Pin No. I/O Description DC Characteristics Comment VIB_DRV 28 PO Motor drive RESET_N 179 DI Reset the module USB_BOOT 46 DI Force the module to boot from USB port CHARGE_ SEL 127 DI Used for charger selection Connected to the negative terminal of the motor. Set USB_BOOT pin to high level will force the module to enter into emergency download mode. If it is open, internal charger is used;

If it is connected to GND, external charger is used. Reserved Interface Pin Name Pin No. I/O Description DC Characteristics Comment RESERVED 151, 152, 153, 154, 155, 156, 157, 158, 159, 183, 187, 190, 191, 194, 195, 196, 197, 199, 202, 203, 204, 205, 206, 207, 210 Reserved pins Not connected by default. SC20_Hardware_Design Confidential / Released 3-33 / 122 Smart LTE Module Series SC20 Hardware Design 3.4. Power Supply 3.4.1. Power Supply Pins SC20 provides four VBAT pins dedicated to connection with the external power supply. Two VBAT_RF pins are used for modules RF part; two VBAT_BB pins are used for modules baseband part. 3.4.2. Decrease Voltage Drop The power supply range of the module is 3.5V~4.2V, and the recommended value is 3.8V. The power supply performance, such as load capacity, voltage ripple, etc. directly influences the modules performance and stability. Under ultimate conditions, the module may have a transient peak current up to 3A. If the supply voltage is not enough, there will be voltage drops, and if the voltage drops below 3.1V, the module will be turned off automatically. Therefore, please make sure the input voltage will never drop below 3.1V. Figure 3: Voltage Drop Sample To decrease voltage drop, a bypass capacitor of about 100F with low ESR (ESR=0.7) should be used, and a multi-layer ceramic chip capacitor (MLCC) should also be reserved due to its ultra-low ESR. It is recommended to use three ceramic capacitors (100nF, 33pF, 10pF) for composing the MLCC array, and place these capacitors close to VBAT_BB/RF pins. The main power supply from an external application has to be a single voltage source and can be expanded to two sub paths with star structure. The width of VBAT_BB trace should be no less than 1.5mm, and the width of VBAT_RF trace should be no less than 2mm. In principle, the longer the VBAT trace is, the wider it will be. In addition, in order to get a stable power source, it is suggested to use a 0.5W zener diode and place it as close to the VBAT_BB/RF pins as possible. The following figure shows the star structure of the power supply. SC20_Hardware_Design Confidential / Released 3-34 / 122 Smart LTE Module Series SC20 Hardware Design Figure 4: Star Structure of the Power Supply 3.4.3. Reference Design for Power Supply The power design for the module is very important, as the performance of module largely depends on the power source. The power supply of SC20 should be able to provide sufficient current up to 3A at least. If the voltage drop between the input and output is not too high, it is suggested to use an LDO to supply power for the module. If there is a big voltage difference between the input source and the desired output

(VBAT), a buck converter is preferred to be used as the power supply. The following figure shows a reference design for +5V input power source which adopts an LDO

(MIC29302WU) from MICREL. The typical output voltage is 3.8V and the maximum load current is 3.0A. Figure 5: Reference Circuit of Power Supply SC20_Hardware_Design Confidential / Released 3-35 / 122 Smart LTE Module Series SC20 Hardware Design NOTES 1. It is suggested that customers should switch off the power supply for module in abnormal state, and then switch on the power to restart the module. 2. The module supports battery charging function by default. If the above power supply design is adopted, please make sure the charging function is disabled by software, or connect VBAT to Schottky diode in series to avoid the reverse current to the power supply chip. 3.5. Turn on and off Scenarios 3.5.1. Turn on Module Using the PWRKEY The module can be turned on by driving PWRKEY pin to a low level for at least 1.6s. PWRKEY pin is pulled to 1.8V internally. It is recommended to use an open drain/collector driver to control the PWRKEY. A simple reference circuit is illustrated in the following figure. Figure 6: Turn on the Module Using Driving Circuit The other way to control the PWRKEY is using a button directly. A TVS component is indispensable to be placed nearby the button for ESD protection. A reference circuit is shown in the following figure. SC20_Hardware_Design Confidential / Released 3-36 / 122 Smart LTE Module Series SC20 Hardware Design Figure 7: Turn on the Module Using Keystroke The turning on scenario is illustrated in the following figure. Figure 8: Timing of Turning on Module NOTE Make sure that VBAT is stable before pulling down PWRKEY pin. The recommended time between them is no less than 30ms. PWRKEY pin cannot be pulled down all the time. SC20_Hardware_Design Confidential / Released 3-37 / 122 Smart LTE Module Series SC20 Hardware Design 3.5.2. Turn off Module Set the PWRKEY pin low for at least 1s, and then choose to turn off the module when the prompt window comes up. The other way to turn off the module is to drive PWRKEY to a low level for at least 8s. The module will execute forced shutdown. The forced power-down scenario is illustrated in the following figure. Figure 9: Timing of Turning off Module 3.6. VRTC Interface The RTC (Real Time Clock) can be powered by an external power source through VRTC when the module is powered down and there is no power supply for the VBAT. The external power source can be capacitor or rechargeable battery (such as coil cells) according to application demands. The following are some reference circuit designs when an external battery or capacitor is utilized for powering RTC. Figure 10: RTC Powered by Coin Cell SC20_Hardware_Design Confidential / Released 3-38 / 122 Smart LTE Module Series SC20 Hardware Design Figure 11: RTC Powered by Capacitor If RTC is ineffective, it can be synchronized through network after the module is powered on. 2.0V~3.25V input voltage range and 3.0V typical value for VRTC. When VBAT is disconnected, the average consumption is about 5uA. When powered by VBAT, the RTC error is 50ppm. When powered by VRTC, the RTC error is 200ppm. If the rechargeable battery is used, the ESR of the battery should be less than 2K, and it is recommended to use the MS621FE FL11E of SEIKO. If large capacitance capacitor is selected, it is recommended to use a 100uF capacitor with low ESR. The capacitor will be able to power the real-time clock for 45 seconds. 3.7. Power Output SC20 supports output of regulated voltages for peripheral circuits. During application, it is recommended to use parallel capacitors (33pF and 10pF) in the circuit to suppress high frequency noise. Table 9: Power Description Pin Name Voltage Range (V) Default Voltage (V) Driving Current (mA) IDLE LDO5_1V8 LDO6_1V8 LDO17_2V85

-

-

-

SD_LDO12 1.750~3.337 SD_LDO11 1.750~3.337 1.8 1.8 2.85 2.95 2.95 USIM1_VDD 1.750~3.337 1.80/2.95 20 100 300 50 600 50 KEEP

/

/

/

/

SC20_Hardware_Design Confidential / Released 3-39 / 122 Smart LTE Module Series SC20 Hardware Design USIM2_VDD 1.750~3.337 1.80/2.95 50 3.8. Battery Charge and Management SC20 module can recharge batteries. The battery charger in SC20 module supports trickle charging, constant current charging and constant voltage charging modes, which optimize the charging procedure for Li-ion batteries. Trickle charging: There are two steps in this mode. When the battery voltage is below 2.8V, a 90mA trickle charging current is applied to the battery. When the battery voltage is charged up and is between 2.8V and 3.2V, the charging current can be set to 450mA maximally. Constant current mode (CC mode): When the battery is increased to between 3.2V and 4.2V, the system will switch to CC mode. The maximum charging current is 1.44A when adapter is used for battery charging; and the maximum charging current is 450mA while USB charging. Constant voltage mode (CV mode): When the battery voltage reaches the final value 4.2V, the system will switch to CV mode and the charging current will decrease gradually. When the battery level reaches 100%, the charging is completed. SC20 module supports battery temperature detection in the condition that the battery integrates a thermistor (47K 1% NTC thermistor with B-constant of 4050K by default; SDNT1608X473F4050FTF of SUNLORD is recommended) and the thermistor is connected to VBAT_THERM pin. The default battery temperature range is -3.0C~48.5C. If VBAT_THERM pin is not connected, there will be malfunctions such as battery charging failure, battery level display error, etc. A reference design for battery charging circuit is shown as below. Figure 12: Reference Design for Battery Charging Circuit SC20_Hardware_Design Confidential / Released 3-40 / 122 Smart LTE Module Series SC20 Hardware Design Mobile devices such as mobile phones and handheld POS systems are powered by batteries. When different batteries are utilized, the charging and discharging curve has to be modified correspondingly so as to achieve the best effect. If thermistor is not available in the battery, or adapter is utilized for powering module, then there is only need for VBAT and GND connection. In this case, the system may mistakenly judge that the battery temperature is abnormal, which will cause battery charging failure. In order to avoid this, VBAT_THERM should be connected to GND via a 47K resistor. If VBAT_THERM is unconnected, the system will be unable to detect the battery, making battery cannot be charged. VBAT_SNS pin must be connected. Otherwise, the module will have abnormalities in voltage detection, as well as associated power on/off and battery charging and discharging issues. 3.9. USB Interface SC20 contains one integrated Universal Serial Bus (USB) interface which complies with the USB 2.0 specification and supports high speed (480Mbps) and full speed (12Mbps) modes. The USB interface is used for AT command communication, data transmission, software debugging and firmware upgrade. The following table shows the pin definition of USB interface. Table 10: Pin Definition of USB Interface Pin Name Pin No. I/O Description USB power supply USB_VBUS 141, 142 USB_DM USB_DP USB_ID 13 14 16 PI IO IO AI Comment 4.35V~6.3V. Typical 5.0V. USB differential data bus (minus) USB differential data bus (plus) Require differential impedance of 90 USB ID detection High level by default USB_VBUS can be powered by USB power or adapter. It can also be used for detecting USB connection, as well as for battery charging via the internal PMU. The input voltage of power supply ranges from 4.35 to 6.3V, and the typical value is 5V. SC20 module supports charging management for a single Li-ion battery, but varied charging parameters should be set for batteries with varied models or capacities. The module is available a built-in linear-charging circuit which supports maximally 1.44A charging current. The following are two USB interface reference designs for customers to choose from. SC20_Hardware_Design Confidential / Released 3-41 / 122 Smart LTE Module Series SC20 Hardware Design Figure 13: USB Interface Reference Design (OTG is not Supported) Figure 14: USB Interface Reference Design (OTG is Supported) SC20 supports OTG protocol. If OTG function is needed, please refer to the above figure for the reference design. AW3605DNR is a high efficiency DC-DC chip manufactured by AWINIC, and customers can choose according to their own demands. In order to ensure USB performance, please comply with the following principles while designing USB interface. SC20_Hardware_Design Confidential / Released 3-42 / 122 It is important to route the USB signal traces as differential pairs with total grounding. The impedance of USB differential trace is 90. Smart LTE Module Series SC20 Hardware Design Keep the ESD protection devices as close as possible to the USB connector. Pay attention to the the junction capacitance of ESD protection devices on USB data lines. Typically, influence of capacitance value should be less than 2pF. Do not route signal traces under crystals, oscillators, magnetic devices and RF signal traces. It is important to route the USB differential traces in inner-layer with ground shielding on not only upper and lower layer but also right and left sides. Make sure the trace length difference between USB_DM and USB_DP is not exceeding 6.6mm. Table 11: USB Trace Length Inside the Module PIN 13 14 Signal USB_DM USB_DP Length (mm) Length Difference (DP-DM) 29.43 29.36

-0.07 3.10. UART Interfaces The module provides two UART interfaces:

UART1: 4-wire UART interface which supports hardware flow control UART2: 2-wire UART interfaces and is used for debugging Table 12: Pin Definition of UART Interfaces Pin Name Pin No UART1_TX UART1_RX UART1_CTS UART1_RTS UART2_RX UART2_TX 34 35 36 37 93 94 I/O DO DI DI DO DI DO Description Comment UART1 transmit data UART1 receive data UART1 clear to send UART1 request to send UART2 receive data. Debug port by default. UART2 transmit data. Debug port by default. 1.8V power domain. If it is unused, keep it open. 1.8V power domain. If it is unused, keep it open. 1.8V power domain. If it is unused, keep it open. 1.8V power domain. If it is unused, keep it open. 1.8V power domain. If it is unused, keep it open. 1.8V power domain. If it is unused, keep it open. SC20_Hardware_Design Confidential / Released 3-43 / 122 Smart LTE Module Series SC20 Hardware Design UART1 provides 1.8V logic level. A level translator should be used if customers application is equipped with a 3.3V UART interface. A level translator TXS0104PWR provided by Texas Instruments is recommended. The following figure shows the reference design. Figure 15: Reference Circuit with Level Translator Chip (for UART1) The following figure is an example of connection between SC20 and PC. A voltage level translator and a RS-232 level translator chip are also recommended to be added between the module and PC, as these two UART interfaces do not support the RS-232 level, while support the 1.8V CMOS level only. Figure 16: RS232 Level Match Circuit (for UART1) NOTE UART2 is similar to UART1. Please refer to UART1 reference circuit designs for UART2s. SC20_Hardware_Design Confidential / Released 3-44 / 122 Smart LTE Module Series SC20 Hardware Design 3.11.

(U)SIM Interfaces SC20 provides 2 (U)SIM interfaces which circuitry meet ETSI and IMT-2000 requirements. Dual SIM Card Dual Standby is supported by default. Both 1.8V and 2.95V (U)SIM cards are supported, and the (U)SIM card interfaces are powered by the internal power supply of SC20 module. Table 13: Pin Definition of (U)SIM Interfaces Pin Name Pin No I/O Description Comment

(U)SIM2 card hot-plug detection Active Low. External pull-up resistor is required. If unused, keep this pin open. USIM2_DETECT USIM2_RST USIM2_CLK USIM2_DATA USIM2_VDD USIM1_DETECT USIM1_RST USIM1_CLK USIM1_DATA USIM1_VDD 17 18 19 20 21 22 23 24 25 26 DI DO DO IO

(U)SIM2 card reset signal

(U)SIM2 card clock signal

(U)SIM2 card data signal PO

(U)SIM2 card power supply DI DO DO IO

(U)SIM1 card hot-plug detection

(U)SIM1 card reset signal

(U)SIM1 card clock signal

(U)SIM1 card data signal PO

(U)SIM1 card power supply Pull-up to USIM2_VDD with a 10K resistor. Either 1.8V or 2.95V (U)SIM card is supported by the module automatically. Active low. External pull-up resistor is required. If unused, keep this pin open. Pull-up to USIM1_VDD with a 10K resistor. Either 1.8V or 2.95V (U)SIM card is supported by the module automatically. SC20 supports (U)SIM card hot-plug via the USIM_DETECT pin. A reference circuit for (U)SIM interface with an 8-pin (U)SIM card connector is shown below. SC20_Hardware_Design Confidential / Released 3-45 / 122 Smart LTE Module Series SC20 Hardware Design Figure 17: Reference Circuit for (U)SIM Interface with an 8-pin (U)SIM Card Connector If there is no need to use USIM_DETECT, please keep it open. The following is a reference circuit for

(U)SIM interface with a 6-pin (U)SIM card connector. Figure 18: Reference Circuit for (U)SIM Interface with a 6-pin (U)SIM Card Connector In order to ensure good performance and avoid damage of (U)SIM cards, please follow the criteria below in (U)SIM circuit design:

Keep placement of (U)SIM card connector as close to the module as possible. Keep the trace length of (U)SIM card signals as less than 200mm as possible. Keep (U)SIM card signals away from RF and VBAT traces. A 100nF filter capacitor shall be reserved for USIM_VDD, and its maximum capacitance should not exceed 1uF. The capacitor should be placed near to (U)SIM card. To avoid cross-talk between USIM_DATA and USIM_CLK, keep them away from each other and shield them with ground. USIM_RST also needs ground protection. SC20_Hardware_Design Confidential / Released 3-46 / 122 Smart LTE Module Series SC20 Hardware Design In order to offer good ESD protection, it is recommended to add a TVS diode array with parasitic capacitance not exceeding 50pF. The 22 resistors should be added in series between the module and (U)SIM card so as to suppress EMI spurious transmission and enhance ESD protection. Please note that the (U)SIM peripheral circuit should be close to the (U)SIM card connector. The 33pF capacitors should be added in parallel on USIM_DATA, USIM_CLK and USIM_RST signal lines so as to filter RF interference, and they should be placed as close to the (U)SIM card connector as possible. 3.12. SD Card Interface SC20 module supports SD cards with 4-bit data interfaces or SDIO devices. The pin definition of the SD card interface is shown below. Comment Vnorm=2.95V IOmax=600mA Support 1.8V or 2.95V power supply. The maximum drive current is 50mA. Control characteristic impedance as 50. Table 14: Pin Definition of SD Card Interface Pin Name Pin No I/O Description SD_LDO11 38 PO Power supply for SD card SD_LDO12 32 PO 1.8V/2.95V output power supply DO High speed digital clock signal of SD card Command signal of SD card High speed bidirectional digital signal lines of SD card SD_CLK SD_CMD SD_DATA0 SD_DATA1 SD_DATA2 SD_DATA3 SD_DET 39 40 41 42 43 44 45 I/O I/O I/O I/O I/O DI SD card insertion detection Active low A reference circuit for SD card interface is shown as below. SC20_Hardware_Design Confidential / Released 3-47 / 122 Smart LTE Module Series SC20 Hardware Design Figure 19: Reference Circuit for SD Card Interface SD_LDO11 is a peripheral driver power supply for SD card. The maximum drive current is approx. 600mA. Because of the high drive current, it is recommended that the trace width is 0.6mm or more. In order to ensure the stability of drive power, a 2.2uF capacitor should be added in parallel near the SD card connector. the characteristic impedance of CMD, CLK, DATA0, DATA1, DATA2 and DATA3 are all high speed signal lines. In PCB design, please control is recommended to route the trace on the inner layer of PCB, and keep the same trace length for CLK, CMD, DATA0, DATA1, DATA2 and DATA3. CLK additionally needs ground shielding. them as 50, and do not cross with other traces. It Layout guidelines:

Control impedance as 5010%, and ground shielding is required. The total trace length difference between CLK and other signal line traces should not exceed 1mm. Table 15: SD Card Trace Length Inside the Module Pin No. Signal Length (mm) Comment 39 40 41 42 43 SD_CLK SD_CMD SD_DATA0 SD_DATA1 SD_DATA2 14.60 14.55 14.53 14.56 14.53 SC20_Hardware_Design Confidential / Released 3-48 / 122 Smart LTE Module Series SC20 Hardware Design 44 SD_DATA3 14.57 3.13. GPIO Interfaces SC20 has abundant GPIO interfaces with logic level of 1.8V. The pin definition is listed below. Table 16: Pin Definition of GPIO Interfaces PIN Pin Name GPIO Default state Comment 30 31 33 34 35 36 37 45 47 48 49 50 74 75 79 80 81 82 TP_INT TP_RST GPIO_23 GPIO_13 B-PD: nppukp Wakeup GPIO_12 B-PD: nppukp Wakeup GPIO_23 B-PD: nppukp UART1_TX GPIO_20 BH-PD: nppukp Wakeup UART1_RX GPIO_21 B-PD: nppukp UART1_RX Wakeup UART1_CTS GPIO_111 B-PD: nppukp Wakeup UART1_RTS GPIO_112 B-PD: nppukp Wakeup SD_DET GPIO_38 B-PD: nppukp Wakeup TP_I2C_SCL GPIO_19 B-PD: nppukp TP_I2C_SDA GPIO_18 B-PD: nppukp LCD_RST LCD_TE CAM0_CLK GPIO_25 B-PD: nppukp Wakeup GPIO_24 GPIO_26 B-PD: nppukp B-PD: nppukp CAM1_CLK GPIO_27 B-PD: nppukp CAM0_RST GPIO_35 B-PD: nppukp Wakeup CAM0_PWD GPIO_34 B-PD: nppukp Wakeup CAM1_RST GPIO_28 B-PD: nppukp Wakeup CAM1_PWD GPIO_33 B-PD: nppukp SC20_Hardware_Design Confidential / Released 3-49 / 122 Smart LTE Module Series SC20 Hardware Design 83 84 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 112 113 CAM_I2C_SCL GPIO_30 B-PD: nppukp CAM_I2C_SDA GPIO_29 B-PD: nppukp GPIO_32 GPIO_32 B-PD: nppukp SENSOR_I2C_SCL GPIO_7 B-PD: nppukp SENSOR_I2C_SDA GPIO_6 B-PD: nppukp UART2_RX UART2_TX GPIO_5 GPIO_4 B-PD: nppukp Wakeup B-PD: nppukp KEY_VOL_UP GPIO_90 B-PD: nppukp Wakeup KEY_VOL_DOWN GPIO_91 B-PD: nppukp Wakeup GPIO_31 GPIO_92 GPIO_88 GPIO_89 GPIO_69 GPIO_68 GPIO_97 GPIO_31 B-PD: nppukp Wakeup GPIO_92 GPIO_88 B-PD: nppukp Wakeup B-PD: nppukp GPIO_89 B-PD: nppukp GPIO_69 B-PD: nppukp GPIO_68 B-PD: nppukp GPIO_97 B-PD: nppukp Wakeup GPIO_110 GPIO_110 B-PD: nppukp Wakeup GPIO_0 GPIO_98 GPIO_94 GPIO_36 GPIO_65 GPIO_96 GPIO_58 GPIO_99 GPIO_0 B-PD: nppukp GPIO_98 B-PD: nppukp Wakeup GPIO_94 B-PD: nppukp Wakeup GPIO_36 B-PD: nppukp Wakeup GPIO_65 B-PD: nppukp Wakeup GPIO_96 GPIO_58 B-PD: nppukp Wakeup B-PD: nppukp Wakeup GPIO_99 B-PD: nppukp SC20_Hardware_Design Confidential / Released 3-50 / 122 Smart LTE Module Series SC20 Hardware Design GPIO_95 B-PD: nppukp Wakeup GPIO_11 B-PD: nppukp Wakeup GPIO_10 B-PD: nppukp GPIO_9 GPIO_8 B-PD: nppukp B-PD: nppukp GPIO_16 B-PD: nppukp GPIO_17 B-PD: nppukp GPIO_95 GPIO_11 GPIO_10 GPIO_9 GPIO_8 GPIO_16 GPIO_17 115 116 117 118 119 123 124 NOTE Wakeup: interrupt pins that can wake up the system B: Bidirectional digital with CMOS input H: High-voltage tolerant PD: nppukp = default pull-down with programmable options following the colon (:) 3.14. I2C Interfaces SC20 provides 3 groups of I2C interfaces which only support the master mode. As an open drain output, the I2C interfaces need a pull-up resistor on its external circuit, and the recommended logic level is 1.8V. Table 17: Pin Definition of I2C Interfaces Pin Name Pin No TP_I2C_SCL TP_I2C_SDA CAM_I2C_SCL 47 48 83 CAM_I2C_SDA 84 SENSOR_I2C_ SCL SENSOR_I2C_ SDA 91 92 I/O OD OD OD OD OD OD Description Comment I2C clock signal of touch panel I2C data signal of touch panel I2C clock signal of camera I2C data signal of camera Used for touch panel Used for camera I2C clock signal for external sensor I2C data signal for external sensor Used for external sensor SC20_Hardware_Design Confidential / Released 3-51 / 122 Smart LTE Module Series SC20 Hardware Design 3.15. ADC Interfaces SC20 module provides three analog-to-digital converter (ADC) interfaces, and the pin definition is shown below. Table 18: Pin Definition of ADC Interfaces Pin Name Pin No I/O Description Comment ADC VBAT_SNS 128 133 VBAT_THERM 134 AI AI AI General purpose ADC Max input voltage is 1.7V Input voltage sense Max input voltage is 4.5V Battery temperature detection Internal pull-up; externally connect to GND with a 47K NTC thermistor The resolution of the ADC is up to 16 bits. NOTE When the input voltage exceeds the maximum input voltage of VBAT_SNS pin, resistor divider cannot be used in the circuit design. Instead, general purpose ADC with resistor divider input can be used. 3.16. Motor Drive Interface The pin of motor drive interface is listed below. Table 19: Pin Definition of Motor Drive Interface Pin Name Pin No VIB_DRV 28 I/O PO Description Comment Motor drive Connected to the negative terminal of the motor The motor is driven by an exclusive circuit, and a reference circuit design is shown below. SC20_Hardware_Design Confidential / Released 3-52 / 122 Smart LTE Module Series SC20 Hardware Design Figure 20: Reference Circuit for Motor Connection When the motor stops, the redundant electricity can be discharged from the circuit loop formed by diodes, thus avoiding component damages. 3.17. LCM Interface SC20 module provides an LCM interface meeting MIPI DSI specification. The interface supports high speed differential data transmission, with up to four lanes and a transmission rate up to 1.5Gbps per lane. It supports maximally 720P resolution displays. Table 20: Pin Definition of LCM Interface Pin Name Pin No I/O Description Comment LDO6_1V8 125 PO LDO17_2V85 129 PWM LCD_RST LCD_TE 29 49 50 PO DO DO DI 1.8V output power supply for LCM logic circuit and DSI 2.85V output power supply for LCM analog circuits Adjust the backlight brightness. PWM control signal. 1.8V normal voltage. Vnorm=1.8V IOmax=100mA 2.85V normal voltage. Vnorm=2.85V IOmax=300mA LCD reset signal Active low LCD tearing effect signal SC20_Hardware_Design Confidential / Released 3-53 / 122 Smart LTE Module Series SC20 Hardware Design MIPI_DSI_CLKN MIPI_DSI_CLKP MIPI_DSI_LN0N MIPI_DSI_LN0P MIPI_DSI_LN1N MIPI_DSI_LN1P MIPI_DSI_LN2N MIPI_DSI_LN2P MIPI_DSI_LN3N MIPI_DSI_LN3P 52 53 54 55 56 57 58 59 60 61 AO AO AO AO AO AO AO AO AO AO MIPI DSI clock signal

(negative) MIPI DSI clock signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) MIPI DSI data signal

(negative) MIPI DSI data signal

(positive) Four-lane MIPI DSI is needed for connection with 720P displays. The following is a reference circuit design, by taking the connection with LCM interface on LHR050H41-00 (IC: ILI9881C) from HUARUI Lighting as an example. Figure 21: Reference Circuit Design for LCM Interface SC20_Hardware_Design Confidential / Released 3-54 / 122 Smart LTE Module Series SC20 Hardware Design MIPI are high speed signal lines. It is recommended that common-mode filters should be added in series near the LCM connector, so as to improve protection against electromagnetic radiation interference. ICMEF112P900MFR from ICT is recommended. When compatible design with other displays is required, please connect the LCD_ID pin of LCM to the modules ADC pin, and please note that the output voltage of LCD_ID cannot exceed the voltage range of ADC pin. Backlight driving circuit needs to be designed for LCM, and a reference circuit design is shown in the following figure. Backlight brightness adjustment can be realized by PWM pin of SC20 module through adjusting the duty ratio. Figure 22: Reference Design for Backlight Dirving Circuit 3.18. Touch Panel Interface SC20 provides a set of I2C interface for connection with Touch Panel (TP), and also provides the corresponding power supply and interrupt pins. The definition of TP interface pins is illustrated below. Table 21: Pin Definition of Touch Panel Interface Pin Name Pin No LDO6_1V8 LDO17_2V85 TP_INT TP_RST 125 129 30 31 I/O PO PO DI DO Description Comment 1.8V output power supply for TP I/O power 2.85V output power supply for TP VDD power Pull-up power supply of I2C. 1.8V normal voltage TP power supply. 2.85V normal voltage Interrupt signal of TP Reset signal of TP Active low SC20_Hardware_Design Confidential / Released 3-55 / 122 Smart LTE Module Series SC20 Hardware Design TP_I2C_SCL TP_I2C_SDA 47 48 OD OD I2C clock signal of TP I2C data signal of TP The following illustrates a TP interface reference circuit, by taking the connection with TP interface on LHR050H41-00 (IC: GT9147) from HUARUI Lighting as an example. Figure 23: Reference Circuit Design for TP Interface 3.19. Camera Interfaces Based on standard MIPI CSI video input interface, SC20 module supports two cameras, and the maximum pixel of the rear camera can be up to 8MP. The video and photo quality is determined by various factors such as the camera sensor, camera lens quality, etc. It is recommended to select a proper camera model, according to the specification of cameras verified and recommended by Quectel. The following models of camera sensors have been verified by Quectel:

For rear camera: Hi843 of SK Hynix, T4KA3 of TOSHIBA For front camera: Hi259 of SK Hynix, SP2508 of SuperPix 3.19.1. Rear Camera Interface The rear camera realizes transmission and control via its FPC and a connector which is connected to the module. SC20 rear camera interface integrates a two-lane MIPI CSI for differential data transmission, and it maximally supports 8MP cameras. The pin definition of rear camera interface is shown below. SC20_Hardware_Design Confidential / Released 3-56 / 122 Smart LTE Module Series SC20 Hardware Design Table 22: Pin Definition of Rear Camera Interface Pin Name Pin No I/O Description LDO6_1V8 125 PO LDO17_2V85 129 PO 1.8V output power supply for DOVDD of camera 2.85V output power supply for AVDD of camera Comment 1.8V normal voltage. Vnorm=1.8V IOmax=100mA 2.85V normal voltage. Vnorm=2.85V IOmax=300mA MIPI_CSI0_CLKN 63 MIPI_CSI0_CLKP 64 MIPI_CSI0_LN0N MIPI_CSI0_LN0P MIPI_CSI0_LN1N MIPI_CSI0_LN1P CAM0_MCLK CAM0_RST CAM0_PWD CAM_I2C_SCL CAM_I2C_SDA 65 66 67 68 74 79 80 83 84 AI AI AI AI AI AI DO DO DO OD OD MIPI CSI clock signal

(negative) MIPI CSI clock signal

(positive) MIPI CSI data signal

(negative) MIPI CSI data signal

(positive) MIPI CSI data signal

(negative) MIPI CSI data signal

(positive) Clock signal of rear camera Reset signal of rear camera Power down signal of rear camera I2C clock signal of camera I2C data signal of camera The following is a reference circuit design for rear camera interface, by taking the connection with T4KA3 camera as an example. SC20_Hardware_Design Confidential / Released 3-57 / 122 Smart LTE Module Series SC20 Hardware Design Figure 24: Reference Circuit Design for Rear Camera Interface NOTE DVDD_1V2 is used to power the rear camera core, and VDD_AF_2V8 is used to power the rear camera AF circuit. Both of them are powered by an external LDO. 3.19.2. Front Camera Interface The front camera interface integrates a differential data interface meeting one-lane MIPI CSI standard, and is tested to support 2MP cameras. The pin definition of front camera interface is shown below. Table 23: Pin Definition of Front Camera Interface Pin Name Pin No I/O Description LDO6_1V8 125 PO 1.8V output power supply for DOVDD of camera Comment 1.8V normal voltage. Vnorm=1.8V IOmax=100mA SC20_Hardware_Design Confidential / Released 3-58 / 122 Smart LTE Module Series SC20 Hardware Design 2.85V normal voltage. Vnorm=2.85V IOmax=300mA LDO17_2V85 129 PO 2.85V output power supply for AVDD of camera MIPI_CSI1_CLKN 70 MIPI_CSI1_CLKP 71 MIPI_CSI1_LN0N MIPI_CSI1_LN0P CAM1_MCLK CAM1_RST CAM1_PWD CAM_I2C_SCL CAM_I2C_SDA 72 73 75 81 82 83 84 AI AI AI AI DO DO DO OD OD MIPI CSI clock signal

(negative) MIPI CSI clock signal

(positive) MIPI CSI data signal

(negative) MIPI CSI data signal

(positive) Clock signal of front camera Reset signal of front camera Power down signal of front camera I2C clock signal of camera I2C data signal of camera The following is a reference circuit design for front camera interface, by taking the connection with SP2508 camera as an example. Figure 25: Reference Circuit Design for Front Camera Interface SC20_Hardware_Design Confidential / Released 3-59 / 122 Smart LTE Module Series SC20 Hardware Design 3.19.3. Design Considerations Special attention should be paid to the definition of video device interface in schematic design. Different video devices will have varied definitions for their corresponding connectors. Assure the device and the connectors are correctly connected. MIPI are high speed signal lines, supporting maximum data rate up to 1.5Gbps. The differential impedance should be controlled as 100. Additionally, it is recommended to route the trace on the inner layer of PCB, and do not cross it with other traces. For the same video device, all the MIPI traces should keep the same length. In order to avoid crosstalk, a distance of 1.5 times of the trace width is recommended to be maintained among MIPI signal lines. During impedance matching, do not connect GND on different planes so as to ensure impedance consistency. It is recommended to select a low capacitance TVS for ESD protection and the recommended parasitic capacitance is below 1pF. Route MIPI traces according to the following rules:

a) The total trace length should not exceed 305mm;

b) Control the differential impedance as 10010%;

c) Control intra-lane length difference within 0.67mm;

d) Control inter-lane length difference within 1.3mm. Table 24: MIPI Trace Length Inside the Module PIN Pin Name Length (mm) Length Difference (P-N) 52 53 54 55 56 57 58 59 60 61 63 64 MIPI_DSI_CLKN MIPI_DSI_CLKP MIPI_DSI_LN0N MIPI_DSI_LN0P MIPI_DSI_LN1N MIPI_DSI_LN1P MIPI_DSI_LN2N MIPI_DSI_LN2P MIPI_DSI_LN3N MIPI_DSI_LN3P MIPI_CSI0_CLKN MIPI_CSI0_CLKP 7.08 6.45 6.15 5.85 6.64 6.60 8.20 8.94 9.28 10.24 10.55 11.09

-0.63

-0.30

-0.04 0.74 0.96 0.54 SC20_Hardware_Design Confidential / Released 3-60 / 122 Smart LTE Module Series SC20 Hardware Design 0.40 0.76 0.13 0.35 65 66 67 68 70 71 72 73 MIPI_CSI0_LN0N MIPI_CSI0_LN0P MIPI_CSI0_LN1N MIPI_CSI0_LN1P MIPI_CSI1_CLKN MIPI_CSI1_CLKP MIPI_CSI1_LN0N MIPI_CSI1_LN0P 12.13 12.53 13.73 14.49 17.32 17.45 18.89 19.24 3.20. Sensor Interfaces SC20 module supports communication with sensors via I2C interface, and it supports ALS/PS, Compass, G-sensor, and Gyroscopic sensors. Verified sensor models by Quectel include: BST-BMA223, STK3311-WV, MPU-6881 and MMC35240PJ. Table 25: Pin Definition of Sensor Interfaces Pin Name Pin No SENSOR_I2C_SCL SENSOR_I2C_SDA GPIO_88 GPIO_89 GPIO_94 GPIO_36 GPIO_65 GPIO_96 91 92 99 100 107 108 109 110 I/O OD OD DI DI DI DI DI DI Description Comment I2C clock signal for external sensor I2C data signal for external sensor Gyroscope sensor interrupt signal 2 Gyroscope sensor interrupt signal 1 Proximity sensor interrupt signal Compass sensor interrupt signal Default configuration;

but not limited to these GPIO pins Gravity sensor interrupt signal 2 Gravity sensor interrupt signal 1 SC20_Hardware_Design Confidential / Released 3-61 / 122 Smart LTE Module Series SC20 Hardware Design 3.21. Audio Interfaces SC20 module provides two analog input channels and three analog output channels. The following table shows the pin definition. Table 26: Pin Definition of Audio Interfaces Pin Name Pin No MIC1P MIC_GND MIC2P EARP EARN SPKP SPKN HPH_R HPH_GND HPH_L HS_DET 4 5 6 8 9 10 11 136 137 138 139 I/O AI AI AO AO AO AO AO AI AO AI Description Comment Microphone positive input for channel 1 MIC reference ground Microphone positive input for channel 2 Earpiece positive output Earpiece negative output Speaker positive output Speaker negative output Headphone right channel output Headphone virtual ground Headphone left channel output Headset insertion detection High level by default The module offers two audio input channels which are both single-ended channels. The earpiece interface uses differential output. The loudspeaker interface uses differential output as well. The output channel is available with a Class-D amplifier whose output power is 879mW when VBAT is 4.2V and load is 8. The headphone interface features stereo left and right channel output, and headphone insert detection function is supported. SC20_Hardware_Design Confidential / Released 3-62 / 122 3.21.1. Reference Circuit Design for Microphone Smart LTE Module Series SC20 Hardware Design Figure 26: Reference Circuit Design for Microphone Interface 3.21.2. Reference Circuit Design for Receiver Interface Figure 27: Reference Circuit Design for Receiver Interface SC20_Hardware_Design Confidential / Released 3-63 / 122 3.21.3. Reference Circuit Design for Headphone Interface Smart LTE Module Series SC20 Hardware Design Figure 28: Reference Circuit Design for Headphone Interface 3.21.4. Reference Circuit Design for Loudspeaker Interface Figure 29: Reference Circuit Design for Loudspeaker Interface SC20_Hardware_Design Confidential / Released 3-64 / 122 Smart LTE Module Series SC20 Hardware Design 3.21.5. Audio Interface Design Considerations It is recommended to use the electret microphone with dual built-in capacitors (e.g. 10pF and 33pF) for filtering out RF interference, thus reducing TDD noise. The 33pF capacitor is applied for filtering out RF interference when the module is transmitting at EGSM900MHz. Without placing this capacitor, TDD noise could be heard. Moreover, the 10pF capacitor here is used for filtering out 1800MHz RF interference. Please note that frequency point of a capacitor largely depends on the material and production technique. Therefore, customers would have to discuss with their capacitor vendors to choose the most suitable capacitor for filtering out high-frequency noises. the resonant The severity degree of the RF interference in the voice channel during GSM transmitting largely depends on the application design. In some cases, GSM900 TDD noise is more severe; while in other cases, DCS1800 TDD noise is more obvious. Therefore, a suitable capacitor can be selected based on the test results. Sometimes, even no RF filtering capacitor is required. The capacitor which is used for filtering out RF noise should be close to the audio device or audio interface. The trace should be as short as possible, and it is recommended to route the trace for capacitors first and then for other points. In order to decrease radio or other signal interference, RF antennas should be placed away from audio interfaces and audio traces. Power traces cannot be parallel with and also should be far away from the audio traces. The differential audio traces must be routed according to the differential signal layout rule. 3.22. Emergency Download Interface USB_BOOT is an emergency download interface. Pull up to LDO5_1V8 during power-up will force the module enter into emergency download mode. This is an emergency option when there are failures such as abnormal startup or running. For convenient firmware upgrade and debugging in the future, please reverse this pin. The reference circuit design is shown as below. Figure 30: Reference Circuit Design for Emergency Download Interface SC20_Hardware_Design Confidential / Released 3-65 / 122 Smart LTE Module Series SC20 Hardware Design 4 Wi-Fi and BT SC20 module provides a shared antenna interface ANT_WIFI/BT for Wi-Fi and Bluetooth (BT) functions. The interface impedance is 50. External antennas such as PCB antenna, sucker antenna and ceramic antenna can be connected to the module via the interface, so as to achieve Wi-Fi and BT functions. 4.1. Wi-Fi Overview SC20 series module supports 2.4GHz/5GHz double-band WLAN wireless communication based on IEEE 802.11a/b/g/n standard protocols. The maximum data rate is up to 150Mbps. The features are as below:

Support Wake-on-WLAN (WoWLAN) Support ad hoc mode Support WAPI SMS4 hardware encryption Support AP mode Support Wi-Fi Direct Support MCS 0-7 for HT20 and HT40 4.1.1. Wi-Fi Performance The following table lists the Wi-Fi transmitting and receiving performance of SC20 module. Table 27: Wi-Fi Transmitting Performance Standard 802.11b 802.11b 2.4GHz 802.11g 802.11g 802.11n HT20 Rate 1Mbps 11Mbps 6Mbps 54Mbps MCS0 Output Power 16dBm2.5dB 16dBm2.5dB 16dBm2.5dB 14dBm2.5dB 15dBm2.5dB SC20_Hardware_Design Confidential / Released 4-66 / 122 Smart LTE Module Series SC20 Hardware Design 802.11n HT20 802.11n HT40 802.11n HT40 802.11a 802.11a 802.11n HT20 802.11n HT20 802.11n HT40 802.11n HT40 5GHz Table 28: Wi-Fi Receiving Performance 2.4GHz Standard 802.11b 802.11b 802.11g 802.11g 802.11n HT20 802.11n HT20 802.11n HT40 802.11n HT40 802.11a 802.11a 5GHz 802.11n HT20 802.11n HT20 802.11n HT40 MCS7 MCS0 MCS7 6Mbps 54Mbps MCS0 MCS7 MCS0 MCS7 Rate 1Mbps 11Mbps 6Mbps 54Mbps MCS0 MCS7 MCS0 MCS7 6Mbps 54Mbps MCS0 MCS7 MCS0 13dBm2.5dB 14dBm2.5dB 13dBm2.5dB 15dBm2.5dB 13dBm2.5dB 14dBm2.5dB 12dBm2.5dB 14dBm2.5dB 12dBm2.5dB Sensitivity

-96dBm

-87dBm

-91dBm

-74dBm

-90dBm

-72dBm

-87dBm

-68dBm

-90dBm

-71dBm

-88dBm

-69dBm

-86dBm SC20_Hardware_Design Confidential / Released 4-67 / 122 Smart LTE Module Series SC20 Hardware Design 802.11n HT40 MCS7

-66dBm Referenced specifications are listed below:

IEEE 802.11n WLAN MAC and PHY, October 2009 + IEEE 802.11-2007 WLAN MAC and PHY, June 2007 IEEE Std 802.11b, IEEE Std 802.11d, IEEE Std 802.11e, IEEE Std 802.11g, IEEE Std 802.11i: IEEE 802.11-2007 WLAN MAC and PHY, June 2007 4.2. BT Overview SC20 module supports BT4.1 (BR/EDR+BLE) specification, as well as GFSK, 8-DPSK, /4-DQPSK modulation modes. Maximally support up to 7 wireless connections. Maximally support up to 3.5 piconets at the same time. Support one SCO (Synchronous Connection Oriented) or eSCO connection. The BR/EDR channel bandwidth is 1MHz, and can accommodate 79 channels. The BLE channel bandwidth is 2MHz, and can accommodate 40 channels. Table 29: BT Data Rate and Version Version Data rate Maximum Application Throughput Comment 1.2 1 Mbit/s

>80 Kbit/s 2.0 + EDR 3 Mbit/s

>80 Kbit/s 3.0 + HS 24 Mbit/s Reference 3.0 + HS 4.0 24 Mbit/s Reference 4.0 LE Referenced specifications are listed below:

Bluetooth Radio Frequency TSS and TP Specification 1.2/2.0/2.0 + EDR/2.1/2.1+ EDR/3.0/3.0 + HS, August 6, 2009 Bluetooth Low Energy RF PHY Test Specification, RF-PHY.TS/4.0.0, December 15, 2009 SC20_Hardware_Design Confidential / Released 4-68 / 122 Smart LTE Module Series SC20 Hardware Design 4.2.1. BT Performance The following table lists the BT transmitting and receiving performance of SC20 module. Table 30: BT Transmitting and Receiving Performance Transmitter Performance Packet Types DH5 2-DH5 3-DH5 Transmitting Power 10dBm2.5dB 8dBm2.5dB 8dBm2.5dB Receiver Performance Packet Types DH5 Receiving Sensitivity

-93dBm 2-DH5

-92dBm 3-DH5

-86dBm SC20_Hardware_Design Confidential / Released 4-69 / 122 Smart LTE Module Series SC20 Hardware Design 5 GNSS SC20 module integrates a Qualcomm IZat GNSS engine (GEN 8C) which supports multiple positioning and navigation systems including GPS, GLONASS and BeiDou. With an embedded LNA, the module provides greatly improved positioning accuracy. 5.1. GNSS Performance The following table lists the GNSS performance of SC20 module in conduction mode. Table 31: GNSS Performance Parameter Description Cold start Sensitivity (GNSS) Reacquisition Tracking Cold start TTFF (GNSS) Warm start Hot start Static Drift (GNSS) CEP-50 5.2. GNSS RF Design Guidance Typ.

-146

-158

-160 32 30 2 6 Unit dBm dBm dBm s s s m Bad design of antenna and layout may cause reduced GPS receiving sensitivity, longer GPS positioning time, or reduced positioning accuracy. In order to avoid this, please follow the reference design rules as below:

SC20_Hardware_Design Confidential / Released 5-70 / 122 Smart LTE Module Series SC20 Hardware Design Maximize the distance between the GNSS RF part and the GPRS RF part (including trace routing and antenna layout) to avoid mutual interference. In user systems, GNSS RF signal lines and RF components should be placed far away from high the clock circuit of single-chip speed circuits, switched-mode power supplies, power inductors, microcomputers, etc. For applications with harsh electromagnetic environment or with high requirement on ESD protection, it is recommended to add ESD protective diodes for the antenna interface. Only diodes with ultra-low junction capacitance such as 0.05pF can be selected. Otherwise, there will be effects on the impedance characteristic of RF circuit loop, or attenuation of bypass RF signal may be caused. Control the impedance of either feeder line or PCB trace as 50, and keep the trace length as short as possible. Refer to Chapter 6.3 for GNSS reference circuit design. SC20_Hardware_Design Confidential / Released 5-71 / 122 Smart LTE Module Series SC20 Hardware Design 6 Antenna Interface SC20 antenna interface includes a main antenna, an Rx-diversity/MIMO antenna, a GNSS antenna and a Wi-Fi/BT antenna. The antenna interface has an impedance of 50. 6.1. Main/Rx-diversity Antenna Interfaces The pin definition of main/Rx-diversity antenna interfaces is shown below. Table 32: Pin Definition of Main/Rx-diversity Antenna Interfaces Pin Name Pin No. ANT_MAIN ANT_DRX 87 131 I/O IO AI Description Main antenna Comment 50 impedance Diversity antenna 50 impedance 6.1.1. Operating Frequency Table 33: SC20 Module Operating Frequencies 3GPP Band GSM850 EGSM900 DCS1800 PCS1900 WCDMA Band1 WCDMA Band2 WCDMA Band4 Receive 869~894 925~960 1805~1880 1930~1990 2110~2170 1930~1990 2110~2155 Transmit 824~849 880~915 1710~1785 1850~1910 1920~1980 1850~1910 1710~1755 Unit MHz MHz MHz MHz MHz MHz MHz SC20_Hardware_Design Confidential / Released 6-72 / 122 WCDMA Band5 WCDMA Band6 WCDMA Band8 WCDAM Band19 CDMA BC0 869~894 875~885 925~960 875~890 869~894 TD-SCDMA Band34 2010~2025 TD-SCDMA Band39 1880~1920 LTE-FDD Band1 LTE-FDD Band2 LTE-FDD Band3 LTE-FDD Band4 LTE-FDD Band5 LTE-FDD Band7 LTE-FDD Band8 LTE-FDD Band12 LTE-FDD Band13 LTE-FDD Band18 LTE-FDD Band19 LTE-FDD Band20 2110~2170 1930~1990 1805~1880 2110~2155 869~894 2620~2690 925~960 729~746 746~756 860~875 875~890 791~821 LTE-FDD Band25 1930~1995 LTE-FDD Band26 LTE-FDD Band28 LTE-TDD Band38 LTE-TDD Band39 LTE-TDD Band40 859~894 758~803 2570~2620 1880~1920 2300~2400 Smart LTE Module Series SC20 Hardware Design 824~849 830~840 880~915 830~845 824~849 2010~2025 1880~1920 1920~1980 1850~1910 1710~1785 1710~1755 824~849 2500~2570 880~915 699~716 777~787 815~830 830~845 832~862 1850~1915 814~849 703~748 2570~2620 1880~1920 2300~2400 MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz MHz SC20_Hardware_Design Confidential / Released 6-73 / 122 Smart LTE Module Series SC20 Hardware Design LTE-TDD Band41 2555~2655 2555~2655 MHz NOTE The bandwidth of LTE-TDD Band 41 for SC20-J is 2545MHz~2655MHz, and the corresponding channel range is 40140~41240. 6.1.2. Reference Design of Main and Rx-diversity Antenna Interfaces A reference circuit design for main and Rx-diversity antenna interfaces is shown as below. A -type matching circuit should be reserved for better RF performance. The -type matching components

(R1/C1/C2, R2/C3/C4) should be placed as close to the antennas as possible and are mounted according to the actual debugging. C1, C2, C3 and C4 are not mounted and a 0 resistor is mounted on R1 and R2 respectively by default. Figure 31: Reference Circuit Design for Main and Rx-diversity Antenna Interfaces 6.1.3. Reference Design of RF Layout For users PCB, the characteristic impedance of all RF traces should be controlled as 50. The impedance of the RF traces is usually determined by the trace width (W), the materials dielectric constant, the distance between signal layer and reference ground (H), and the clearance between RF trace and ground (S). Microstrip line or coplanar waveguide line is typically used in RF layout for characteristic impedance control. The following are reference designs of microstrip line or coplanar waveguide line with different PCB structures. SC20_Hardware_Design Confidential / Released 6-74 / 122 Smart LTE Module Series SC20 Hardware Design Figure 32: Microstrip Line Design on a 2-layer PCB Figure 33: Coplanar Waveguide Line Design on a 2-layer PCB Figure 34: Coplanar Waveguide Line Design on a 4-layer PCB (Layer 3 as Reference Ground) SC20_Hardware_Design Confidential / Released 6-75 / 122 Smart LTE Module Series SC20 Hardware Design Figure 35: Coplanar Waveguide Line Design on a 4-layer PCB (Layer 4 as Reference Ground) In order to ensure RF performance and reliability, the following principles should be complied with in RF layout design:

Use impedance simulation tool to control the characteristic impedance of RF traces as 50. The GND pins adjacent to RF pins should not be designed as thermal relief pads, and should be fully connected to ground. The distance between the RF pins and the RF connector should be as short as possible, and all the right angle traces should be changed to curved ones. There should be clearance area under the signal pin of the antenna connector or solder joint. The reference ground of RF traces should be complete. Meanwhile, adding some ground vias around RF traces and the reference ground could help to improve RF performance. The distance between the ground vias and RF traces should be no less than two times the width of RF signal traces (2*W). For more details about RF layout, please refer to document [4]. 6.2. Wi-Fi/BT Antenna Interface The following tables show the pin definition and frequency specification of the Wi-Fi/BT antenna interface. Table 34: Pin Definition of Wi-Fi/BT Antenna Interface Pin Name Pin No. ANT_WIFI/BT 77 I/O IO Description Comment Wi-Fi/BT antenna interface 50 impedance SC20_Hardware_Design Confidential / Released 6-76 / 122 Smart LTE Module Series SC20 Hardware Design Table 35: Wi-Fi/BT Frequency Type 802.11a/b/g/n BT4.1 LE NOTE Frequency 2400~2482 5180~5825 2402~2480 Unit MHz MHz The supported Wi-Fi frequencies of SC20-J are 2400MHz~2496MHz and 5180MHz~5825MHz. A reference circuit design for Wi-Fi/BT antenna interface is shown as below. A -type matching circuit should be reserved for better RF performance. The -type matching components (R1, C1, C2) should be placed as close to the antenna as possible and are mounted according to the actual debugging. C1 and C2 are not mounted and a 0 resistor is mounted on R1 by default. Figure 36: Reference Circuit Design for Wi-Fi/BT Antenna 6.3. GNSS Antenna Interface The following tables show pin definition and frequency specification of GNSS antenna interface. Table 36: Pin Definition of GNSS Antenna Interface Pin Name Pin No. ANT_GNSS 121 I/O AI Description Comment GNSS antenna interface 50 impedance SC20_Hardware_Design Confidential / Released 6-77 / 122 Smart LTE Module Series SC20 Hardware Design Table 37: GNSS Frequency Type GPS GLONASS BeiDou Frequency 1575.421.023 1597.5~1605.8 1561.0982.046 Unit MHz MHz MHz 6.3.1. Recommended Circuit for Passive Antenna GNSS antenna interface supports passive ceramic antennas and other types of passive antennas. When the passive antenna is placed far away from the module (that is, the antenna trace is long), it is recommended to add an external LNA circuit for better GNSS receiving performance, and the LNA should be placed close to the antenna. A reference circuit design is given below. Figure 37: Reference Circuit Design for GNSS Passive Antenna 6.3.2. Recommended Circuit for Active Antenna The active antenna is powered by VCC power supply through the R1 and L1 power paths shown in the following figure. The common power supply voltage ranges from 3.3V to 5.0V. Although featuring low power consumption, the active antenna still requires stable and clean power supplies. It is recommended to use high performance LDO as the power supply. A reference design of GNSS active antenna is shown below. SC20_Hardware_Design Confidential / Released 6-78 / 122 Smart LTE Module Series SC20 Hardware Design Figure 38: Reference Circuit Design for GNSS Active Antenna 6.4. Antenna Installation 6.4.1. Antenna Requirement The following table shows the requirement on main antenna, RX-diversity antenna, Wi-Fi/BT antenna and GNSS antenna. Table 38: Antenna Requirements Type Requirements VSWR: 2 Gain (dBi): 1 Max Input Power (W): 50 Input Impedance (): 50 Polarization Type: Vertical Cable Insertion Loss: < 1dB

(GSM850, EGSM900, WCDMA B5/B6/B8/B19, CDMA BC0, LTE-FDD B5/B8/B12/B13/B18/B19/B20/B26/B28) Cable Insertion Loss: < 1.5dB

(DCS1800, PCS1900, WCDMA B1/B2/B4, TD-SCDMA B34/B39, LTE-FDD B1/B2/B3/B4/B25, LTE-TDD B39) Cable Insertion Loss: < 2dB

(LTE-FDD B7, LTE-TDD B38/B40/B41) VSWR: 2 Gain (dBi): 1 Max Input Power (W): 50 Input Impedance (): 50 GSM/WCDMA/TD-SCDMA/

LTE Wi-Fi/BT SC20_Hardware_Design Confidential / Released 6-79 / 122 Smart LTE Module Series SC20 Hardware Design GNSS Polarization Type: Vertical Cable Insertion Loss: < 1dB Frequency range: 1565MHz~1607MHz Polarization: RHCP or linear VSWR: < 2 (Typ.) Passive Antenna Gain: > 0dBi Active Antenna Noise Figure: < 1.5dB Active Antenna Total Gain: > 18dBi (Typ.) 6.4.2. Recommended RF Connector for Antenna Installation If RF connector is used for antenna connection, it is recommended to use the U.FL-R-SMT connector provided by HIROSE. Figure 39: Dimensions of the U.FL-R-SMT Connector (Unit: mm) SC20_Hardware_Design Confidential / Released 6-80 / 122 U.FL-LP serial connectors listed in the following figure can be used to match the U.FL-R-SMT. Smart LTE Module Series SC20 Hardware Design Figure 40: Mechanicals of U.FL-LP Connectors The following figure describes the space factor of mated connector. Figure 41: Space Factor of Mated Connectors (Unit: mm) For more details, please visit http://www.hirose.com. SC20_Hardware_Design Confidential / Released 6-81 / 122 Smart LTE Module Series SC20 Hardware Design 7 Electrical, Reliability and Radio Characteristics 7.1. Absolute Maximum Ratings Absolute maximum ratings for power supply and voltage on digital and analog pins of the module are listed in the following table. Table 39: Absolute Maximum Ratings Parameter VBAT USB_VBUS Peak Current of VBAT Voltage on Digital Pins Min.

-0.5

-0.5 0

-0.3 Max. 6 16 3 2.3 Unit V V A V 7.2. Power Supply Ratings Table 40: SC20 Module Power Supply Ratings Parameter Description Conditions Min. Typ. Max. Unit VBAT VBAT Voltage drop during transmitting burst The actual input voltages must stay between the minimum and maximum values. Maximum power control level at EGSM900. 3.5 3.8 4.2 V 400 mV SC20_Hardware_Design Confidential / Released 7-82 / 122 Smart LTE Module Series SC20 Hardware Design IVBAT Peak supply current (during transmission slot) Maximum power control level at EGSM900. 1.8 USB_VBUS USB detection 4.35 5.0 3.0 6.3 VRTC Power supply voltage of backup battery. 2.0 3.0 3.25 A V V 7.3. Charging Performance Specifications Table 41: Charging Performance Specifications Parameter Trickle charging-A current Min. Typ. Max. 81 90 99 Trickle charging-A threshold voltage range (15.62mV steps) 2.5 2.796 2.984 Trickle charging-B threshold voltage range (18.75mV steps) 3.0 4 90 Charge voltage range (25mV steps) Charge voltage accuracy Charge current range (90mA steps) Charge current accuracy Charge termination current:

when charge current is from 90mA to 450mA Charge termination current:

when charge current is from 450mA to 1440mA 3.581 4.775

+/-2 1440

+/-10 3.2 4.2 7 7.4 Unit mA V V V

%

mA

%

%

%

SC20_Hardware_Design Confidential / Released 7-83 / 122 Smart LTE Module Series SC20 Hardware Design 7.4. Operating Temperature The operating temperature is listed in the following table. Table 42: Operating Temperature Parameter Operating temperature range 1) Extended temperature range 2) Min.

-35

-40 NOTES Typ.

+25 Max.

+65

+75 Unit C C 1. 2. 1) Within operation temperature range, the module is 3GPP compliant. 2) Within extended temperature range, the module remains the ability to establish and maintain a voice, SMS, data transmission, emergency call, etc. There is no unrecoverable malfunction. There are also no effects on radio spectrum and no harm to radio network. Only one or more parameters like Pout might reduce in their value and exceed the specified tolerances. When the temperature returns to the normal operating temperature levels, the module will meet 3GPP specifications again. 7.5. Current Consumption The values of current consumption are shown below. Table 43: SC20-CE R1.1 Current Consumption Parameter Description OFF state Conditions Power down IVBAT GSM/GPRS supply current WCDMA supply current Sleep (USB disconnected)

@DRX=2 Sleep (USB disconnected)

@DRX=5 Sleep (USB disconnected)

@DRX=9 Sleep (USB disconnected)

@DRX=6 Typ. 20 3.85 3.01 2.91 3.30 Unit uA mA mA mA mA SC20_Hardware_Design Confidential / Released 7-84 / 122 Smart LTE Module Series SC20 Hardware Design Sleep (USB disconnected)

@DRX=7 Sleep (USB disconnected)

@DRX=8 Sleep (USB disconnected)

@DRX=9 Sleep (USB disconnected)

@DRX=5 Sleep (USB disconnected)

@DRX=6 Sleep (USB disconnected)

@DRX=7 Sleep (USB disconnected)

@DRX=8 Sleep (USB disconnected)

@DRX=5 Sleep (USB disconnected)

@DRX=6 Sleep (USB disconnected)

@DRX=7 Sleep (USB disconnected)

@DRX=8 GSM900 PCL=5 @31.84dBm GSM900 PCL=12 @18.49dBm GSM900 PCL=19 @4.95dBm DCS1800 PCL=0 @28.91dBm DCS1800 PCL=7 @15.35dBm DCS1800 PCL=15 @-0.21dBm BC0 (max power)

@23.91dBm BC0 (min power)

@-60.28dBm Band1 (max power)

@22.61dBm 2.79 2.49 2.33 5.60 3.83 3.02 2.65 5.49 3.87 3.05 2.67 TBD TBD TBD TBD TBD TBD TBD TBD TBD mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA LTE-FDD supply current LTE-TDD supply current GSM voice call CDMA voice call WCDMA voice call SC20_Hardware_Design Confidential / Released 7-85 / 122 Smart LTE Module Series SC20 Hardware Design Band8 (max power)

@22.74dBm EDGE900 (1UL/4DL)

@26.29dBm EDGE900 (2UL/3DL)

@26.15dBm EDGE900 (3UL/2DL)

@26.06dBm EDGE900 (4UL/1DL)

@25.92dBm DCS1800 (1UL/4DL)

@24.89dBm DCS1800 (2UL/3DL)

@24.74dBm DCS1800 (3UL/2DL)

@24.54dBm DCS1800 (4UL/1DL)

@24.44dBm BC0 (max power)

@23.68dBm Band 1 (HSDPA)

@21.64dBm Band 8 (HSDPA)

@21.61dBm Band 1 (HSUPA)

@21.36dBm Band 8 (HSUPA)

@21.56dBm LTE-FDD Band1

@22.96dBm LTE-FDD Band3

@22.95dBm LTE-FDD Band5

@22.90dBm LTE-FDD Band8

@23.17dBm LTE-TDD Band38

@22.02dBm LTE-TDD Band39

@22.13dBm LTE-TDD Band40 TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA EDGE data transfer CDMA data transfer WCDMA data transfer LTE data transfer SC20_Hardware_Design Confidential / Released 7-86 / 122 Smart LTE Module Series SC20 Hardware Design

@22.01dBm LTE-TDD Band41

@22.31dBm TBD mA Table 44: SC20-E Current Consumption Parameter Description OFF state Conditions Power down GSM/GPRS supply current WCDMA supply current IVBAT LTE-FDD supply current LTE-TDD supply current GSM voice call Sleep (USB disconnected)

@DRX=2 Sleep (USB disconnected)

@DRX=5 Sleep (USB disconnected)

@DRX=9 Sleep (USB disconnected)

@DRX=6 Sleep (USB disconnected)

@DRX=7 Sleep (USB disconnected)

@DRX=8 Sleep (USB disconnected)

@DRX=9 Sleep (USB disconnected)

@DRX=5 Sleep (USB disconnected)

@DRX=6 Sleep (USB disconnected)

@DRX=7 Sleep (USB disconnected)

@DRX=8 Sleep (USB disconnected)

@DRX=5 Sleep (USB disconnected)

@DRX=6 Sleep (USB disconnected)

@DRX=7 Sleep (USB disconnected)

@DRX=8 GSM850 PCL=5 @33.13dBm Typ. 20 3.58 2.46 2.13 2.99 2.35 2.01 1.85 5.51 3.56 2.62 2.14 5.93 3.74 2.70 2.17 263.8 Unit uA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA SC20_Hardware_Design Confidential / Released 7-87 / 122 Smart LTE Module Series SC20 Hardware Design GSM850 PCL=12 @19.15dBm GSM850 PCL=19 @5.31dBm EGSM900 PCL=5 @33.07dBm EGSM900 PCL=12 @19.53dBm EGSM900 PCL=19 @5.59dBm DCS1800 PCL=0 @30.00dBm DCS1800 PCL=7 @16.45dBm DCS1800 PCL=15 @0.67dBm PCS1900 PCL=0 @29.72dBm PCS1900 PCL=7 @16.72dBm PCS1900 PCL=15 @0.98dBm Band 1 (max power)

@23.18dBm Band 5 (max power)

@23.22dBm Band 8 (max power)

@23.29dBm GPRS850 (1UL/4DL)

@33.12dBm GPRS850 (2UL/3DL)

@33.02dBm GPRS850 (3UL/2DL)

@30.50dBm GPRS850 (4UL/1DL)

@29.49dBM GPRS900 (1UL/4DL)

@33.10dBm GPRS900 (2UL/3DL)

@33.00dBm GPRS900 (3UL/2DL)

@30.96dBm 134.7 109.2 271.2 137.3 110.6 203.0 150.7 130.8 195.9 151.3 130.0 544.1 513.5 522.7 265.9 435.1 478.8 564.0 272.7 445.0 512.0 mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA WCDMA voice call GPRS data transfer SC20_Hardware_Design Confidential / Released 7-88 / 122 Smart LTE Module Series SC20 Hardware Design GPRS900 (4UL/1DL)

@29.93dBm DCS1800 (1UL/4DL)

@29.96dBm DCS1800 (2UL/3DL)

@29.86dBm DCS1800 (3UL/2DL)

@29.73dBm DCS1800 (4UL/1DL)

@29.63dBm PCS1900 (1UL/4DL)

@29.77dBm PCS1900 (2UL/3DL)

@29.64dBm PCS1900 (3UL/2DL)

@29.54dBm PCS1900 (4UL/1DL)

@29.34dBm EDGE850 (1UL/4DL)

@26.75dBm EDGE850 (2UL/3DL)

@27.13dBm EDGE850 (3UL/2DL)

@26.63dBm EDGE850 (4UL/1DL)

@26.54dBm EDGE900 (1UL/4DL)

@27.05dBm EDGE900 (2UL/3DL)

@27.13dBm EDGE900 (3UL/2DL)

@27.28dBm EDGE900 (4UL/1DL)

@27.19dBm DCS1800 (1UL/4DL)

@26.04dBm DCS1800 (2UL/3DL)

@25.98dBm DCS1800 (3UL/2DL)

@25.71dBm DCS1800 (4UL/1DL)

@25.46dBm 599.2 205.8 314.3 420.8 531.7 199.3 307.2 411.5 518.7 172.2 266.6 353.1 446.9 182 177.4 278.3 371.0 170.6 260.5 349.8 440.2 mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA EDGE data transfer SC20_Hardware_Design Confidential / Released 7-89 / 122 Smart LTE Module Series SC20 Hardware Design PCS1900 (1UL/4DL)

@26.14dBm PCS1900 (2UL/3DL)

@26.11dBm PCS1900 (3UL/2DL)

@26.11dBm PCS1900 (4UL/1DL)

@25.70dBm Band 1 (HSDPA)

@22.43dBm Band 5 (HSDPA)

@22.23dBm Band 8 (HSDPA)

@22.24dBm Band 1 (HSUPA)

@22.30dBm Band 5 (HSUPA)

@21.93dBm Band 8 (HSUPA)

@21.90dBm LTE-FDD Band1

@23.29dBm LTE-FDD Band3

@23.29dBm LTE-FDD Band5

@23.44dBm LTE-FDD Band7

@23.28dBm LTE-FDD Band8

@23.44dBm LTE-FDD Band20

@23.36dBm LTE-TDD Band38

@23.19dBm LTE-TDD Band40

@23.17dBm LTE-TDD Band41

@23.19dBm 171.0 260.5 349.6 442.3 503.8 471.6 481.6 504.6 460.5 464.8 737 756 636 842 639 684 427 427 455 mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA WCDMA data transfer LTE data transfer SC20_Hardware_Design Confidential / Released 7-90 / 122 Table 45: SC20-A Current Consumption Parameter Description OFF state Conditions Power down GSM/GPRS supply current WCDMA supply current IVBAT FDD-LTE supply current GSM voice call WCDMA voice call Sleep USB disconnected)

@DRX=2 Sleep (USB disconnected) DRX=5 Sleep (USB disconnected) DRX=9 Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) DRX=8 Sleep (USB disconnected) DRX=9 Sleep (USB disconnected) DRX=5 Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) DRX=8 GSM850 PCL=5 @32.23dBm GSM850 PCL=12 @18.34dBm GSM850 PCL=19 @4.87dBm PCS1900 PC=L0 @29.14dBm PCS1900 PCL=7 @16.23dBm PCS1900 PCL=15 @0.62dBm Band 1 (max power)

@23.24dBm Band 2 (max power) Smart LTE Module Series SC20 Hardware Design Typ. 20 4.08 3.10 2.77 3.86 2.90 2.55 2.43 6.60 4.24 3.11 2.77 254.60 136.30 111.30 196.60 158.40 135.50 548.13 575.70 Unit uA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA SC20_Hardware_Design Confidential / Released 7-91 / 122 Smart LTE Module Series SC20 Hardware Design

@23.40dBm Band 4 (max power)

@23.20dBm Band 5 (max power)

@23.47dBm Band 8 (max power)

@23.5dBm GPRS850 (1UL/4DL)

@32.18dBm GPRS850 (2UL/3DL)

@32.00dBm GPRS850 (3UL/2DL)

@30.43dBm GPRS850 (4UL/1DL)

@29.37dBm PCS1900 (1UL/4DL)

@29.13dBm PCS1900 (2UL/3DL)

@29.19dBm PCS1900 (3UL/2DL)

@29.05dBm PCS1900 (4UL/1DL)

@28.84dBm EDGE850 (1UL/4DL)

@26.39dBm EDGE850 (2UL/3DL)

@26.30dBm EDGE850 (3UL/2DL)

@26.30dBm EDGE850 (4UL/1DL)

@26.07dBm PCS1900 (1UL/4DL)

@25.70dBm PCS1900 (2UL/3DL)

@25.55dBm PCS1900 (3UL/2DL)

@25.39dBm PCS1900 (4UL/1DL)

@25.17dBm Band 1 (HSDPA)

@22.24dBm 561.35 558.00 557.10 254.50 410.70 496.10 573.90 198.70 306.50 408.90 514.60 186.00 280.00 368.00 456.00 184.40 276.60 365.20 456.50 506.35 mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA GPRS data transfer EDGE data transfer WCDMA data transfer SC20_Hardware_Design Confidential / Released 7-92 / 122 Band 2 (HSDPA)

@22.44dBm Band 4 (HSDPA)

@22.23dBm Band 5 (HSDPA)

@22.38dBm Band 8 (HSDPA)

@22.47dBm Band 1 (HSUPA)

@22.2dBm Band2 (HSUPA)

@22.4dBm Band 4 (HSUPA)

@21.93dBm Band 5 (HSUPA)

@22.26dBm Band 8 (HSUPA)

@22 dBm LTE-FDD Band2

@23.05dBm LTE-FDD Band4

@23.3dBm LTE-FDD Band5

@23.13dBm LTE-FDD Band7

@22.75dBm LTE-FDD Band12

@22.74dBm LTE-FDD Band13

@23.3dBm LTE-FDD Band25

@23.2dBm LTE-FDD Band26

@23.57dBm LTE data transfer Table 46: SC20-AU Current Consumption Parameter Description IVBAT OFF state Conditions Power down GSM/GPRS supply Sleep (USB disconnected) Smart LTE Module Series SC20 Hardware Design 535.10 523.07 513.13 512.30 516.00 545.60 527.93 528.94 507.70 710.01 736.50 626.18 733.40 606.02 674.84 665.62 718.75 Typ. 20 TBD mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA Unit uA mA SC20_Hardware_Design Confidential / Released 7-93 / 122 Smart LTE Module Series SC20 Hardware Design current DRX=2 WCDMA supply current LTE-FDD supply current LTE-TDD supply current GSM voice call Sleep (USB disconnected) DRX=5 Sleep (USB disconnected) DRX=9 Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) DRX=8 Sleep (USB disconnected) DRX=9 Sleep (USB disconnected) DRX=5 Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) DRX=8 Sleep (USB disconnected) DRX=5 Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) DRX=8 GSM850 PCL=5 @32.96dBm GSM850 PCL=12 @18.83dBm GSM850 PCL=19 @5.31dBm GSM900 PCL=5 @32.96dBm GSM900 PCL=12 @19.21dBm GSM900 PCL=19 @5.60dBm TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD 268 133 109 267 137 108 mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA SC20_Hardware_Design Confidential / Released 7-94 / 122 Smart LTE Module Series SC20 Hardware Design 202 152 131 194 149 130 561 521 551 478 267 TBD 503 574 266 TBD 509 583 205 316 TBD mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA PCS1800 PC=L0 @29.93dBm PCS1800 PCL=7 @16.29dBm PCS1800 PCL=15 @0.62dBm PCS1900 PC=L0 @29.67dBm PCS1900 PCL=7 @16.74dBm PCS1900 PCL=15 @1.09dBm Band 1 (max power)

@23.33dBm Band 2 (max power)

@23.51dBm Band 5 (max power)

@23.37dBm Band 8 (max power)

@23.38dBm GPRS850 (1UL/4DL)

@32.91dBm GPRS850 (2UL/3DL)

@32.73dBm GPRS850 (3UL/2DL)

@30.72dBm GPRS850 (4UL/1DL)

@29.38dBm GSM900 (1UL/4DL)

@32.92dBm GSM900 (2UL/3DL)

@32.74dBm GSM900 (3UL/2DL)

@30.85dBm GSM900 (4UL/1DL)

@29.58dBm DCS1800 (1UL/4DL)

@39.81dBm DCS1800 (2UL/3DL)

@39.70dBm DCS1800 (3UL/2DL)

@29.50dBm WCDMA voice call GPRS data transfer SC20_Hardware_Design Confidential / Released 7-95 / 122 Smart LTE Module Series SC20 Hardware Design 530 TBD TBD TBD TBD TBD 300 389 457 178 276 394 490 197 287 373 461 168 257 345 436 mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA DCS1800 (4UL/1DL)

@29.34dBm PCS1900 (1UL/4DL)

@29.58dBm PCS1900 (2UL/3DL)

@29.48dBm PCS1900 (3UL/2DL)

@29.31dBm PCS1900 (4UL/1DL)

@29.40dBm EDGE850 (1UL/4DL)

@26.70dBm EDGE850 (2UL/3DL)

@27.02dBm EDGE850 (3UL/2DL)

@26.60dBm EDGE850 (4UL/1DL)

@26.33dBm GSM900 (1UL/4DL)

@26.87dBm GSM900 (2UL/3DL)

@27.27dBm GSM900 (3UL/2DL)

@26.85dBm GSM900 (4UL/1DL)

@26.53dBm DCS1800 (1UL/4DL)

@25.39dBm DCS1800 (2UL/3DL)

@25.40dBm DCS1800 (3UL/2DL)

@25.35dBm DCS1800 (4UL/1DL)

@25.05dBm PCS1900 (1UL/4DL)

@26.03dBm PCS1900 (2UL/3DL)

@26.07dBm PCS1900 (3UL/2DL)

@25.81dBm PCS1900 (4UL/1DL)

@25.70dBm EDGE data transfer SC20_Hardware_Design Confidential / Released 7-96 / 122 WCDMA data transfer LTE data transfer Band 1 (HSDPA)

@23.02dBm Band 2 (HSDPA)

@23.11dBm Band 5 (HSDPA)

@22.68dBm Band 8 (HSDPA)

@22.72dBm Band 1 (HSUPA)

@22.39dBm Band2 (HSUPA)

@23.19dBm Band 5 (HSUPA)

@22.44dBm Band 8 (HSUPA)

@22.25dBm LTE-FDD Band1

@23.37dBm LTE-FDD Band3

@23.06dBm LTE-FDD Band5

@23.25dBm LTE-FDD Band7

@22.82dBm LTE-FDD Band8

@23.47dBm LTE-FDD Band28

@23.13dBm LTE-TDD Band40

@23.24dBm Table 47: SC20-J Current Consumption Parameter Description OFF state Conditions Power down IVBAT WCDMA supply current Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) Smart LTE Module Series SC20 Hardware Design 517 550 486 466 521 509 503 474 698 709 643 802 620 756 388 Typ. 20 TBD TBD TBD mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA Unit uA mA mA mA SC20_Hardware_Design Confidential / Released 7-97 / 122 Smart LTE Module Series SC20 Hardware Design LTE-FDD supply current LTE-TDD supply current WCDMA voice call WCDMA data transfer DRX=8 Sleep (USB disconnected) DRX=9 Sleep (USB disconnected) DRX=5 Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) DRX=8 Sleep (USB disconnected) DRX=5 Sleep (USB disconnected) DRX=6 Sleep (USB disconnected) DRX=7 Sleep (USB disconnected) DRX=8 Band 1 (max power)

@22.97dBm Band 6 (max power)

@22.99dBm Band 8 (max power)

@23.20dBm Band 19 (max power)

@22.99dBm Band 1 (HSDPA)

@22.13dBm Band 6 (HSDPA)

@22.28dBm Band 8 (HSDPA)

@22.17dBm Band 19 (HSDPA)

@22.31dBm Band 1 (HSUPA)

@21.4dBm Band 6 (HSUPA)

@22.11dBm Band 8 (HSUPA)

@21.57dBm TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD 482 TBD 471 500 494 TBD 472 mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA mA SC20_Hardware_Design Confidential / Released 7-98 / 122 Smart LTE Module Series SC20 Hardware Design TBD TBD TBD 637 TBD TBD TBD 451 mA mA mA mA mA mA mA mA Band 19 (HSUPA)

@22.10dBm LTE-FDD Band1

@23.64dBm LTE-FDD Band3

@23.52dBm LTE-FDD Band8

@23.40dBm LTE-FDD Band18

@23.45dBm LTE-FDD Band19

@23.42dBm LTE-FDD Band26

@23.36dBm LTE-TDD Band41

@23.23dBm LTE data transfer 7.6. RF Output Power The following table shows the RF output power of SC20 module. Table 48: RF Output Power Frequency GSM850 EGSM900 DCS1800 PCS1900 WCDMA Band1 WCDMA Band2 WCDMA Band4 WCDMA Band5 WCDMA Band6 Max. 33dBm2dB 33dBm2dB 30dBm2dB 30dBm2dB 24dBm+1/-3dB 24dBm+1/-3dB 24dBm+1/-3dB 24dBm+1/-3dB 24dBm+1/-3dB Min. 5dBm5dB 5dBm5dB 0dBm5dB 0dBm5dB

<-49dBm

<-49dBm

<-49dBm

<-49dBm

<-49dBm SC20_Hardware_Design Confidential / Released 7-99 / 122 Smart LTE Module Series SC20 Hardware Design WCDMA Band8 WCDMA Band19 CDMA BC0 TD-SCDMA Band34 TD-SCDMA Band39 LTE-FDD B1 LTE-FDD B2 LTE-FDD B3 LTE-FDD B4 LTE-FDD B5 LTE-FDD B7 LTE-FDD B8 LTE-FDD B12 LTE-FDD B13 LTE-FDD B18 LTE-FDD B19 LTE-FDD B20 LTE-FDD B25 LTE-FDD B26 LTE-FDD B28 LTE-TDD B38 LTE-TDD B39 LTE-TDD B40 LTE-TDD B41 24dBm+1/-3dB 24dBm+1/-3dB 24dBm+3/-1dB 24dBm+1/-3dB 24dBm+1/-3dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB 23dBm2dB

<-49dBm

<-49dBm

<-49dBm

<-49dBm

<-49dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm

<-39dBm SC20_Hardware_Design Confidential / Released 7-100 / 122 Smart LTE Module Series SC20 Hardware Design NOTE In GPRS 4 slots TX mode, the maximum output power is reduced by 3dB. This design conforms to the GSM specification as described in Chapter 13.16 of 3GPP TS 51.010-1. 7.7. RF Receiving Sensitivity The following table shows the RF receiving sensitivity of SC20 module. Table 49: SC20-CE R1.1 RF Receiving Sensitivity Frequency EGSM900 DCS1800 WCDMA Band1 WCDMA Band8 CDMA BC0 TD-SCDMA Band 34 TD-SCDMA Band 39 LTE-FDD B1 (10M) LTE-FDD B3 (10M) LTE-FDD B5 (10M) LTE-FDD B8 (10M) LTE-FDD B38 (10M) LTE-FDD B39 (10M) LTE-FDD B40 (10M) LTE-FDD B41 (10M) Primary Diversity SIMO 3GPP(SIMO) Receive Sensitivity (Typ.) TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD TBD NA NA NA NA NA NA NA TBD TBD TBD TBD TBD TBD TBD TBD NA NA NA NA NA NA NA TBD TBD TBD TBD TBD TBD TBD TBD

-102dBm

-102dBm

-106.7dBm

-103.7dBm

-104dBm

-108dBm

-108dBm

-96.3dBm

-93.3dBm

-94.3dBm

-93.3dBm

-96.3dBm

-96.3dBm

-96.3dBm

-94.3dBm SC20_Hardware_Design Confidential / Released 7-101 / 122 Smart LTE Module Series SC20 Hardware Design Table 50: SC20-E RF Receiving Sensitivity Frequency

-109dBm GSM850 NA EGSM900 DCS1800 PCS1900 WCDMA Band1 WCDMA Band5 WCDMA Band8 LTE-FDD B1 (10M) LTE-FDD B3 (10M) LTE-FDD B5 (10M) LTE-FDD B7 (10M) LTE-FDD B8 (10M) LTE-FDD B20 (10M) LTE-TDD B38 (10M) LTE-TDD B40 (10M) LTE-TDD B41 (10M) Primary

-109dBm

-109dBm

-109dBm

-109dBm

-110dBm

-110dBm

-110dBm

-98dBm

-97dBm

-99dBm

-97dBm

-98dBm

-98dBm

-97dBm

-97dBm

-96dBm Receive Sensitivity (Typ.) Diversity SIMO 3GPP (SIMO) NA NA NA NA NA NA NA NA NA NA NA NA NA NA

-102dBm

-102dBm

-102dBm

-102dBm

-106.7dBm

-104.7dBm

-103.7dBm

-99dBm

-102dBm

-96.3dBm

-98dBm

-98dBm

-97dBm

-98dBm

-98dBm

-98dBm

-98dBm

-98dBm

-101dBm

-102dBm

-102dBm

-101dBm

-101dBm

-100dBm

-100dBm

-100dBm

-93.3dBm

-94.3dBm

-94.3dBm

-93.3dBm

-93.3dBm

-96.3dBm

-96.3dBm

-94.3dBm Table 51: SC20-A RF Receiving Sensitivity Frequency

-109dBm GSM850 NA PCS1900 WCDMA Band1 WCDMA Band2 Primary

-109dBm

-108dBm

-110dBm

-110dBm Receive Sensitivity (Typ.) Diversity SIMO NA NA NA NA NA NA NA NA 3GPP (SIMO)

-102dBm

-102dBm

-106.7dBm

-104.7dBm SC20_Hardware_Design Confidential / Released 7-102 / 122 Smart LTE Module Series SC20 Hardware Design WCDMA Band4 WCDMA Band5 WCDMA Band8 LTE-FDD B2 (10M) LTE-FDD B4 (10M)

-110dBm

-110dBm

-110dBm

-98dBm

-97dBm NA NA NA

-99dBm

-98dBm NA NA NA

-106.7dBm

-104.7dBm

-103.7dBm

-102dBm

-94.3dBm

-101dBm

-96.3dBm LTE-FDD B5 (10M)

-99.5dBm

-99.5dBm

-102.5dBm

-94.3dBm LTE-FDD B7 (10M)

-97dBm

-99dBm

-100dBm

-94.3dBm LTE-FDD B12 (10M)

-97.5dBm

-98.5dBm

-101dBm

-93.3dBm LTE-FDD B13 (10M) LTE-FDD B25 (10M) LTE-FDD B26 (10M)

-99dBm

-99dBm

-99dBm

-99dBm

-99dBm

-101dBm

-93.3dBm

-102dBm

-92.8dBm

-100dBm

-102.5dBm

-93.8dBm Table 52: SC20-AU RF Receiving Sensitivity Frequency Primary Receive Sensitivity (Typ.) Diversity SIMO 3GPP (SIMO)

-109dBm GSM850 NA

-109dBm EGSM900 DCS1800 PCS1900 WCDMA Band1 WCDMA Band2 WCDMA Band5 WCDMA Band8 LTE-FDD B1 (10M) LTE-FDD B3 (10M) LTE-FDD B5 (10M)

-109dBm

-108dBm

-109dBm

-110dBm

-110dBm

-110dBm

-110dBm

-98dBm

-97dBm

-99dBm NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA

-102dBm

-102dBm

-102dBm

-102dBm

-106.7dBm

-104.7dBm

-104.7dBm

-103.7dBm

-99dBm

-98dBm

-101dBm

-96.3dBm

-101.8dBm

-93.3dBm

-100dBm

-103dBm

-94.3dBm SC20_Hardware_Design Confidential / Released 7-103 / 122 Smart LTE Module Series SC20 Hardware Design LTE-FDD B7 (10M) LTE-FDD B8 (10M)

-97dBm

-98dBm

-99dBm

-100dBm LTE-FDD B28 (10M)

-97.5dBm

-100dBm LTE-TDD B40 (10M)

-97dBm

-98dBm

-100.6dBm

-94.3dBm

-102dBm

-93.3dBm

-101.8dBm

-100.7dBm

-94.8dBm

-96.3dBm Table 53: SC20-J RF Receiving Sensitivity Frequency WCDMA Band1 WCDMA Band6 WCDMA Band8 WCDMA Band19 LTE-FDD B1 (10M) LTE-FDD B3 (10M) LTE-FDD B8 (10M) LTE-FDD B18 (10M) LTE-FDD B19 (10M) LTE-FDD B26 (10M) LTE-FDD B41 (10M) Primary

-110dBm

-110dBm

-110dBm

-110dBm

-97dBm

-97dBm

-97dBm

-98dBm

-98dBm

-98dBm

-96dBm Receive Sensitivity (Typ.) Diversity SIMO 3GPP (SIMO) NA NA NA NA NA NA NA NA

-106.7dBm

-106.7dBm

-103.7dBm

-106.7dBm

-97.5dBm

-100dBm

-96.3dBm

-98dBm

-98dBm

-99dBm

-99dBm

-99dBm

-101.5dBm

-93.3dBm

-100dBm

-93.3dBm

-101.5dBm

-96.3dBm

-101.5dBm

-96.3dBm

-101.5dBm

-93.8dBm

-96.5dBm

-100dBm

-94.3dBm SC20_Hardware_Design Confidential / Released 7-104 / 122 Smart LTE Module Series SC20 Hardware Design 7.8. Electrostatic Discharge The module is not protected against electrostatic discharge (ESD) in general. Consequently, it should be subject to ESD handling precautions that are typically applied to ESD sensitive components. Proper ESD handling and packaging procedures must be applied throughout the processing, handling and operation of any application that incorporates the module. The following table shows the module electrostatic discharge characteristics. Table 54: Electrostatic Discharge Characteristics ( Temperature: 25C, Humidity: 45%) Tested Points Contact Discharge Air Discharge Unit VBAT, GND All Antenna Interfaces USB Interfaces Other Interfaces

+/-5

+/-5

+/-0.5

+/-0.5

+/-10

+/-10

+/-1

+/-1 KV KV KV KV SC20_Hardware_Design Confidential / Released 7-105 / 122 Smart LTE Module Series SC20 Hardware Design 8 Mechanical Dimensions This chapter describes the mechanical dimensions of the module. All dimensions are measured in millimeter (mm). The tolerances for dimensions without tolerance values are 0.05mm. 8.1. Mechanical Dimensions of the Module Figure 42: Module Top and Side Dimensions SC20_Hardware_Design Confidential / Released 8-106 / 122 Smart LTE Module Series SC20 Hardware Design Figure 43: Module Bottom Dimensions (Top View) SC20_Hardware_Design Confidential / Released 8-107 / 122 8.2. Recommended Footprint Smart LTE Module Series SC20 Hardware Design Figure 44: Recommended Footprint (Top View) NOTES 1. For easy maintenance of the module, keep about 3mm between the module and other components on host PCB. 2. All RESERVED pins should be kept open and MUST NOT be connected to ground. SC20_Hardware_Design Confidential / Released 8-108 / 122 8.3. Top and Bottom Views of the Module Smart LTE Module Series SC20 Hardware Design Figure 45: Top View of the Module Figure 46: Bottom View of the Module NOTE These are design effect drawings of SC20 module. For more accurate pictures, please refer to the module that you get from Quectel. SC20_Hardware_Design Confidential / Released 8-109 / 122 Smart LTE Module Series SC20 Hardware Design 9 Storage, Manufacturing and Packaging 9.1. Storage SC20 is stored in a vacuum-sealed bag. The storage restrictions are shown as below. 1. Shelf life in the vacuum-sealed bag: 12 months at < 40C/90%RH. 2. After the vacuum-sealed bag is opened, devices that will be subjected to reflow soldering or other high temperature processes must be:

Mounted within 168 hours at the factory environment of 30C/60%RH. Stored at <10%RH. 3. Devices require baking before mounting, if any circumstance below occurs. When the ambient temperature is 23C5C and the humidity indication card shows the humidity is >10% before opening the vacuum-sealed bag. Device mounting cannot be finished within 168 hours at factory conditions of 30C/60%. 4. If baking is required, devices may be baked for 48 hours at 125C5C. NOTE As the plastic package cannot be subjected to high temperature, it should be removed from devices before high temperature (125C) baking. to IPC/JEDECJ-STD-033 for baking procedure. If shorter baking time is desired, please refer SC20_Hardware_Design Confidential / Released 9-110 / 122 Smart LTE Module Series SC20 Hardware Design 9.2. Manufacturing and Soldering Push the squeegee to apply the solder paste on the surface of stencil, thus making the paste fill the stencil openings and then penetrate to the PCB. The force on the squeegee should be adjusted properly so as to produce a clean stencil surface on a single pass. To ensure the module soldering quality, the thickness of stencil for the module is recommended to be 0.18mm. For more details, please refer to document [3]. Figure 47: Recommended Stencil Design for LGA Pads It is suggested that the peak reflow temperature is from 235C to 245C (for SnAg3.0Cu0.5 alloy). The absolute maximum reflow temperature is 260C. To avoid damage to the module caused by repeated heating, it is suggested that the module should be mounted after reflow soldering for the other side of PCB has been completed. Recommended reflow soldering thermal profile is shown below:

SC20_Hardware_Design Confidential / Released 9-111 / 122 Smart LTE Module Series SC20 Hardware Design Figure 48: Reflow Soldering Thermal Profile SC20_Hardware_Design Confidential / Released 9-112 / 122 Smart LTE Module Series SC20 Hardware Design 9.3. Packaging SC20 is packaged in tape and reel carriers. Each reel is 12.32m long and contains 200 modules. The following figures show the package details, measured in mm. Figure 49: Tape Dimensions Figure 50: Reel Dimensions SC20_Hardware_Design Confidential / Released 9-113 / 122 Smart LTE Module Series SC20 Hardware Design Table 55: Reel Packaging Model Name MOQ for MP Minimum Package: 200pcs Minimum Package 4=800pcs SC20 200 Size: 370mm 350mm 85mm N.W: 1.92kg G.W: 3.17kg Size: 380mm 365mm 365mm N.W: 7.68kg G.W: 13.63kg SC20_Hardware_Design Confidential / Released 9-114 / 122 Smart LTE Module Series SC20 Hardware Design 10 Appendix A References Table 56: Related Documents SN Document Name Remark

[1]

[2]

[3]

[4]

Quectel_Smart_EVB_User_Guide Smart EVB user guide Quectel_SC20_Reference_Design SC20 reference design Quectel_Module_Secondary_SMT_User_Guide Module secondary SMT user guide Quectel_RF_Layout_Application_Note RF layout application note Table 57: Terms and Abbreviations Abbreviation Description ADC AMR ARP bps CHAP CS CSD CTS DRX DCE DTE DTR Analog-to-Digital Converter Adaptive Multi-rate Antenna Reference Point Bits Per Second Challenge Handshake Authentication Protocol Coding Scheme Circuit Switched Data Clear to Send Discontinuous Reception Data Communications Equipment (typically module) Data Terminal Equipment (typically computer, external controller) Data Terminal Ready SC20_Hardware_Design Confidential / Released 10-115 / 122 Smart LTE Module Series SC20 Hardware Design Discontinuous Transmission Enhanced Full Rate Extended GSM900 band (includes standard GSM900 band) Enhanced Synchronous Connection Oriented Electrostatic Discharge Full Rate Flexible Printed Circuit Gaussian Minimum Shift Keying Global Positioning System Global System for Mobile Communications Half Rate High Speed Packet Access Input/Output International Mobile Equipment Identity Maximum Load Current Normal Current Light Emitting Diode Low Noise Amplifier Mobile Originated Mobile Station (GSM engine) Mobile Terminated Password Authentication Protocol Packet Broadcast Control Channel Printed Circuit Board Protocol Data Unit DTX EFR EGSM eSCD ESD FR FPC GMSK GPS GSM HR HSPA I/O IMEI Imax Inorm LED LNA MO MS MT PAP PBCCH PCB PDU SC20_Hardware_Design Confidential / Released 10-116 / 122 Smart LTE Module Series SC20 Hardware Design PPP PSK QAM QPSK RF RHCP RMS RTC Rx SDIO SIM SMS TDMA TE TP TX UART UMTS URC

(U)SIM USSD Vmax Vnorm Vmin VIHmax Point-to-Point Protocol Phase Shift Keying Quadrature Amplitude Modulation Quadrature Phase Shift Keying Radio Frequency Right Hand Circularly Polarized Root Mean Square (value) Real Time Clock Receive Secure Digital Input and Output Subscriber Identification Module Short Message Service Time Division Multiple Access Terminal Equipment Touch Panel Transmitting Direction Universal Asynchronous Receiver & Transmitter Universal Mobile Telecommunications System Unsolicited Result Code Universal Subscriber Identity Module Unstructured Supplementary Service Data Maximum Voltage Value Normal Voltage Value Minimum Voltage Value Maximum Input High Level Voltage Value SC20_Hardware_Design Confidential / Released 10-117 / 122 Smart LTE Module Series SC20 Hardware Design VIHmin VILmax VILmin VImax VImin VOHmax VOHmin VOLmax VOLmin VSWR WCDMA Minimum Input High Level Voltage Value Maximum Input Low Level Voltage Value Minimum Input Low Level Voltage Value Absolute Maximum Input Voltage Value Absolute Minimum Input Voltage Value Maximum Output High Level Voltage Value Minimum Output High Level Voltage Value Maximum Output Low Level Voltage Value Minimum Output Low Level Voltage Value Voltage Standing Wave Ratio Wideband Code Division Multiple Access SC20_Hardware_Design Confidential / Released 10-118 / 122 Smart LTE Module Series SC20 Hardware Design 11 Appendix B GPRS Coding Schemes Table 58: Description of Different Coding Schemes Scheme Code Rate USF Pre-coded USF CS-1 1/2 3 3 Radio Block excl.USF and BCS 181 BCS Tail Coded Bits Punctured Bits Data Rate Kb/s 40 4 456 0 9.05 CS-2 2/3 3 6 268 16 4 588 132 13.4 CS-3 3/4 3 6 312 16 4 676 220 15.6 C4-4 1 3 12 428 16

-

456

-

21.4 SC20_Hardware_Design Confidential / Released 11-119 / 122 Smart LTE Module Series SC20 Hardware Design 12 Appendix C GPRS Multi-slot Classes Twenty-nine classes of GPRS multi-slot modes are defined for MS in GPRS specification. Multi-slot classes are product dependent, and determine the maximum achievable data rates in both the uplink and downlink directions. Written as 3+1 or 2+2, the first number indicates the amount of downlink timeslots, while the second number indicates the amount of uplink timeslots. The active slots determine the total number of slots the GPRS device can use simultaneously for both uplink and downlink communications. The description of different multi-slot classes is shown in the following table. Table 59: GPRS Multi-slot Classes Multislot Class Downlink Slots Uplink Slots Active Slots 1 2 3 4 5 6 7 8 9 10 11 12 13 14 1 2 2 3 2 3 3 4 3 4 4 4 3 4 1 1 2 1 2 2 3 1 2 2 3 4 3 4 2 3 3 4 4 4 4 5 5 5 5 5 NA NA SC20_Hardware_Design Confidential / Released 12-120 / 122 Smart LTE Module Series SC20 Hardware Design 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 5 6 7 8 6 6 6 6 6 8 8 8 8 8 8 5 5 5 5 5 6 7 8 2 3 4 4 6 2 3 4 4 6 8 1 2 3 4 NA NA NA NA NA NA NA NA NA NA NA NA NA NA NA 6 6 6 6 SC20_Hardware_Design Confidential / Released 12-121 / 122 Smart LTE Module Series SC20 Hardware Design 13 Appendix D EDGE Modulation and Coding Schemes Table 60: EDGE Modulation and Coding Schemes Coding Scheme Modulation Coding Family 1 Timeslot 2 Timeslot 4 Timeslot CS-1 CS-2 CS-3 CS-4 MCS-1 MCS-2 MCS-3 MCS-4 MCS-5 MCS-6 MCS-7 MCS-8 MCS-9 GMSK GMSK GMSK GMSK GMSK GMSK GMSK GMSK 8-PSK 8-PSK 8-PSK 8-PSK 8-PSK

/

/

/

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C B A C B A B A A 9.05kbps 13.4kbps 15.6kbps 21.4kbps 8.80kbps 11.2kbps 14.8kbps 17.6kbps 22.4kbps 29.6kbps 44.8kbps 54.4kbps 59.2kbps 18.1kbps 36.2kbps 26.8kbps 53.6kbps 31.2kbps 62.4kbps 42.8kbps 85.6kbps 17.60kbps 35.20kbps 22.4kbps 44.8kbps 29.6kbps 59.2kbps 35.2kbps 70.4kbps 44.8kbps 89.6kbps 59.2kbps 118.4kbps 89.6kbps 179.2kbps 108.8kbps 217.6kbps 118.4kbps 236.8kbps SC20_Hardware_Design Confidential / Released 13-122 / 122

 

 

Carbon Mobile 5 Installation Guide Verifone Part Number DOC278-003-EN-A, Revision A.5 Carbon Mobile 5 Installation Guide 2019 Verifone, Inc. All rights reserved. No part of the contents of this document may be reproduced or transmitted in any form without the written permission of Verifone, Inc. The information contained in this document is subject to change without notice. Although Verifone has attempted to ensure the accuracy of the contents of this document, this document may include errors or omissions. The examples and sample programs are for illustration only and may not be suited for your purpose. You should verify the applicability of any example or sample program before placing the software into productive use. This document, including without limitation the examples and software programs, is supplied As-Is. Verifone and the Verifone logo are registered trademarks of Verifone. Other brand names or trademarks associated with Verifones products and services are trademarks of Verifone, Inc. All other brand names and trademarks appearing in this manual are the property of their respective holders. Product Warranty:

For product warranty information, go to http://www.verifone.com/terms. Comments? Please e-mail all comments on this document to your local Verifone Support Team. Verifone, Inc. 1-800-Verifone www.verifone.com Verifone Part Number DOC278-003-EN-A, Revision A.5 CONTENTS PREFACE . 5 Audience. 5 Organization . 5 Related Documentation . 5 Conventions and Acronyms . 6 CHAPTER 1 Device Overview Features and Benefits . 10 BT and WiFi Performance. 11 Modern Application Environment . 11 Accepts All Forms of Payment On-the-Go . 11 Exceptional Ease of Use. 11 Performance and Durability . 11 Security. 11 Connectivity . 12 Charger IC . 13 Main Battery . 13 Fuel Gauge . 13 Exceptional Ease of Use. 13 CHAPTER 2 Device Setup Usage Guidelines . 15 Environmental Factors . 15 Personal Security Considerations. 16 Electrical Considerations . 16 Unpacking the Shipping Carton . 16 Examining Verifone Carbon Mobile 5 Device Features . 17 Front Panel . 17 Installing or Replacing MSAM Cards . 18 To Install or replace MSAMs. 18 Connecting Cash Drawer to the Verifone Carbon Mobile 5 . 18 Examining Connection Port . 18 Using the Battery . 19 Battery Features . 19 Battery Behavior (No Power Pack). 19 Manual Startup . 19 Manual Shutdown . 19 Connecting the Terminal Power Pack . 20 Loading a Paper Roll in Device with Printer . 20 Charging the Battery. 22 Battery Life . 22 Using the Smart Card Reader . 22 Using the Magnetic Card Reader . 22 Using the CTLS Reader . 23 CARBON MOBILE 5 INSTALLATION GUIDE 3 CONTENTS CHAPTER 3 Specifications Technical Specifications . 25

. 25 CHAPTER 4 Maintenance Surface Cleaning . 29 Magnetic Card Reader . 29 Smart Card Reader . 29 Additional Safety Information . 30 CHAPTER 5 Verifone Service and Support CHAPTER 6 Troubleshooting Guidelines Returning a Device for Service. 31 Accessories and Documentation . 32 Accessories. 32 Documentation . 32 Device Does Not Start . 35 Device Display Does Not Show Correct/Readable Info . 35 Battery Does Not Charge . 36 Blank Display . 36 Transactions Fail to Process . 36 4 CARBON MOBILE 5 INSTALLATION GUIDE PREFACE This guide is your primary source of information for setting up Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer. Audience This guide is useful for anyone installing the Verifone Carbon Mobile 5 device. Organization This guide is organized as follows:

Chapter 1, Device Overview. Provides an overview of the Verifone Carbon Mobile 5 device. Chapter 2, Device Setup. Explains how to set up the Verifone Carbon Mobile 5 device. It tells you how to select a location and establish power connection. Chapter 3, Specifications. Discusses power requirements and dimensions of the Verifone Carbon Mobile 5. Chapter 4, Maintenance. Explains how to maintain your Verifone Carbon Mobile 5. Chapter 5, Verifone Service and Support. Provides information on how to contact your local Verifone representative or service provider, and information on how to order accessories or documentation from Verifone. Chapter 6, Troubleshooting Guidelines. Provides troubleshooting guidelines, should you encounter a problem in device installation. Related Documentation To learn more about the Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer, refer to the following set of documents:

Verifone Carbon Mobile 5 Certifications and Regulations Sheet VPN -DOC278-001-EN-A Verifone Carbon Mobile 5 Quick Installation Guide VPN -DOC278-002-EN-A Verifone Carbon Mobile 5 with Printer Quick Installation Guide VPN -DOC278-01-002-EN-A CARBON MOBILE 5 INSTALLATION GUIDE 5 PREFACE Conventions and Acronyms Conventions and Acronyms This section describes the conventions and acronyms used in this guide. Various conventions are used to help you quickly identify special formatting. Table 1 describes these conventions and provides examples of their use. Table 1 Convention Meaning Blue Example See Conventions and Acronyms. Document Conventions Text in blue indicates terms that are cross referenced. Italics Courier NOTE CAUTION Italic typeface indicates book titles or emphasis. The courier type face is used while specifying onscreen text, such as text that you would enter at a command prompt, or to provide an URL. The pencil icon is used to highlight important information. The caution symbol indicates possible hardware or software failure, or loss of data. N A .2 The lightning symbol is used as a warning when bodily injury might occur. You must install a roll of thermal-

sensitive paper in the printer. http://www.verifone.com RS-232-type devices do not work with the PIN pad port. The device is not waterproof or dustproof, and is intended for indoor use only. Due to risk of shock do not use the device near water. V I S I O WARNING E R Acronym Definitions Various acronyms are used in place of the full definition. Table 2 presents acronyms and their definitions. Table 2 Acronym AC ARM EMV LCD NFC MRA PCI PED PIN USB VPN Definitions Alternating Current Acorn RISC Machine Europay MasterCard and VISA Liquid Crystal Display Near Field Communication Merchandise Return Authorization Payment Card Industry PIN Entry Device Personal Identification Number Universal Serial Bus Verifone Part Number 6 CARBON MOBILE 5 INSTALLATION GUIDE Device Overview CHAPTER 1 This chapter provides a brief description of the Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer devices. The Verifone Carbon Mobile 5 device is a best-in-class, single-screen commerce solution. A secure wireless handheld mobile payment device that allows merchants to process credit/debit card transactions anywhere. In combination with Verifone Connect digital services, it offers checkout, payment, and the ability to run Android apps, like loyalty and inventory. It also enables clients to remotely monitor and update their device using Verifones estate management solution. The Verifone Carbon Mobile 5 device supports Bluetooth BLE and WiFi, and meets PCI 5.X SRED requirements for maximum security. The Verifone Carbon Mobile 5s small, sleek, design makes it easily pocketable while supporting all payment methods - magnetic stripe, EMV, and NFC/CTLS, including Apple Pay, Google Pay, and Samsung Pay mobile wallets. The easy to read color touch screen supports all payment related user interactions, including secure PIN entry. NOTE Verifone ships two variants of the Verifone Carbon Mobile 5 device for different markets. Your device may have different features described in this section. The Verifone Carbon Mobile 5 device has two variants:

Verifone Carbon Mobile 5

Verifone Carbon Mobile 5 with Printer The two variants (Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer) differ in memory size, front camera, battery size and printer. CARBON MOBILE 5 INSTALLATION GUIDE 7 DEVICE OVERVIEW 1 Figure 1 Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer Key Features and Benefits Features Verifone Carbon Mobile 5 Processor Memory Display Keypad

Cortex A7 Quad

Core, 1.1GHz

(QCOM 8909),

(QCOM MSM8909)

1 GB RAM (option for 2 GB)

8 GB Flash (option for 16 GB)

Secure processor:

128 MB DRAM, 256 MB Flash

5" (720 1280) HD IPS LCD touchscreen

On-screen, Navigator possible Printer

SKU 8 CARBON MOBILE 5 INSTALLATION GUIDE Yes Yes Yes Yes NA Verifone Carbon Mobile 5 with Printer Yes Yes Yes Yes Yes DEVICE OVERVIEW Yes Yes

Loudspeaker

Microphone

Loudspeaker

Microphone

Optional 3.5mm Headset Jack Yes Yes Yes Yes Yes Yes

MSR

SCR

CTLS Payment Audio Communication Peripheral Ports Camera

4G LTE

3G

2G

Bluetooth 4.2 BLE,

2.4 GHz + 5.8 GHz WiFi,

802.11 a, b, g, n, GPS, GLONASS

USB-C

OTG

Charging pins

5 MP

Auto-focus

Fast scanner

LED aimer

LED torch Optional 2 MP front QR/

barcode scanner Barcode reader

Yes Yes

Removable battery provides 300 CTLS transactions over 10.5 hrs. Battery Dimensions 4000-mAh 6200-mAh

Length: 165.7 mm

Width: 77.9 mm

Height: 15.8 mm

Weight: 275 g

Length: 184.29 mm

Width: 77.9 mm

Height: 32.7 mm

59.55(Head)

Weight: 495 g with full paper roll CARBON MOBILE 5 INSTALLATION GUIDE 9 DEVICE OVERVIEW Features and Benefits Security Power Supply SIM/SAM Card Reader Environmental Yes Yes

PCI PTS 5.X-

approved

SRED

Supports AES DUKPT

Up to 5 V 3 A charging

4000 mAh Li-Ion rechargeable battery

Up to 5 V 3 A charging

6200 mAh Li-

Ion rechargeable battery Yes Yes Yes Yes Yes Yes

1 Nano SIM,

1 micro SAM or 2nd micro SIM

Triple track MSR

EMV L1-approved smart card ISO

NFC/CTLS

Operating temperature: -10 to 50deg C (14deg to 122deg F)

Storage temperature:

-25 to 70 C (-13 to 158 F)

Relative humidity:

5% to 95%

Non-condensing Printer NA

High-speed thermal printer:

30 lps

Paper roll: Max 57.65mm Length x Max 40mm Diameter. Features and Benefits Verifone Carbon Mobile 5 provides magnetic-stripe card reader (MSR), smart card

(SC) and contactless (CTLS) payment processing with a 5-inch (12.7 cm) color TFT capacitive touch panel LCD screen. Some variants provide additional expansion options such as a bar code scanner and weighing scale, connectivity features: USB, Ethernet as well as power charging and an embedded internal thermal printer (ITP). 10 CARBON MOBILE 5 INSTALLATION GUIDE DEVICE OVERVIEW Features and Benefits The Verifone Carbon Mobile 5 provides the right combination of features and functions including a triple-track magnetic-stripe card reader, smart card reader, digital PINpad and contactless/NFC support. BT and WiFi Performance The dynamic combination of Bluetooth and Wi-Fi provides convenience to wireless payment with fewer dropped transactions, and flexible point-of-sale options. Modern Application Environment Accepts All Forms of Payment On-the-Go

The Verifone Carbon Mobile 5 offers 256 MB flash and 128 MB of dynamic memory allocation for the terminal and 1GB (optional 2GB) of SDRAM, which supports multiple applications. The primary smart card reader and the MSAMs safeguard sensitive financial data and support multiple smart card schemes.

Verifone Carbon Mobile 5 units are certified for ISO 7816-1 and ISO 7816-2 standards for smart card solutions, as well as ISO 14443 type A & B and ISO 18092 standards for CTLS operations. The VeriShield security architecture meets published specifications for PCI PTS POI and provides sophisticated file authentication to prevent execution of unauthorized software on Verifone Carbon Mobile 5 devices.

Accommodates all payment types - Magnetic stripe, EMV, Contactless/NFC, and mobile wallets along with a 5 inch color touch screen with digital PIN pad and signature capture. Exceptional Ease of Use

The lightweight, compact, stylish, and ergonomic balance provide a convenient payment experience for the user.

Horizontal, bi-directional, magnetic stripe card reader at the top of Verifone Carbon Mobile 5 features an enlarged card entrance and delivers optimal card swiping and reading.

Easy to hold, easy to carry. The Verifone Carbon Mobile 5 units compact size allows it to easily fit in your pocket and provides lanyard holes, on both sides of the device, to attach wrist/neckbands. Performance and Durability

Secure and powerful 300 MHz processing encrypts and completes transactions quickly.

High-capacity, lithium-ion rechargeable battery for CM5 only (4.4 V / 4000 mAh) that easily supports a full 16-hour business day on a single charge. The USB-C port allows for convenient product charging as well as connection to accessories, and Android, iOS, and Windows devices.

Drop-tested up to 1.2m on marble floor surface.

This device has 256MB Flash, 128MB SDRAM of memory. Security PCI PED 5.X approved for PIN-based transactions CARBON MOBILE 5 INSTALLATION GUIDE 11 DEVICE OVERVIEW Features and Benefits TLS/SSL protocols

Direct key injection using industry standard HSMs

VeriShield Retain

VeriShield Remote Key

Verifone Secure Data

VeriShield Total Protect

MasterCard TQM

EMV L1 and L2

ISO7816-3, ISO7816-10, and EMV 4.3 standards IPP8 functionality plus multiple AES DUKPT engines Connectivity USB host/ device port

1 USB Type-C Receptacle (can be used for charging)

Support Android UART software debug (TXD, RXD)

Support Secure Processor UART software debug (TXD0, RXD0)

Android USB 2.0 HighSpeed Host/Client Support

Secure Processor USB 2.0 HighSpeed Host/Client Support 5V/500mA for external USB peripherals

USB host or device is configured by Software

Smart device communication is through USB-C The Verifone Carbon Mobile 5 USB-C port is on the right hand side Cellular (wireless communication)

4G LTE (3GPP R8 Cat.4 FDD and TDD) 3G UMTS (3GPP R8 DC-HSDPA/HSPA+/HSDPA/HSUPA/WCDMA) 2G GSM (R99/GPRS/EDGE) Bluetooth (wireless communication)

Bluetooth 4.2 (BR/EDR+BLE)

RF transmitter output power Class 1

RF receiver GFSK typical -90dBm,/4 PSK typical -90dBm, 8-DPSK typical -

83dBm WiFi (wireless communication)

WiFi 2.4GHz/5GHz dual band, 802.11 a/b/g/n Charger IC Single cell or dual parallel cell switching mode Li-Ion battery charger 12 CARBON MOBILE 5 INSTALLATION GUIDE DEVICE OVERVIEW Features and Benefits

Power path management integrated

Programmable charging parameters

Support dual inputs from either charging pins or USB connector Main Battery Removable battery

Nominal capacity/voltage: 4000mAh/3.85V (CM5) or 6200mAh/3.7V (CM5P Printer) Fuel Gauge Host-side fuel gauge with Coulomb counter function Exceptional Ease of Use

Capacitive touch-screen UI access for merchant and customer

The contactless (CTLS) functionality offers a convenient payment option for consumers The triple-track, high-coercivity card reader handles most magnetic stripe cards

EMV card reader ensures secure payment option

Large 5-inch LCD displays The multiple font-capable optional thermal printer simplifies paper loading and reduces paper jams

Uses Max 57.65 mm Length x Max 40 mm Diameter paper rolls, prints at 100 mm/sec CARBON MOBILE 5 INSTALLATION GUIDE 13 DEVICE OVERVIEW Features and Benefits 14 CARBON MOBILE 5 INSTALLATION GUIDE Device Setup CHAPTER 2 Installing or Replacing MSAM Cards This chapter describes the device setup procedure. You will learn about:

Usage Guidelines

Unpacking the Shipping Carton

Examining Verifone Carbon Mobile 5 Device Features

Examining Connection Port

Examining Connection Port

Using the Battery

Connecting the Terminal Power Pack

Charging the Battery

Using the Smart Card Reader

Using the Magnetic Card Reader

Using the CTLS Reader Loading a Paper Roll in Device with Printer Usage Guidelines Environmental Factors Use the following guidelines when using your Verifone Carbon Mobile 5.

Select a flat support surface, such as a countertop or table, place the device. Please store your Verifone Carbon Mobile 5 device in a dry area:

Operation temperature is -10--50 degree Celsius ( 14--122 F).

Storage temperature is -25--70 degree Celsius (-13--158 F).

Do not use the device where there is high heat, dust, humidity, moisture, or caustic chemicals or oils.

Keep the device away from direct sunlight and anything that radiates heat, such as a stove or motor. CAUTION The device is not waterproof or dustproof, and is intended for indoor use only. Any damage to the unit from exposure to rain or dust may void any warranty. CARBON MOBILE 5 INSTALLATION GUIDE 15 DEVICE SETUP Unpacking the Shipping Carton Personal Security Considerations Electrical Considerations The Verifone Carbon Mobile 5 can be used as handover device. Always exercise extreme caution when conducting transactions especially during PIN entry.

Hand the Verifone Carbon Mobile 5 directly to the cardholder for PIN entry.

Encourage the cardholder to hold the Verifone Carbon Mobile 5 close to avoid others from seeing the information entered.

Avoid using this product during electrical storms.

Avoid locations near electrical appliances or other devices that cause excessive voltage fluctuations or emit electrical noise (for example, air conditioners, electric motors, neon signs, high-frequency or magnetic security devices, or computer equipment).

Do not use the device near water or in moist conditions. Unpacking the Shipping Carton Open the shipping carton and carefully inspect its contents for possible tampering or shipping damage. The Verifone Carbon Mobile 5 is a secure product and any tampering may cause the device to cease to function properly. To unpack the shipping carton 1 Validate the authenticity of the sender by verifying the shipping tracking number and other information located on the product order paperwork. 2 Remove and inspect the following items:

Verifone Carbon Mobile 5 unit

USB-C to USB cable

Paper roll NOTE Verifone ships variants of the Verifone Carbon Mobile 5 for different markets. Your unit may have different options or accessories described in this section. 3 Remove all plastic wrapping from the unit and other components. 4 Remove the clear protective film from the display. CAUTION Do not use a unit that has been tampered with or otherwise damaged. This unit comes equipped with tamper-evident labels. If a label or component appears damaged, immediately notify the shipping company and your Verifone representative or service provider. 16 CARBON MOBILE 5 INSTALLATION GUIDE DEVICE SETUP Examining Verifone Carbon Mobile 5 Device Features 5 Save the shipping carton and packing material for future repacking or storing the device. NOTE

Charge the Verifone Carbon Mobile 5 device for eight hours before initial use.

The Verifone Carbon Mobile 5 device comes with an extra battery, that will power the security circuit of the device, in case the device is tampered, and the main battery fails to charge. This extra battery has a life of 2 yrs.

Ensure not to store the device for more than 1 week without charging, else the secondary battery gets discharged in turn reducing the life of the battery. Examining Verifone Carbon Mobile 5 Device Features Before you continue the installation process, familiarize yourself with the features of the Verifone Carbon Mobile 5 (See Figure 2.) Front Panel The front panel includes the following features:

1 1 Figure 2

Verifone Carbon Mobile 5 (Front Panel) The Verifone Carbon Mobile 5 device has a colored capacitive-touch LCD Display

A smart card reader built into the top of the device to process smart card-

based debit or credit transactions. For directions on how to use a smart card, see Using the Smart Card Reader.

A magnetic card reader built into the bottom part of the device for performing debit or credit card transactions. The card can be swiped from either direction. To ensure a proper read of the magnetic swipe card, insert the magnetic card from the side of the device as shown in Figure 7. The Verifone Carbon Mobile 5 device has a power/charging indicator.

ALL LED's to indicate CTLS, EMV, MSR, BT, and Wi-Fi are shown ON the display.

CTLS around the display for contactless payments. For directions on how to conduct contactless transactions, see Using the CTLS Reader. CARBON MOBILE 5 INSTALLATION GUIDE 17 DEVICE SETUP Installing or Replacing MSAM Cards Installing or Replacing MSAM Cards When you first receive your Verifone Carbon Mobile 5, you may need to install one or more MSAM cards, or you may need to replace old cards. CAUTION Observe standard precautions when handling electrostatically sensitive devices. Electrostatic discharges can damage this equipment. Verifone recommends using a grounded anti-static wrist strap. NOTE Verifone ships variants of the Verifone Carbon Mobile 5 for different markets. Your unit may have different options or accessories described in this section. To Install or replace MSAMs/MSIMs FOR CM5 1 Turn off the Verifone Carbon Mobile 5 device. 2 Place the device face down on a soft, clean surface to protect the display from scratches. 3 Remove the battery cover from the bottom and provide access to the MSAM card slot. 4 Remove any previously installed MSAM cards from the cardholder by pulling out the MSAM in a horizontal direction. card is fully inserted. 5 Insert a MSAM card (with contacts face down) by carefully sliding it into the slot until the 6 Make sure the card orientation is matching with the icon engraved in the housing. 7 Place the battery cover. FOR CM5P 1 Turn off the Verifone Carbon Mobile 5 device. 2 Place the device face down on a soft, clean surface to protect the display from scratches. 3 Remove the battery cover from the bottom corners. 4 Remove the primary battery from the battery compartment, but keep the battery connected. 5 Remove any previously installed MSAM cards from the cardholder by pushing down on the Nano-SIM icon (or actual Nano-SIM card) and pulling out the MSAM in horizontal direction. 6 Insert a MSAM card (with contacts face down) by carefully sliding it into the slot until the card is fully inserted. 7 Make sure the card orientation is matching with the icon engraved in the housing. 8 Place the primary battery. 9 Place battery cover. 18 CARBON MOBILE 5 INSTALLATION GUIDE Examining Connection Port The Verifone Carbon Mobile 5 device has one primary USB-C port used for power and download. DEVICE SETUP Examining Connection Port USB-C USB-A Figure 3 The Verifone Carbon Mobile 5 Primary USB-C Port Using the Battery The Verifone Carbon Mobile 5 device uses a single cell Li-Polymer battery or a dual cell Li-Ion battery. The internal logic of the battery prevents both overcharging and undercharging (a fault condition in which the battery level goes well below the minimum acceptable charge and the battery becomes unusable). Battery Features The following are features of the battery:

Single Li-Polymer cell for CM5 and two Li-Ion cells for CM5 printer.

A safety circuit that:

NOTE

Prevents cell damage from overcharge, over-discharge, or overheating

Activates when the battery is left in an unused device for extended periods

Charge the Verifone Carbon Mobile 5 device for eight hours before initial use.

The Verifone Carbon Mobile 5 device comes with an extra battery that will power the security circuit of the device in case, the device is tampered, and the main battery fails to charge. This extra battery has a life of 1 year.

Do not store the device for more than 1 week without charging, else the secondary battery gets discharged in turn reducing the life of the battery.

Disconnecting and unplugging the device power pack, reduces the life of the coin cell battery, which does not recharge and must be replaced if drained.

Conserve battery power by turning the Verifone Carbon Mobile 5 device off when not in use. Do not let the battery charge fall below 10% for extended periods of time as this may permanently diminish the battery capacity. Recharge the battery by attaching the USB-C end of the power pack to the device and plugging the other end of the power pack into a wall outlet. CARBON MOBILE 5 INSTALLATION GUIDE 19 DEVICE SETUP Connecting the Terminal Power Pack Manual Startup Hold the start button for about 3 seconds until the device displays the startup screen. NOTE Once the device is powered up, The Verifone ADK MAC screen is displayed. Manual Shutdown Hold the start button for about 1 second until the message is displayed on the screen. Touch the "Off" selection to turn off. NOTE The screen is blank when the device has no power. Connecting the Terminal Power Pack Connect the Verifone Carbon Mobile 5 device to the provided USB cable and insert the other end into any USB charger head for initial charging. CAUTION Using an incorrectly rated power supply may damage the device or cause it not to work as specified. Before troubleshooting, ensure that the power supply being used to power the device matches the requirements specified on the bottom of the device. (See Specifications for detailed power supply specifications.) You can use any standard USB charger. WARNING Do not plug the power pack into an outdoor outlet or operate the device outdoors. During a transaction, disconnecting the power by unplugging the device from a wall power while at very low battery charge may cause transaction data files not yet stored in the device memory to be lost. Each Verifone Carbon Mobile 5 device comes with a power supply cable, USB-A to USB-C cable is used to connect the device directly to an USB outlet to charge the battery. The Verifone Carbon Mobile 5 unit is equipped with an USB capable universal port. 20 CARBON MOBILE 5 INSTALLATION GUIDE DEVICE SETUP Loading a Paper Roll in Device with Printer To Connect the Terminal Power Supply 1 Insert the USB-C to the Verifone Carbon Mobile 5 and USB-A port to the power supply or Desktop. USB-A USB-A Figure 4 Verifone Carbon Mobile 5 Power Supply Connection TIP To protect against possible damage caused by lightning strikes and electrical surges, consider installing a power surge protector. Loading a Paper Roll in Device with Printer Install a paper roll before you can process transactions that require a receipt. The Verifone Carbon Mobile 5 Printer Stand uses a roll of 58 mm x 40 mm, single-

ply, thermal-sensitive paper. A pink out-of-paper indicator line appears on the edge of the paper before the end of the roll. After this line appears, there is enough paper remaining on the roll to conclude at least one more transaction. NOTE A message is always displayed to indicate when the printer is out of paper. CAUTION Poor-quality paper can jam the printer and create excessive paper dust. To order high-quality Verifone paper, refer to Accessories and Documentation. Store thermal paper in a dry, dark area. Handle thermal paper carefully: impact, friction, temperature, humidity, and oils affect the color and storage characteristics of the paper. Never load a roll of paper with folds, wrinkles, tears, or holes at the edges. To install a paper roll 1 Hold both sides of the paper door, which is on the upper corner of the device and open the paper door by pulling outside (See below Figure 5-A). CARBON MOBILE 5 INSTALLATION GUIDE 21 DEVICE SETUP Charging the Battery 2 Remove any partial roll of paper in the tray.

Figure 5 3 Loosen the glued leading edge of the new paper roll or remove the protective Steps to Install a Paper Roll in Verifone Carbon Mobile 5 strip. Unwind the paper roll past any glue residue. 4 Hold the roll so the paper feeds from the top of the roll. 5 Pull the paper past the printer door. 6 Align the printer paper to the tabs to the paper guides and hold the paper up when closing the door. 7 With the printer paper extending outside, close the printer door by swinging upward until the door clicks shut, allowing the printer paper to extend outside the printer door. Charging the Battery After unpacking your Verifone Carbon Mobile 5 device, connect the power pack to the unit for eight hours or until fully charged. Refer to the Using the Battery section for more details. Battery Life Charging and discharging the battery will cause normal wear on the battery. WARNING Do not dispose batteries in a fire. Li-Polymer and Li-Ion batteries must be recycled or disposed of properly. Do not dispose Li-ion batteries in municipal waste sites. Using the Smart Card Reader Insert the smart card to proceed with the EMV transaction. EMV supports credit card and debit card transactions. To Conduct a Smart Card Transaction 1 Position the smart card with the contacts facing upward (see illustration below). 22 CARBON MOBILE 5 INSTALLATION GUIDE DEVICE SETUP Using the Magnetic Card Reader 2 Insert the card into the reader slot in a smooth, continuous motion until it seats firmly. 3 Wait for the application to indicate a completed transaction before removing the card. Premature card removal invalidates the transaction.

Figure 6 Inserting a Smart Card Use the magnetic stripe reader to perform credit and debit card transactions. Using the Magnetic Card Reader To Conduct a Debit or Credit Card Transaction 1 Position the card with the magnetic stripe facing backwards. 2 To ensure a proper read of the magnetic swipe card, insert the magnetic card from the side of the device, as shown in the illustration below.

Figure 7 3 Swipe the card through the magnetic card reader. Using Magnetic Stripe Card CARBON MOBILE 5 INSTALLATION GUIDE 23 DEVICE SETUP Using the CTLS Reader Using the CTLS Reader The Verifone Carbon Mobile 5 supports contactless credit or debit card transactions. To perform a contactless transaction, gently tap the card or hold the card against the surface of the display.

Figure 8 Using the CTLS Reader 24 CARBON MOBILE 5 INSTALLATION GUIDE BeforeusingCM5,pleasefollowbelowinstructiontoinstalltheCM5intheholster Theholsterisdesignedsuchthatthedevicecanonlybeplacedintotheholsterwiththefront ofthedevicefacingthebody,asshownintheimagebelow.IfaholsternotapprovedbyVerifone isusedwiththisdevice,theuseristoplacethedeviceinthesameorientationasdescribed below. Frontface ofdevice Body CHAPTER 3 Specifications This chapter discusses the power requirements and dimensions of the Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer devices. Technical Specifications Refer to the following information on the power, weight, temperature, memory, ports and other technical details about Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer devices. Temperature

Operating Environment:

Temperature: -10C to 50C (14 F to 122 F)

Relative humidity: 5% to 95% RH non-condensing

Non-Operating Environment:

Temperature: -25C to 70C (-13F to 158F) Relative humidity: 5% to 95% RH non-condensing Android Memory

RAM: 1GB (option for 2GB)

Secure processor: 128 MB DRAM, 256 MB Flash Flash: 8GB (option for 16GB) Triple-track Magnetic Stripe Card

Supports bi-directional card read

Swipe speed at 10 IPS to 40 IPS Smart Card Reader

Non-sliding

Card conserving plated landing contacts SAM Requirements

1 SAM slot ID-000 format CARBON MOBILE 5 INSTALLATION GUIDE 25 SPECIFICATIONS Technical Specifications Display

5" (720 1280) HD IPS LCD touchscreen Input power rating: 5 V DC, 2 A Unit Power Requirement

Charging via USB-C to and external dock connector

Rechargeable battery

Verifone Carbon Mobile 5 - 3900 to 4000 mAh Li-Polymer rechargeable battery

Verifone Carbon Mobile 5 with Printer - 6200 mAh Li-Ion rechargeable Verifone Carbon Mobile 5 with Printer 184.29 mm 77.9 mm 32.7 mm handle/59.55 mm 495 g with full paper roll battery External Dimensions Verifone Carbon Mobile 5 Length Width Height Drum Paper roll Weight 165.7 mm 77.9 mm 15.8 mm 275 g (for non-printer) Communication

BT 4.2 BLE (Bluetooth Low Energy)

WiFi 2.4GHz/5GHz (A/B/G/N) SIM/SAM

1 Nano SIM 1 micro SAM or 2nd micro SIM Audio

Optional headset jack (Verifone Carbon Mobile 5 with Printer only) Loudspeaker, microphone Camera

5 MP, auto-focus Fast scanner LED aimer LED torch 26 CARBON MOBILE 5 INSTALLATION GUIDE SPECIFICATIONS Technical Specifications

Optional 2 MP front QR/barcode scanner Printer

Verifone Carbon Mobile 5 with Printer

High-speed thermal printer: 30 lps

paper roll: Max 57.65mm Length x Max 40mm Diameter CARBON MOBILE 5 INSTALLATION GUIDE 27 SPECIFICATIONS Technical Specifications 28 CARBON MOBILE 5 INSTALLATION GUIDE CHAPTER 4 Maintenance The Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer devices have no user-maintainable parts. It can, however, be cleaned. Surface Cleaning To clean the device, use a clean cloth slightly dampened with water and a drop or two of mild soap. For stubborn stains, use cleaner. CAUTION Never use thinner, trichloroethylene, or ketone-based solvents they may cause deterioration of plastic or rubber parts. Do not spray cleaners or other solutions directly on the device display. Magnetic Card Reader Dirt accumulation can lead to MSR reading problems unless you clean the magnetic stripe reader (MSR) on a regular basis (daily to once a week, depending on usage). Clean the MSR using commercially available card reader cleaning cards or using Verifones recommended MSR-cleaning card (PN 02746-02). NOTE If using a commercially available cleaning card, use ONLY an approved MSR cleaning card made specifically for POS MSR terminals or Petroleum MSR card readers. Smart Card Reader Do not attempt to clean the Smart Card Reader (SCR). Doing so may void any warranty. For smart card reader service, contact your Verifone distributor or service provider. CAUTION If you find foreign objects in the SCR, send your terminal to a Verifone authorized repair center. Do not use Verifones recommended MSR-cleaning card (PN 02746-02) or commercially available card reader cleaning cards with the SCR. CARBON MOBILE 5 INSTALLATION GUIDE 29 MAINTENANCE Additional Safety Information Additional Safety Information The following is additional information for your safety in using this device. WARNING Potentially Explosive Environments When using the device in areas with potential risk of explosion, such as gas stations, follow the advice of all signs and instructions. If there has been a leak, do not use this device. 30 CARBON MOBILE 5 INSTALLATION GUIDE CHAPTER 5 Verifone Service and Support For Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer problems, contact your local Verifone representative or service provider. For Verifone Carbon Mobile 5 product service and repair information:

USA Verifone Service and Support Group, 1-800-Verifone (837-4366), Monday - Friday, 8 A.M. - 8 P.M., Eastern time International Contact your Verifone representative

Returning a Device for Service Before returning the device, you must obtain an MRA number. The following procedure describes how to return one or more devices for repair or replacement

(U.S. customers only). NOTE Customers outside the United States are advised to contact their local Verifone representative for assistance regarding service, return, or replacement of devices and accessories. To return a device for service 1 Get the following information from the on the box or underneath the plastic rear shell. You have to remove the white plastic shell from the rear of the device to expose the printed labels or get the information from the labels on the box. at the back of each Verifone Carbon Mobile 5 to be returned:

Product ID, including the model and part number. For example, Verifone Carbon Mobile 5 and M087-XXX-XXX-XXX.

Serial number (S/N nnn-nnn-nnn) 2 Obtain the MRA number(s) by completing one of the following:

a Call Verifone toll-free within the United States at 1-800-Verifone and follow the automated menu options.

Select the MRA option from the automated message. The MRA department is open Monday to Friday, 8 A.M.8 P.M., Eastern Time.

Give the MRA representative the information you gathered in Step 1. If the list of serial numbers is long, you can fax the list, along with the information gathered in Step 1, to the MRA department at 727-953-

4172 (U.S.). b Address a fax to Verifone MRA Department. include the model and part number(s) CARBON MOBILE 5 INSTALLATION GUIDE 31 VERIFONE SERVICE AND SUPPORT Accessories and Documentation

Include a telephone number where you can be reached and your fax number. c Complete the Inquiry Contact Form at http://www.verifone.com/

aboutus/contact/contact_form.cfm.

Address the Subject box to Verifone MRA Department.

Reference the model and part number in the Note box. NOTE One MRA number must be issued for each device you return to Verifone, even if you are returning several of the same model. 3 Describe the problem(s). 4 Provide the shipping address where the repaired or replacement unit must be returned. 5 Keep a record of the following items:

Assigned MRA number(s).

Verifone serial number assigned to the device you are returning for service or repair (device serial numbers are located at the back of the unit.

Shipping documentation, such as air bill numbers used to trace the shipment.

Model(s) returned (model numbers are located on the Verifone label at the bottom of the white plastic shell or box labels. Verifone produces the following accessories and documentation for the Verifone Carbon Mobile 5 and Verifone Carbon Mobile 5 with Printer. When ordering, please take note of the part number.

Verifone online store at www.estore.verifone.com

USA Verifone Customer Development Center, 800-Verifone (837-4366), Monday - Friday, 7 A.M. - 8 P.M., Eastern time International Contact your Verifone representative

Verifone Certified Power Adapter Verifone MSR Cleaning Kit PWR087-300-01-A 02746-01 Accessories and Documentation Accessories Documentation Verifone Carbon Mobile 5 Certifications and Regulations Sheet VPN -DOC278-001-EN-A Verifone Carbon Mobile 5 Quick Installation Guide VPN -DOC278-002-EN-A Verifone Carbon Mobile 5 with Printer Quick Installation Guide VPN -DOC278-01-002-EN-A 32 CARBON MOBILE 5 INSTALLATION GUIDE CHAPTER 6 Troubleshooting Guidelines The troubleshooting guidelines provided in the following section are included to help you install and configure your Verifone Carbon Mobile 5 successfully. Typical examples of malfunction you may encounter while operating your Verifone Carbon Mobile 5 and steps you can take to resolve them are listed in this chapter. If the problem persists even after performing the outlined guidelines or if the problem is not described below, contact your local Verifone representative for assistance. NOTE The Verifone Carbon Mobile 5 comes equipped with tamper-evident labels. The Verifone Carbon Mobile 5 unit contains no user serviceable parts. Do not, under any circumstance, attempt to disassemble the device. Perform only those adjustments or repairs specified in this guide. For all other services, contact your local Verifone service provider. Service conducted by parties other than authorized Verifone representatives may void any warranty. CAUTION Before troubleshooting, ensure that the power supply being used to power the device matches the requirements specified at the bottom of the device. (See Specifications, for detailed power supply specifications.) Obtain the appropriately rated power supply before continuing with troubleshooting. Device Does Not Start Device Display Does Not Show Correct/

Readable Info

Ensure that the battery charge state is not below the critically low level.

Recharge the battery.

Connect the Verifone Carbon Mobile 5 into a known-good power supply (if

available) to see if this clears the problem. If the problem persists, contact your local Verifone representative for assistance. CARBON MOBILE 5 INSTALLATION GUIDE 35 TROUBLESHOOTING GUIDELINES Battery Does Not Charge Battery Does Not Charge The Verifone Carbon Mobile 5 battery must initially receive a full charge to ensure proper operation. NOTE

Allow the Verifone Carbon Mobile 5 device to remain connected to the power

pack for eight hours to ensure the battery receives a full charge. Li-Polymer and Li-Ion batteries are not affected by shallow charging. Furthermore, when the device has no external power source or battery the coin cell battery provides power to the security circuit.

Disconnecting and unplugging the device power pack reduce the life of the coin cell battery, which does not recharge and must be replaced if drained.

Conserve battery power by turning the Verifone Carbon Mobile 5 device off when not in use. Do not let the battery charge fall below 10% for extended periods of time as this may permanently diminish the battery capacity. Recharge the battery by attaching USB end of the power pack to the device and plugging the other end of the power pack into a wall outlet. The Verifone Carbon Mobile 5 device automatically shuts off when the battery reaches the critically low charge state.

Please charge the device once a week even when the device is not in use. Blank Display When the Verifone Carbon Mobile 5 device display screen does not show correct or clearly readable information:

When the battery connection has some connection issue.

Connect to the charger.

If the problem persists, contact your local Verifone service provider. If the display doesn't turn on, press and hold the power key for 8-10 seconds. Transactions Fail to Process There are several reasons why the device may not be processing transactions. Use the following steps to troubleshoot failures. Check the Magnetic Card Reader

Perform a test transaction using one or more different magnetic stripe cards to ensure the problem is not a defective card.

Ensure that you are swiping cards properly. With the Verifone Carbon Mobile 5 card reader, the black magnetic stripe on the card should face down and outward (see Figure 7).

Process a transaction manually. If the manual transaction works, the problem may be a defective card reader.

Contact your Verifone distributor or service provider. 36 CARBON MOBILE 5 INSTALLATION GUIDE TROUBLESHOOTING GUIDELINES Transactions Fail to Process CARBON MOBILE 5 INSTALLATION GUIDE 37 APPENDIX 7 Caution and Warning Messages Verifone Carbon Mobile 5 Caution and Warning Messages Products with UL/cUL certification include French translations of Caution and Warning notices. The following table lists all notices found in the document, their location and the equivalent French translations. Table 1 Notice Caution Caution and Warning Messages Chapter English Text Setup Page page 12 Warning Setup page 13 Caution Setup page 15 The terminal is not waterproof or dustproof, and is intended for indoor use only. Any damage to the unit from exposure to rain or dust may void any warranty. Do not use a unit that has been tampered with or otherwise damaged. This unit comes equipped with tamper-evident labels. If a label or component appears damaged, immediately notify the shipping company and your Verifone representative or service provider. Observe standard precautions when handling electrostatically sensitive devices. Electrostatic discharges can damage this equipment. Verifone recommends using a grounded anti-static wrist strap. French Text Le terminal est pas tanche ou la poussire, et est destin une utilisation en intrieur. Tout dommage l'unit de l'exposition la pluie ou la poussire peut annuler la garantie. Ne pas utiliser une unit qui a t altr ou endommag. Cet appareil est quip d' tiquettes inviolables. Si une tiquette ou d'un composant semble endommag, avertissez immdiatement la compagnie de navigation et votre reprsentant ou du prestataire de services Verifone. Respecter les prcautions standard lors de la manipulation des appareils sensibles aux dcharges lectrostatiques. Les dcharges lectrostatiques peuvent endommager cet quipement. Verifone recommande d'utiliser un bracelet anti-

statique la terre. CARBON MOBILE 5 INSTALLATION GUIDE 38 CAUTION AND WARNING MESSAGES Verifone Carbon Mobile 5 Caution and Warning Messages Table 1 Notice Caution Caution and Warning Messages (continued) English Text Chapter Setup Page page 15 Using an incorrectly rated power supply may damage the terminal or cause it not to work as specified. Before troubleshooting, ensure that the power supply being used to power the terminal matches the requirements specified on the bottom of the terminal. (See Specifications, for detailed power supply specifications.) Obtain the appropriately rated power supply before continuing with troubleshooting. Do not plug the power pack into an outdoor outlet or operate the terminal outdoors. Disconnecting the power during a transaction may cause transaction data files not yet stored in terminal memory to be lost. To protect against possible damage caused by lightning strikes and electrical surges, consider installing a power surge protector. Do not dispose batteries in a fire. Li-Polymer and Li-Ion batteries must be recycled or disposed of properly. Do not dispose Li-ion batteries in municipal waste sites. Never use thinner, trichloroethylene, or ketone-based solvents they can deteriorate plastic or rubber parts. Avoid touching the contacts of the Verifone Carbon Mobile 5 battery. Finger oils tarnish contacts, causing bad connections. When operating on battery power and experiencing a high occurrence of bad or incomplete data transfers, clean the contacts. French Text Utilisation d'une alimentation mal class peut endommager le terminal ou de l'empcher de travailler comme spcifi. Avant de dpannage, assurez-vous que l'alimentation est utilis pour alimenter le terminal correspond aux exigences spcifies sur le fond de la borne. (Voir le, Caractristiques, pour les caractristiques de l'alimentation.) Obtenir l'alimentation nominale approprie avant de continuer avec le dpannage. Ne pas brancher le bloc d'alimentation une prise extrieure ou exploiter le terminal l'extrieur. Dconnexion de l' alimentation lors d'une transaction peut entraner des fichiers de donnes de transaction non encore stockes dans la mmoire terminal pour tre perdu. Pour se protger contre de possibles dommages causs par la foudre et les surtensions lectriques, pensez installer un protecteur de surtension. Ne jetez pas les batteries au feu. Les batteries Li-ion doivent tre recycles ou limines correctement. Ne jetez pas les batteries Li-ion dans les sites de dchets municipaux. Ne jamais utiliser de diluant, le trichlorthylne ou des solvants base de ctone - ils peuvent dtriorer les pices en plastique ou en caoutchouc. vitez de toucher les contacts de la batterie Verifone Carbon Mobile 5. Les huiles de doigt ternissent les contacts, provoquant de mauvaises connexions. Lorsque vous utilisez une batterie et que la transmission de donnes est incorrecte ou incomplte, nettoyez les contacts. Warning Setup page 15 Warning Setup Page 16 Caution Maintenance and Cleaning page 23 Caution Maintenance and Cleaning page 23 39 CARBON MOBILE 5 INSTALLATION GUIDE CAUTION AND WARNING MESSAGES Verifone Carbon Mobile 5 Caution and Warning Messages Table 1 Notice Caution Caution and Warning Messages (continued) English Text Chapter Troubleshooting Guidelines Page Page 27 Caution Troubleshooting Guidelines Page 27 Using an incorrectly rated power supply may damage the unit or cause it to not work properly. Before troubleshooting, ensure that the power supply used to power the unit matches the specified requirements (see Specifications for detailed power supply specifications). If not, obtain the appropriately rated power supply before continuing with troubleshooting. Before troubleshooting, ensure that the power supply being used to power the device matches the requirements specified at the bottom of the device. (See Specifications, for detailed power supply specifications.) Obtain the appropriately rated power supply before continuing with troubleshooting. French Text Utilisation d'une alimentation mal class peut endommager l'appareil ou provoquer sa ne fonctionne pas correctement. Avant de dpannage, assurez-vous que l'alimentation utilise pour alimenter l'unit correspond aux exigences spcifies (voir spcifications pour les caractristiques de l'alimentation ). Si non, obtenir l'alimentation nominale approprie avant de continuer avec le dpannage. CARBON MOBILE 5 INSTALLATION GUIDE 40 CAUTION AND WARNING MESSAGES Verifone Carbon Mobile 5 Caution and Warning Messages 41 CARBON MOBILE 5 INSTALLATION GUIDE Verifone, Inc. 1-800-Verifone www.verifone.com Carbon Mobile 5 Installation Guide Verifone Part Number DOC278-003-EN-A, Revision A

 

 

Verifone, Inc. 1-800-Verifone www.verifone.com Separate Power Sources Before you connect the terminal power pack to an electrical outlet, check that the on/off power switch on the terminal is off. If the terminal does not have an on/off switch, check that the power cable connector is removed from the terminal's power port. Or, when connecting the terminal to a power pack, always connect the plug of the power pack to an electrical wall outlet first. Then connect the power cable to the terminal's power port. The reference input power rating are as follows:

Input Voltage: 100-240 V AC, 50/60 Hz Output Voltage: 5 V DC, 2 A

Model CM5/CM5P/CM5W/CM5PW is intended to be provided with appropriately certified power module suitable for the destination country with an output rating of 5 VDC, 2 A and evaluated as a Limited Power Source, output rated SELV, non-energy hazardous. Suitability of power module subject to auditing agency's discretion. AC Adapter The AC adapter is designed to ensure your personal safety and to be compatible with this equipment. Please follow these guidelines:

Do not use the adapter in a high moisture environment. Never tough the adapter when your hands or feet are wet. Allow adequate ventilation around the adapter. Avoid locations with restricted airflow. Connect the adapter to a proper power source. The voltage and grounding requirements are found on the product case and/or packaging. Do not use the adapter if the cord becomes damaged. Do not attempt to service the adapter. There are no serviceable parts inside. Replace the unit if it is damaged or exposed to excess moisture. Disconnecting Power Disconnecting power during a transaction may cause transaction data files that are not yet stored in terminal memory to be lost. Location Electrical Considerations WARNING!

This device contains sensitive electronic components that can be permanently damaged if exposed to excessive shock, electrical interference or vibration. AVERTISSEMENT! Cet appareil contient des composants lectroniques sensibles qui peuvent tre endommags defaon permanente si elle est expose des chocs CAUTION:

excessifs, des interfrences lectriques ou des vibrations. Due to risk of electrical shock or unit damage, do not use the unit near water, including a bathtub, wash bowl, kitchen sink or laundry tub, in a wet basement, or near a swimming pool. Also, avoid using this product during electrical storms. Avoid locations near electrical appliances or other devices that cause excessive voltage fluctuations or emit electrical noise (for example, air conditioners, neon signs, high-frequency or magnetic security devices, or electric motors). ATTENTION: Du fait d'un risque d'lectrocution ou d'une dtrioration du terminal, ne pas utiliser cet quipement prs d'une source d'eau, par exemple prs d'une baignoire, d'un lavabo, d'un vier de cuisine ou d'un bac de lavage, dans un sous-sol humide ou proximit d'une piscine. De mme, viter dutiliser ce produit lors des orages provoquant des coupures lectriques. viter de placer le terminal proximit dappareils lectriques ou autres units pouvant entraner des fluctuations de tension importantes ou des interfrences lectriques, tels que les climatiseurs, enseignes au non, dispositifs de scurit haute frquence ou quipements lectriques. Equipment Damage Carefully inspect the shipping carton and its contents for any damage. If the unit or any product component appears damaged or to have been tampered with, immediately notify the shipping company and your Verifone distributor or service provider. Do not use a Verifone Carbon Mobile 5 unit that has been tampered. Repairs Do not, under any circumstances, attempt any service, adjustments, or repairs on this equipment. Instead, contact your local Verifone distributor or service provider for assistance. Failure to comply may void the product warranty. Location Environmental Considerations Do not plug the power pack into an outdoor outlet or operate the terminal outdoors. It is not waterproof or dustproof and is for indoor use only. Any damage to the unit from exposure to rain or dust may void your warranty. Do not use the terminal where there is high heat, dust, humidity, moisture, or caustic chemicals or oils. Keep the terminal away from direct sunlight and anything that radiates heat, such as a stove or a motor. WARNING!

Your POS Terminal contains sensitive electronic components that can be permanently damaged if exposed to excessive shock or vibration. To minimize the risk of damage to your Terminal, avoid dropping your Terminal and operating it in high-shock and high-vibration environments. Do not store the Terminal where prolonged exposure to extreme temperature can occur, because it can cause permanent damage. Do not expose the Terminal to water. Contact with water can cause this unit to malfunction. AVERTISSEMENT !Votre terminal de point de vente contient des composants lectroniques sensibles, susceptibles de subir des dommages dfinitifs en cas d'exposition des chocs ou des vibrations excessives. Pour minimiser le risque de dommages pour votre terminal, viter de le faire tomber ou de l'exposer des environnements pouvant provoquer des chocs et des vibrations excessives. Ne pas stocker le terminal dans des lieux susceptibles d'entraner une exposition prolonge des tempratures extrmes, du fait des dommages dfinitifs que cette situation peut provoquer. Ne pas exposer le terminal l'eau. Un contact avec de l'eau peut provoquer un dysfonctionnement de l'unit. Cleaners and Solvents Never use thinner, trichloroethylene or ketone-based solvents to clean the Verifone Carbon Mobile 5 these may deteriorate plastic or rubber parts. Do not spray cleaners or other solutions directly onto the keypad or display. For best results, use a clean cloth dampened with water and mild soap. To remove stubborn stains, use alcohol or an alcohol-based cleaner. Battery Pack Instruction for Portable Product Dispose of the battery pack in accordance with all national, state, and local laws and regulations as regionally required. Some batteries may be recycled and may be accepted for disposal at local recycling centers. CAUTION:

ATTENTION:

There is risk of explosion if the battery is replaced by an incorrect type. Il y a risque d'explosion si la batterie est remplace par un type incorrect. Verifone Carbon Mobile 5 Certifications and Regulations Verifone Part Number: DOC278-001-EN-C Revision C.1

*DOC278-001-EN-C*

2019 Verifone, Inc. All rights reserved. Verifone Carbon Mobile 5 Certifications and Regulations FCC Compliance The following product has been tested and certified as compliant with the regulations and guidelines detailed below:

Manufacturer: Verifone, Inc. Brand, Model: CM5, CM5P, CM5W, CM5PW Part 15 of FCC Rules This device complies with the limits for a Class B digital device as specified in Part 15 of FCC Rules which provide reasonable protection against harmful interference in a residential installation. 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. 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. In the unlikely event that there is 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 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. This device and its antenna(s) must not be co-located or operating in conjunction with any other antenna or transmitter. Use of a shielded interface cable is required to comply with the Class B limits of Part 15 of FCC Rules. Any changes or modifications to this equipment not expressly approved by Verifone could void the user's authority to operate this equipment. NOTE: The country code selection is for non-US models only and is not available for all US models. Per FCC regulation, all Wi-Fi products marketed in the US must be fixed to US operational channels only. RF Exposure USA The product comply with the FCC portable RF exposure limit set forth for an uncontrolled environment and are safe for intended operation as described in This device meets the governments requirements for exposure to radio waves. This device is designed and manufactured not to exceed the emission limits this manual. The further RF exposure reduction can be achieved if the product can be kept as far as possible from the user body or set the device to lower for exposure to radio frequency (RF) energy set by the Federal Communications Commission of the U.S. Government. The exposure standard for wireless device employs a unit of measurement known as the Specific Absorption Rate, or SAR. The SAR limit set by the FCC is output power if such function is available. 1.6W/kg for body SAR and 4W/kg for extremity SAR. *Tests for SAR are conducted using standard operating positions accepted by the FCC with the device transmitting at its highest certified power level in all tested frequency bands. To maintain compliance with FCC RF exposure guidelines, if you wear this device on your body when transmitting, always place the device in a Verifone supplied or approved clip, holder, holster, case or body harness for this product. Use of non-Verifone approved accessories may not maintain compliance with FCC RF exposure guidelines. If you do not use one of the Verifone supplied or approved body-worn accessories and are not using the device held in the normal use position, ensure that the device is at least 15 mm from your body when transmitting. This device complies with SAR for general population/uncontrolled exposure limits in ANSI/IEEE C95.1-1999 and has been tested in accordance with the measurement methods and procedures specified in OET Bulletin 65 Supplement C. CE This device complies with the Radio Equipment Directive (2014/53/EU) issued by the Commission of the European Community. A minimum separation distance of 0 cm must be maintained between the users body and the device, including the antenna during body-worn operation to comply with the RF exposure requirements in Europe. Notice for Operating Frequency and Output Power NFC:-6.10dBA /m at 10m WLAN (2.4G):802.11b/g/n20, 15.85dBm;14.92dBm; 14.15dBm WLAN (5G):802.11a/n20/n40, 12.3dBm; 12.25dBm;11.5dBm WLAN (BT): EDR/LE, 9.09dBm; 3.71Bm 2G:GSM900/GSM1800, 33dBm, 30dBm 3G (UMTS/WCDMA):Band I/Band VIII, 24dBm 4G(LTE): Band 1/3/5/7/8/20/38/40/41, 23dBm Notice for WLAN For 5G Band (WLAN:5150-5350 MHz) This device is restricted for indoor use only when operating in the 5150 to 5350 MHz frequency range. Legal Terms and Conditions Regarding PCI SSC Approvals PCI SSC's approval only applies to PEDs that are identical to the PED tested by a PCI Security Standards Council recognized laboratory. If any aspect of the PED is different from that which was tested by the laboratory - even if the PED conforms to the basic product description contained in the letter, then the PED model should not be considered approved, nor prompted as approved. For example, if a PED contains firmware, software, or physical construction that has the same name or model number as those tested by the laboratory, but in fact are not identical to those PED samples tested by the laboratory, then the PED should not be considered or promoted as approved. No vendor or other third party may refer to a PED as "PCI Approved," nor otherwise state or imply that PCI SSC has, in whole or part, approved any aspect of a vendor or its PEDs, except to the extent and subject to the terms and restrictions expressly set forth in a written agreement with PCI SSC, or in an approval letter. All other references to PCI SSC's approval are strictly and actively prohibited by PCI SSC. When granted, an approval is provided by PCI SSC to ensure certain security and operational characteristics important to the achievement of PCI SSC's goals, but the approval does not under any circumstances include any endorsement or warranty any products or services provided by third parties. Approval does not, under any circumstances, include or imply any product warranties from PCI SSC, including, without limitation, any implied warranties of merchantability, fitness for purpose or noninfringement, all of which are expressly disclaimed by PCI SSC. All rights and remedies regarding products and services, which have received an approval, shall be provided by the party providing such products or services, and not by PCI SSC or the payment brand participants. Operating temperature The product is designed to use at the maximum ambient temperature (Tma) permitted by the manufacturers specification of: 50 C. Recycling: DO NOT DISCARD!

UNIT MUST BE RECYCLED OR DISPOSED OF PROPERLY For proper disposal instructions, go to http://recycle.verifone.com reference. continued on rear cover Recyclage: NE PAS JETER!

L'unit doit tre recycle ou mise au rebut dans les endroits prvus cet effet. Pour connatre les procdures de mise au rebut, consultez le site http://recycle.verifone.com suite au verso Please retain this sheet for future conserver pour rfrence ultrieure. E u r o p e a n c o n a c t f t o r r e g u a l t o r y t i o p c s o n y

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VeriFone Systems Pte Ltd. Taiwan Branch 2Fl., No. 19-2, Sanchung Road, Nankang Dist. Taipei, Taiwan,11501 R.O.C. Label Location Model: CM5 Brand: Verifone FCC ID: B32CM5P Back side of CM5P Back side of EUT-

underneath of battery compartment

 

 

E132144 FCC ID:B32CM5P IC:

BC R-NZ LBL278-511-03-A FCC ID:B32CM5P KIM_H4 LBL278-511-03-AW A00 LABEL CM5P PROD ID 3/11/19 3/11/19 3/11/19 2X A00 XXXXX 3/11/19 KIM_H4

 

 

Date: 2019-03-19 FCC ID: B32CM5P AUTHORIZATION LETTER To Whom It May Concern:

VeriFone Inc hereby authorizes Joanna Hung / Specialist of Bureau Veritas Consumer Products Services (H.K.) Ltd., Taoyuan Branch (BV CPS Taoyuan), to act on its behalf in all matters relating to the Federal Communication Commission (FCC) application for equipment authorization in connection with the FCC ID listed above, including signing of all documents relating to these matters. Any and all acts carried out by Joanna Hung / Specialist of BV CPS Taoyuan on VeriFone Incs behalf, within the scope of the powers granted herein, shall have the same effect as acts of its own. If you have any questions regarding the authorization, please dont hesitate to contact us. Sincerely yours, ___ Don Perkins Director, Engineering, R & D Verifone, Inc. Tel.: 916-625-1833 Fax: 916-625-1800 E-mail: Don_P3@verifone.com Verifone, Inc. | 1400 West Stanford Ranch Road Suite 200 | Rocklin CA 95765 | USA

(t) 916-625-1833 | (f) 916-625-1800 | www.verifone.com

 

 

Date: March 19, 2019 Declaration To whom it may concern, This is a WLAN/Bluetooth combination antenna with FCC ID: B32CM5P. This WLAN/Bluetooth co-existence mechanism is to ensure that the WLAN and Bluetooth transmitters would not simultaneously operate. Therefore, WLAN and Bluetooth antenna in FCC ID: B32CM5P should not be considered to be able to transmit Though the users can use WLAN and Bluetooth simultaneously, but the real situation is that WLAN and Bluetooth are used by time sharing and no overlap Should you have any question, please have my best attention. simultaneously. transmission. Sincerely yours, ____________________________ Don Perkins Director, Engineering, R & D Verifone, Inc. Tel.: 916-625-1833 Fax: 916-625-1800 E-mail: Don_P3@verifone.com Verifone, Inc. | 1400 West Stanford Ranch Road Suite 200 | Rocklin CA 95765 | USA

(t) 916-625-1833 | (f) 916-625-1800 | www.verifone.com

 

 

Date: March 19, 2019 Label Location Declaration We, Verifone, Inc., state that there is no other space for putting the label on our device, FCC ID: B32CM5P, except for the space of the battery compartment of this device. The label will be put under the battery compartment and it is visible to the users as they purchase the product and install the battery. If you have any question regarding the declaration, please dont hesitate to contact us. Thank you!

Sincerely yours, ____________________________ Don Perkins Director, Engineering, R & D Verifone, Inc. Tel.: 916-625-1833 Fax: 916-625-1800 E-mail: Don_P3@verifone.com Verifone, Inc. | 1400 West Stanford Ranch Road Suite 200 | Rocklin CA 95765 | USA

(t) 916-625-1833 | (f) 916-625-1800 | www.verifone.com

 

 

Date: March 19, 2019 To: Federal Communications Commission 7435 Oakland Mills Road Columbia, MD FCC ID: B32CM5P To Whom It May Concern:

This letter is to ascertain that Verifone, Inc. Product Point of Sale Terminal has been the unit(s) used for conducting FCC compliance testing. The SDoC portion has been conducted in accordance with FCC SDoC requirement as per Section 2.1077 compliance information. Supplier's Declaration of Conformity 47 CFR 2.1077 Compliance Information Unique Identifier: (Verifone, CM5) Responsible Party U.S. Contact Information Verifone., Inc. 1400 West Stanford Ranch Road, Suite 200 Rocklin, CA 95765 1-916-625-1833 FCC Compliance Statement (e.g., products subject to Part 15) 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. Sincerely, Don Perkins Director, Engineering, R & D Verifone, Inc. Tel.: 916-625-1833 Fax: 916-625-1800 E-mail: Don_P3@verifone.com Verifone, Inc. | 1400 West Stanford Ranch Road Suite 200 | Rocklin CA 95765 | USA

(t) 916-625-1833 | (f) 916-625-1800 | www.verifone.com

 

 

 

 

 

 

Third Party Confidentiality Letter FCC Laboratory 7435 Oakland Mills Road Columbia, MD 21046 Date2019-04-16 Subject: Third Party Confidentiality Request for Exhibits To Whom It May Concern:

Pursuant of Section 0.457 and 0.459 of the Commissions Rules and KDB 726920 D01 Confidentiality Request Procedures, we hereby request that the exhibits listed below, submitted in support of the certification application, be withheld permanently from public disclosure:

Exhibit Type Document Number or Name File Name Schematics Parts List Schematics BOM Block Diagram Block Diagram n/a Version/ or Revision Version 1.1 Version 1.1 SC20-A_SCH_V1.1-20190401 SC20-AU_V1.1_BOM(BOM21)190221-

TOC CERT 4. SC20-AU Block The above exhibits, owned solely by Quectel Wireless Solutions Co., Ltd., contain trade secrets and proprietary information not customarily release to the public. The public disclosure of these materials may be harmful to Quectel Wireless Solutions Co., Ltd. and provide unjustified benefits to its competitors. Verifone Inc. is authorized to reference these exhibits in its application but not authorized to access them. Timco Engineering, Inc., as a TCB, is authorized to access these exhibits and include them in the filing under permanent confidentiality. Best Regards, Signature Signees Printed Name Johnny Xiang Title Director Page 1 of 1

 

 

FCC Laboratory 7435 Oakland Mills Road Columbia, MD 21046 Date: 2019-04-25 Subject: Confidentiality Request for Exhibits under FCC ID: B32CM5P To Whom It May Concern:

Pursuant of Section 0.457 and 0.459 of the Commissions Rules and KDB 726920 D01 Confidentiality Request Procedures, we hereby request that the exhibits listed below, submitted in support of the certification application for FCC ID: B32CM5P, be withheld permanently from public disclosure. Exhibit Type File Name Document Number or Name Operational Description Operational Description Tune up Procedure Tune up Procedure Software Operation Software Operation Description Block Diagram Schematics Description Block Diagram Schematics Operational Description rev Tune up Procedure Software Operation Description E500 Block Diagram v1.12_CM5 & CM5P CM5P_PCA278-Sch_20190311 Parts List Parts List This request includes third party confidentiality for items not allowed to be accessed by Verifone. The below third party and its confidentiality documents are listed as below:

Documents only accessible by Quectel:

Exhibit Type Document Number or Name CM5P_BOM_20190326 File Name Version/

or Revision Rev NA NA NA NA NA Block Diagram module Schematics Schematics Parts List module Block Diagram module Part List Version/ or Revision NA NA NA 4. SC20-AU Block SC20-A_SCH_V1.1-20190401 SC20-AU_V1.1_BOM(BOM21)190221-

TOC CERT The above materials contain trade secrets and proprietary information not customarily released to the public. The public disclosure of these materials may be harmful to the applicant and provide unjustified benefits to its competitors. The applicant understands that pursuant to Section 0.457 of the Rules, disclosure of this application and all accompanying documentation will not be made before the date of the Grant for this application. Don Perkins/Director, Engineering, R & D ___ Verifone, Inc. Tel.: 916-625-1833 Fax: 916-625-1800 E-mail: Don_P3@verifone.com Verifone, Inc. | 1400 West Stanford Ranch Road Suite 200 | Rocklin CA 95765 | USA

(t) 916-625-1833 | (f) 916-625-1800 | www.verifone.com Page 1 of 1

 

 

DFS client device channel plan and software operational declaration We, Verifone, Inc., declare that the device, FCC ID: B32CM5P, does not have Ad Hoc on non-US frequencies and/or on DFS frequencies. Also, the client software and associated drivers will not initiate any transmission on DFS frequencies without initiation by a master. This includes restriction on transmissions for beacons and support for ad-hoc peer-to-peer modes. Scan Type CH Scan Type CH Scan Type CH Scan Type CH Scan Type CH Below is the channel / frequency plan for the device 5 CH 1 3 Frequency (MHz) Frequency (MHz) 2 4 2422 2417 11 2412 2462 Active Active Active Active Active Active Active Active Active Active Active 58 5290 Active Active Active Active Active Active Active Passive Passive Passive Passive 38 5190 36 5180 40 5200 42 5210 52 5260 44 5220 46 5230 48 5240 54 5270 56 5280 10 2457 2437 2442 2447 2432 2427 2452 9 6 7 8 Frequency (MHz) 60 5300 64 5320 Passive Passive Passive 62 5310 Frequency (MHz) 100 5500 122 5610 Passive Passive Passive Passive Passive Passive Passive Passive Passive Passive Passive 110 5550 112 5560 116 5580 120 5600 102 5510 104 5520 108 5540 106 5530 118 5590 Frequency (MHz) Frequency (MHz) Scan Type 124 5620 126 5630 128 5640 132 5660 134 5670 136 5680 138 5690 140 5700 142 5710 144 5720 Passive Passive Passive Passive Passive Passive Passive Passive Passive Passive 165 5825 Active Active Active Active Active Active Active Active 159 5795 161 5805 151 5755 149 5745 153 5765 157 5785 155 5775 Also, on DFS channels, the WLAN driver in the device operates under the control of an AP at all times, except when in ad-hoc mode, on US non-DFS channels. The device passively scans DFS frequencies until a master device is detected. The control of this functionality is not accessible to anyone under any conditions. Furthermore, the firmware is protected by special signature and CRC checksum. Signature and CRC checksum will be calculated and verified before firmware upgrade. Unauthorized modification to firmware will lead the failure of verification thus firmware upgrade is not allowed. Sincerely yours, _____________________ Don Perkins Director, Engineering, R & D Verifone, Inc. Tel.: 916-625-1833 Fax: 916-625-1800 E-mail: Don_P3@verifone.com Verifone, Inc. | 1400 West Stanford Ranch Road Suite 200 | Rocklin CA 95765 | USA

(t) 916-625-1833 | (f) 916-625-1800 | www.verifone.com

 

 

Date: March 19, 2019 Declaration We, Verifone, Inc., declare that the device, FCC ID: B32CM5P, does not support any non-US channels in all the operational mode(s). All non-US frequencies, US 2.4G channel 12-13 and Country code selection are disabled through proprietary software and are not user changeable. Should you have any question or comment regarding this matter, please do not hesitate to contact me. Sincerely yours, ____________________________ Don Perkins Director, Engineering, R & D Verifone, Inc. Tel.: 916-625-1833 Fax: 916-625-1800 E-mail: Don_P3@verifone.com Verifone, Inc. | 1400 West Stanford Ranch Road Suite 200 | Rocklin CA 95765 | USA

(t) 916-625-1833 | (f) 916-625-1800 | www.verifone.com