HL8518_1103928

Product Technical Specification AirPrime HL8518, HL8528 and HL8529 4117047 2.1 December 10, 2015 Product Technical Specification Important Notice Due to the nature of wireless communications, transmission and reception of data can never be guaranteed. Data may be delayed, corrupted (i.e., have errors) or be totally lost. Although significant delays or losses of data are rare when wireless devices such as the Sierra Wireless modem are used in a normal manner with a well-constructed network, the Sierra Wireless modem should not be used in situations where failure to transmit or receive data could result in damage of any kind to the user or any other party, including but not limited to personal injury, death, or loss of property. Sierra Wireless accepts no responsibility for damages of any kind resulting from delays or errors in data transmitted or received using the Sierra Wireless modem, or for failure of the Sierra Wireless modem to transmit or receive such data. Safety and Hazards Do not operate the Sierra Wireless modem in areas where cellular modems are not advised without proper device certifications. These areas include environments where cellular radio can interfere such as explosive atmospheres, medical equipment, or any other equipment which may be susceptible to any form of radio interference. The Sierra Wireless modem can transmit signals that could interfere with this equipment. Do not operate the Sierra Wireless modem in any aircraft, whether the aircraft is on the ground or in flight. In aircraft, the Sierra Wireless modem MUST BE POWERED OFF. When operating, the Sierra Wireless modem can transmit signals that could interfere with various onboard systems. Note: Some airlines may permit the use of cellular phones while the aircraft is on the ground and the door is open. Sierra Wireless modems may be used at this time. The driver or operator of any vehicle should not operate the Sierra Wireless modem while in control of a vehicle. Doing so will detract from the driver or operator’s control and operation of that vehicle. In some states and provinces, operating such communications devices while in control of a vehicle is an offence. Limitations of Liability This manual is provided “as is”. Sierra Wireless makes no warranties of any kind, either expressed or implied, including any implied warranties of merchantability, fitness for a particular purpose, or noninfringement. The recipient of the manual shall endorse all risks arising from its use. The information in this manual is subject to change without notice and does not represent a commitment on the part of Sierra Wireless. SIERRA WIRELESS AND ITS AFFILIATES SPECIFICALLY DISCLAIM LIABILITY FOR ANY AND ALL DIRECT, INDIRECT, SPECIAL, GENERAL, INCIDENTAL, CONSEQUENTIAL, PUNITIVE OR EXEMPLARY DAMAGES INCLUDING, BUT NOT LIMITED TO, LOSS OF PROFITS OR REVENUE OR ANTICIPATED PROFITS OR REVENUE ARISING OUT OF THE USE OR INABILITY TO USE ANY SIERRA WIRELESS PRODUCT, EVEN IF SIERRA WIRELESS AND/OR ITS AFFILIATES HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES OR THEY ARE FORESEEABLE OR FOR CLAIMS BY ANY THIRD PARTY. Notwithstanding the foregoing, in no event shall Sierra Wireless and/or its affiliates aggregate liability arising under or in connection with the Sierra Wireless product, regardless of the number of events, occurrences, or claims giving rise to liability, be in excess of the price paid by the purchaser for the Sierra Wireless product. Customer understands that Sierra Wireless is not providing cellular or GPS (including A-GPS) services. These services are provided by a third party and should be purchased directly by the Customer. 4117047 Rev 2.1 December 10, 2015 2 Product Technical Specification SPECIFIC DISCLAIMERS OF LIABILITY: CUSTOMER RECOGNIZES AND ACKNOWLEDGES SIERRA WIRELESS IS NOT RESPONSIBLE FOR AND SHALL NOT BE HELD LIABLE FOR ANY DEFECT OR DEFICIENCY OF ANY KIND OF CELLULAR OR GPS (INCLUDING A-GPS) SERVICES. Patents This product may contain technology developed by or for Sierra Wireless Inc. This product includes technology licensed from QUALCOMM®. This product is manufactured or sold by Sierra Wireless Inc. or its affiliates under one or more patents licensed from InterDigital Group and MMP Portfolio Licensing. Copyright © 2015 Sierra Wireless. All rights reserved. Trademarks Sierra Wireless®, AirPrime®, AirLink®, AirVantage®, WISMO®, ALEOS® and the Sierra Wireless and Open AT logos are registered trademarks of Sierra Wireless, Inc. or one of its subsidiaries. Watcher® is a registered trademark of NETGEAR, Inc., used under license. Windows® and Windows Vista® are registered trademarks of Microsoft Corporation. Macintosh® and Mac OS X® are registered trademarks of Apple Inc., registered in the U.S. and other countries. QUALCOMM® is a registered trademark of QUALCOMM Incorporated. Used under license. Other trademarks are the property of their respective owners. Contact Information Sales Desk: Post: Technical Support: RMA Support: Fax: Web: Phone: 1-604-232-1488 Hours: 8:00 AM to 5:00 PM Pacific Time Contact: http://www.sierrawireless.com/sales Sierra Wireless 13811 Wireless Way Richmond, BC Canada V6V 3A4 support@sierrawireless.com repairs@sierrawireless.com 1-604-231-1109 http://www.sierrawireless.com/ Consult our website for up-to-date product descriptions, documentation, application notes, firmware upgrades, troubleshooting tips, and press releases: www.sierrawireless.com 4117047 Rev 2.1 December 10, 2015 3 Product Technical Specification Document History Version Date Updates 1.0 May 20, 2015 Creation 1.1 May 29, 2015 Updated:  1 Introduction  2 Pad Definition  Table 32 26Mhz Clock Interface Pin Description  Table 54 Ordering Information Deleted 4.1 Model Views Added 8 Conformance with ATEX 2.0 December 02, 2015 Updated:  Table 1 Supported Bands/Connectivity  1.2 Physical Dimensions  Table 2 General Features  Table 3 ESD Specifications  1.9 Environmental and Certifications  2 Pad Definition  Table 8 Power Supply  3.4 Current DC Power Consumption  4 Mechanical Drawings  6 Reliability Specification  7 Legal Information  Table 54 Ordering Information Deleted HSIC 2.1 4117047 December 10, 2015 Updated Table 11 Current Consumption Rev 2.1 December 10, 2015 4 Contents 1. INTRODUCTION ................................................................................................ 11 1.1. Common Flexible Form Factor (CF3) ..............................................................................11 1.2. Physical Dimensions .......................................................................................................12 1.3. General Features .............................................................................................................12 1.4. Encryption Support ..........................................................................................................15 1.5. Architecture .....................................................................................................................15 1.6. Interfaces .........................................................................................................................16 1.7. Connection Interface .......................................................................................................16 1.8. ESD .................................................................................................................................17 1.9. Environmental and Certifications .....................................................................................17 1.9.1. Environmental Specifications ...................................................................................17 1.9.2. Regulatory ................................................................................................................18 1.9.3. RoHS Directive Compliant .......................................................................................19 1.9.4. Disposing of the Product ..........................................................................................19 1.10. References ......................................................................................................................19 2. PAD DEFINITION ............................................................................................... 20 2.1. Pin Types .........................................................................................................................24 2.2. Pin Configuration (Top View, Through Module) ..............................................................25 3. DETAILED INTERFACE SPECIFICATIONS ..................................................... 26 3.1. Power Supply ..................................................................................................................26 3.1.1. Electrical Characteristics ..........................................................................................26 3.1.2. Pin Description .........................................................................................................26 3.1.3. Burst Transmission Current Requirements ..............................................................27 3.1.4. Power Input (VBATT) ...............................................................................................28 3.2. Ground Connection .........................................................................................................28 3.3. Decoupling of Power Supply Signals ..............................................................................28 3.4. Current DC Power Consumption .....................................................................................29 3.5. VGPIO .............................................................................................................................31 3.5.1. Electrical Characteristics ..........................................................................................31 3.5.2. Pin Description .........................................................................................................31 3.6. BAT_RTC ........................................................................................................................31 3.6.1. Electrical Characteristics ..........................................................................................32 3.6.2. Pin Description .........................................................................................................32 3.7. SIM Interface ...................................................................................................................32 3.7.1. Electrical Characteristics ..........................................................................................33 3.7.2. Pin Description .........................................................................................................33 3.7.3. UIM1_DET................................................................................................................34 3.7.4. Application ................................................................................................................34 4117047 Rev 2.1 December 10, 2015 5 Product Technical Specification 3.8. USB .................................................................................................................................35 3.8.1. Electrical Characteristics ..........................................................................................35 3.8.2. Pin Description .........................................................................................................35 3.9. Electrical Information I/O .................................................................................................35 3.10. General Purpose Input/Output (GPIO) ............................................................................36 3.11. Main Serial Link (UART1) ................................................................................................37 3.11.1. Pin Description .........................................................................................................37 3.11.2. 8-wire Application .....................................................................................................38 3.11.3. 4-wire Application .....................................................................................................38 3.11.4. 2-wire Application .....................................................................................................38 3.12. POWER ON Signal (PWR_ON_N) ..................................................................................39 3.13. Reset Signal (RESET_IN_N) ..........................................................................................39 3.14. ADC .................................................................................................................................40 3.14.1. Electrical Characteristics ..........................................................................................40 3.14.2. Pin Description .........................................................................................................40 3.15. PWM ................................................................................................................................41 3.15.1. Electrical Characteristics ..........................................................................................41 3.15.2. Pin Description .........................................................................................................41 3.15.3. Application ................................................................................................................42 3.16. Clock Interfaces ...............................................................................................................43 3.16.1. Electrical Characteristics ..........................................................................................43 3.16.2. Pin Description .........................................................................................................43 3.17. PCM .................................................................................................................................43 3.17.1. Electrical Characteristics ..........................................................................................44 3.17.2. PCM Waveforms ......................................................................................................45 3.17.3. PCM Master Mode ...................................................................................................45 3.17.4. PCM Slave Mode .....................................................................................................46 3.17.5. Pin Description .........................................................................................................47 3.18. Debug Interfaces .............................................................................................................47 3.18.1. Debug Port ...............................................................................................................47 3.18.2. JTAG ........................................................................................................................47 3.19. RF Interface .....................................................................................................................48 3.19.1. RF Connection .........................................................................................................48 3.19.2. RF Performances .....................................................................................................49 3.19.3. TX Burst Indicator (2G_TX_ON) ..............................................................................49 4. MECHANICAL DRAWINGS ............................................................................... 51 5. DESIGN GUIDELINES ....................................................................................... 53 5.1. Power-Up Sequence .......................................................................................................53 5.2. Module Switch-Off ...........................................................................................................53 5.3. Emergency Power OFF ...................................................................................................54 5.4. Sleep Mode Management ...............................................................................................54 5.4.1. Using UART .............................................................................................................54 5.4.2. Using USB ................................................................................................................54 4117047 Rev 2.1 December 10, 2015 6 Product Technical Specification 5.5. Power Supply Design ......................................................................................................55 5.6. ESD Guidelines for SIM Card ..........................................................................................55 5.7. ESD Guidelines for USB..................................................................................................56 5.8. Dual SIM Application .......................................................................................................56 5.9. Radio Frequency Integration ...........................................................................................57 6. RELIABILITY SPECIFICATION ......................................................................... 58 6.1. Reliability Compliance .....................................................................................................58 6.2. Reliability Prediction Model .............................................................................................58 6.2.1. Life Stress Test ........................................................................................................58 6.2.2. Environmental Resistance Stress Tests ..................................................................59 6.2.3. Corrosive Resistance Stress Tests ..........................................................................59 6.2.4. Thermal Resistance Cycle Stress Tests ..................................................................60 6.2.5. Mechanical Resistance Stress Tests .......................................................................61 6.2.6. Handling Resistance Stress Tests ...........................................................................62 7. LEGAL INFORMATION ..................................................................................... 63 7.1. FCC Regulations .............................................................................................................63 7.2. IC Regulations .................................................................................................................64 7.3. CE Regulation .................................................................................................................65 8. CONFORMANCE WITH ATEX........................................................................... 66 9. ORDERING INFORMATION .............................................................................. 67 10. TERMS AND ABBREVIATIONS ........................................................................ 68 4117047 Rev 2.1 December 10, 2015 7 List of Figures Figure 1. Architecture Overview ..................................................................................................... 15 Figure 2. Mechanical Overview ...................................................................................................... 16 Figure 3. Pin Configuration ............................................................................................................. 25 Figure 4. Power Supply During Burst Transmission ....................................................................... 27 Figure 5. Power Supply Requirements ........................................................................................... 28 Figure 6. Power Supply Voltage Drops Shapes During Burst Transmission ................................. 29 Figure 7. UIM1 Application Reference Schematic .......................................................................... 34 Figure 8. 8-wire UART Application Example .................................................................................. 38 Figure 9. 4-wire UART Application Example .................................................................................. 38 Figure 10. 2-wire UART Application Example .................................................................................. 38 Figure 11. PWR_ON_N Assertion Time ........................................................................................... 39 Figure 12. Relative Timing for the PWM Output ............................................................................... 41 Figure 13. Example of an LED Driven by either the PWM1 or PWM2 Output ................................. 42 Figure 14. Example of a BUZZER Driven by either the PWM1 or PWM2 Output ............................ 42 Figure 15. PCM Timing Waveform ................................................................................................... 45 Figure 16. PCM Master Mode Timing............................................................................................... 45 Figure 17. PCM Master Mode Timing............................................................................................... 46 Figure 18. JTAG Timing Waveform .................................................................................................. 48 Figure 19. 2G_TX_ON State during TX Burst .................................................................................. 50 Figure 20. Schematic Diagram ......................................................................................................... 51 Figure 21. Footprint .......................................................................................................................... 52 Figure 22. PWR_ON_N Sequence with VGPIO Information ............................................................ 53 Figure 23. PWR_ON_N Sequence with Trampup ................................................................................ 53 Figure 24. Power OFF Sequence for PWR_ON_N, VGPIO ............................................................. 54 Figure 25. Voltage Limiter Example ................................................................................................. 55 Figure 26. EMC and ESD Components Close to the SIM ................................................................ 55 Figure 27. ESD Protection for USB .................................................................................................. 56 Figure 28. Reference Design for Dual SIM Application .................................................................... 56 Figure 29. GSM Antenna Connection with Antenna Detection ........................................................ 57 4117047 Rev 2.1 December 10, 2015 8 List of Tables Table 1. Supported Bands/Connectivity ........................................................................................ 11 Table 2. General Features ............................................................................................................ 12 Table 3. ESD Specifications .......................................................................................................... 17 Table 4. Environmental Specifications .......................................................................................... 17 Table 5. Regulation Compliance ................................................................................................... 18 Table 6. Pad Definition .................................................................................................................. 20 Table 7. Pin Type Codes ............................................................................................................... 24 Table 8. Power Supply .................................................................................................................. 26 Table 9. Power Supply Pin Description ......................................................................................... 26 Table 10. Radio Burst Rates – Connected Mode ............................................................................ 27 Table 11. Current Consumption (at nominal voltage, 3.7V) ............................................................ 29 Table 12. Current Consumption per Power Supply (VBATT_PA and VBATT) ............................... 30 Table 13. VGPIO Electrical Characteristics ..................................................................................... 31 Table 14. VGPIO Pin Description .................................................................................................... 31 Table 15. BAT_RTC Electrical Characteristics................................................................................ 32 Table 16. BAT_RTC Pin Description ............................................................................................... 32 Table 17. Electrical Characteristics of UIM1 ................................................................................... 33 Table 18. UIM1 Pin Description ....................................................................................................... 33 Table 19. USIM Socket Pin Description .......................................................................................... 34 Table 20. Electrical Characteristics of USB..................................................................................... 35 Table 21. USB Pin Description ........................................................................................................ 35 Table 22. Digital I/O Electrical Characteristics ................................................................................ 35 Table 23. GPIO Pin Description ...................................................................................................... 36 Table 24. UART1 Pin Description ................................................................................................... 37 Table 25. PWR_ON_N Electrical Characteristics ........................................................................... 39 Table 26. RESET_IN_N Electrical Characteristics .......................................................................... 40 Table 27. ADC Electrical Characteristics ........................................................................................ 40 Table 28. ADC Pin Description ........................................................................................................ 40 Table 29. PWM Electrical Characteristics ....................................................................................... 41 Table 30. PWM Pin Description ...................................................................................................... 41 Table 31. 32.768Khz Clock Interface Pin Description .................................................................... 43 Table 32. 26Mhz Clock Interface Pin Description .......................................................................... 43 Table 33. Clock Interface Pin Description ....................................................................................... 43 Table 34. Digital Audio PCM Electrical Characteristics ................................................................... 44 Table 35. PCM Master Mode Parameters ....................................................................................... 45 Table 36. PCM Slave Mode Parameters ......................................................................................... 46 Table 37. Digital Audio PCM Pin Description .................................................................................. 47 4117047 Rev 2.1 December 10, 2015 9 Product Technical Specification Table 38. SW Trace Pin Description ............................................................................................... 47 Table 39. JTAG Pin Connection ...................................................................................................... 47 Table 40. JTAG Pin Description ...................................................................................................... 48 Table 41. RF Pin Connection .......................................................................................................... 49 Table 42. RF Performance .............................................................................................................. 49 Table 43. Burst Indicator States ...................................................................................................... 49 Table 44. 2G_TX_ON Burst Characteristics .................................................................................. 49 Table 45. 2G_TX_ON Burst Pin Description .................................................................................. 50 Table 46. Standards Conformity...................................................................................................... 58 Table 47. Life Stress Test................................................................................................................ 58 Table 48. Environmental Resistance Stress Tests ......................................................................... 59 Table 49. Corrosive Resistance Stress Tests ................................................................................. 59 Table 50. Thermal Resistance Cycle Stress Tests ......................................................................... 60 Table 51. Mechanical Resistance Stress Tests .............................................................................. 61 Table 52. Handling Resistance Stress Tests .................................................................................. 62 Table 53. ATEX Conformance ........................................................................................................ 66 Table 54. Ordering Information ....................................................................................................... 67 4117047 Rev 2.1 December 10, 2015 10 1. Introduction This document is the Product Technical Specification for the AirPrime HL8518, HL8528 and HL8529 Embedded Modules. It defines high level features and illustrates the interfaces for these features. This document is intended to cover hardware aspects, including electrical and mechanical, of the AirPrime HL8518, HL8528 and HL8529. The AirPrime HL8518, HL8528 and HL8529 modules belong to the AirPrime HL Series from the Essential Connectivity Module family. These are industrial grade Embedded Wireless Modules that provide voice and data connectivity on GPRS, EDGE RX, WCDMA, HSDPA and HSUPA networks (as listed in Table 1 Supported Bands/Connectivity). The HL8518, HL8528 and HL8529 modules support a large variety of interfaces such as Digital Audio, GPIOs and UART to provide customers with the highest level of flexibility in implementing high-end solutions. Transmit band (Tx) Receive band (Rx) Maximum Output Power UMTS B1 1922 to1978 MHz 2112 to 2168 MHz 22.5 dBm (± 1.5 dB) UMTS B2 1852 to 1908 MHz 1932 to 1988 MHz 22.5 dBm (± 1.5 dB) UMTS B5 826 to 847 MHz 871 to 892 MHz 22.5 dBm (± 1.5 dB) UMTS B8 882 to 913 MHz 927 to 958 MHz 22.5 dBm (± 1.5 dB) GSM 850 824 to 849 MHz 869 to 894 MHz 33 dBm ± 2 dB GSM, GPRS E-GSM 900 880 to 915 MHz 925 to 960 MHz 33 dBm ± 2 dB GSM, GPRS  DCS 1800 1710 to 1785 MHz 1805 to 1880 MHz 30 dBm ± 2 dB GSM, GPRS  PCS 1900 1850 to 1910 MHz 1930 to 1990 MHz 30 dBm ± 2 dB GSM, GPRS 1.1. HL8529 RF Band HL8528 Supported Bands/Connectivity HL8518 Table 1.         Common Flexible Form Factor (CF3) The AirPrime HL8518, HL8528 and HL8529 belong to the Common Flexible Form Factor (CF3) family of modules. This family consists of a series of WWAN modules that share the same mechanical dimensions (same width and length with varying thicknesses) and footprint. The CF3 form factor provides a unique solution to a series of problems faced commonly in the WWAN module space as it:  Accommodates multiple radio technologies (from 2G to LTE advanced) and band groupings  Supports bit-pipe (Essential Module Series) and value add (Smart Module Series) solutions  Offers electrical and functional compatibility  Provides Direct Mount as well Socketability depending on customer needs 4117047 Rev 2.1 December 10, 2015 11 Product Technical Specification 1.2. Introduction Physical Dimensions The AirPrime HL8518, HL8528 and HL8529 modules are compact, robust, fully shielded modules with the following dimensions:  Length: 23 mm  Width: 22 mm  Thickness: 2.5 mm  Weight: 2.65 g Note: Dimensions specified above are typical values. 1.3. General Features The table below summarizes the AirPrime HL8518, HL8528 and HL8529 features. Table 2. General Features Feature Physical Electrical Description  Small form factor (146-pin solderable LGA pad) – 23mm x 22mm x 2.5mm (nominal)  Metal shield can  RF connection pad  Baseband signals connection Single or double supply voltage (VBATT and VBATT_PA) – 3.2V – 4.5V HL8518 (dual-band UMTS and dual-band GSM):  UMTS B1  UMTS B8  E-GSM 900  DCS 1800 HL8528 (dual-band UMTS and dual-band GSM): RF  UMTS B2  UMTS B5  GSM 850  PCS 1900 HL8529 (dual-band UMTS): Audio interface 4117047  UMTS B2  UMTS B5  Digital interface (ONLY)  Supports Enhanced Full Rate (EFR), Full Rate (FR), Half Rate (HR), and both Narrow-Band and Wide-band Adaptive Multirate (AMR-NB and AMRWB) vocoders  MO and MT calling  Echo cancellation and noise reduction  Emergency calls (112, 110, 911, etc.)  Incoming call notification  DTMF generation Rev 2.1 December 10, 2015 12 Product Technical Specification Feature SIM interface Application interface Introduction Description  Dual SIM Single Standby (DSSS) with fast network switching capability  1.8V/3V support  SIM extraction / hot plug detection  SIM/USIM support  Conforms with ETSI UICC Specifications.  Supports SIM application tool kit with proactive SIM commands  NDIS NIC interface support (Windows XP, Windows 7, Windows 8, Windows CE, Linux)  Multiple non-multiplexed USB channel support  Dial-up networking  USB selective suspend to maximize power savings  CMUX multiplexing over UART  AT command interface – 3GPP 27.007 standard, plus proprietary extended AT commands Dual-mode UMTS (WCDMA) / HSDPA / HSUPA / EDGE RX / GPRS / GSM operation  GSM/GPRS/EDGE RX  GPRS Class 12  EDGE RX  CSD (Circuit-switched data bearers)  Release 4 GERAN Feature Package 1  SAIC / DARP Phase 1  Latency Reduction  Repeated FACCH and Repeated SACCH  GPRS ROHC  Enhanced Operator Name String (EONS)  Enhanced Network Selection (ENS)  WCDMA  3GPP WCDMA FDD Multimode Type II UE Protocol Stack  Configurable for data classes up to 384 kBit/s  Inter-RAT Handover and Cell Reselection  Supports two types of Compressed Mode  Network Assisted Cell Change from UTRAN to GERAN and GERAN to UTRAN  CSD (Circuit-switched data bearers) over WCDMA (transparent/non transparent up to 64 kBit/s; Support for Video Telephony)  HSDPA (High Speed Downlink Packet Access)  Compliant with 3GPP Release 5  HSDPA Category 8 data rate – 7.2 Mbps (peak rate)  IPv6 support  HSUPA (High Speed Uplink Packet Access)  Compliant with 3GPP Release 6  HSUPA Category 6 data rate - 5.76 Mbps (peak rate)  Robust Header Compression (RoHC) Protocol Stack  Fractional DPCH 4117047 Rev 2.1 December 10, 2015 13 Product Technical Specification Feature Description  HSPA+ (Evolved High Speed Packet Access)  Compliant with 3GPP Release 7  Higher-Order Modulation (HOM)  MAC-ehs support  Continuous Packet Connectivity (CPC)  Enhanced F-DPCH  Enhanced Cell FACH  Circuit Switched Voice over HSPA  SMS MO and MT  CS and PS support  SMS saving to SIM card or ME storage  SMS reading from SIM card or ME storage  SMS sorting  SMS concatenation  SMS Status Report  SMS replacement support  SMS storing rules (support of AT+CNMI, AT+CNMA)  Call Barring  Call Forwarding  Call Hold  Caller ID  Call Waiting  Multi-party service  USSD  Automatic answer  Multiple (up to 20) cellular packet data profiles  Sleep mode for minimum idle power draw  Automatic GPRS attach at power-up  GPRS detach  Mobile-originated PDP context activation / deactivation  Support QoS profile  Release 97 – Precedence Class, Reliability Class, Delay Class, Peak Throughput, Mean Throughput  Release 99 QoS negotiation – Background, Interactive, and Streaming  Static and Dynamic IP address. The network may assign a fixed IP address or dynamically assign one using DHCP (Dynamic Host Configuration Protocol).  Supports PAP and CHAP authentication protocols  PDP context type (IPv4, IPv6, IPv4v6). IP Packet Data Protocol context  RFC1144 TCP/IP header compression  Interaction with existing GSM services (MO/MT SMS voice calls) while:  GPRS is attached, or  In a GPRS data session (class B GPRS suspend / resume procedures) Protocol Stack SMS Supplementary Services Connectivity Introduction Operating temperature ranges (industrial grade): Environmental 4117047   Class A: -30°C to +70°C Class B: -40°C to +85°C Rev 2.1 December 10, 2015 14 Product Technical Specification Introduction Feature Description RTC Real Time Clock (RTC) with calendar and alarm Temperature Sensor 1.4.  Temperature monitoring  Alarms Encryption Support The AirPrime HL8518, HL8528 and HL8529 supports the following encryption algorithms:  Ciphering algorithms A51, A52 and A53  GEA1/GEA2 and GEA3 algorithm for GPRS encryption  Cyclic Redundancy Check (CRC) with programmable polynomial  UMTS confidentiality algorithm f8 for message ciphering (Kasumi based UEA1)  UMTS integrity algorithm f9 for message authentication (Kasumi based UIA1 and SNOW 3G based UIA2) 1.5. Architecture The figure below presents an overview of the AirPrime HL8518, HL8528 and HL8529 modules internal architecture and external interfaces. AirPrime HL8518, HL8528 and HL8529 RX_DCS 26MHz Transceiver SAW Filters RX_DCS TX_2G 3G PA RX_2G RX_3G 2G PA + Antenna Switch Isoplexer B1/B8GSM900 RF RF Or LGA-146 ADC x2 UART1 (8pins) Debug (2pins) JTAG 26M_CLKOUT 32K_CLKOUT SIM1 RESET_IN_N TP1 PWR_ON_N PWM x 2 2G_TX_ON USB TX_3G Baseband B2-PCS/B5GSM850 Or B2/B5 MCU DSP PMU RF RF LGA-146 VBATT GND VGPIO BAT_RTC GPIO x 12 Analog Baseband Peripherals PCM Memory (Flash + RAM) Figure 1. 4117047 32.768KHz Architecture Overview Rev 2.1 December 10, 2015 15 Product Technical Specification 1.6. Introduction Interfaces The AirPrime HL8518, HL8528 and HL8529 modules provide the following interfaces and peripheral connectivity:  1x – 8-pin UART  1x – Active Low RESET  1x – USB 2.0  1x – Backup Battery Interface  2x – System Clock Out  1x – Active Low POWER ON  1x – 1.8V/3V SIM  1x – Digital Audio  2x – ADC  1x – JTAG Interface  1x – Debug Interface  2x – PWM  12x – GPIOs  1x – 2G TX Burst Indicator  1x – GSM Antenna 1.7. Connection Interface The AirPrime HL8518, HL8528 and HL8529 modules are an LGA form factor device. All electrical and mechanical connections are made through the 146 Land Grid Array (LGA) pads on the bottom side of the PCB. Figure 2. Mechanical Overview The 146 pads have the following distribution:  66 inner signal pads, 1x0.5mm, pitch 0.8mm  1 reference test point (Ground), 1.0mm diameter  7 test point (JTAG), 0.8mm diameter, 1.20mm pitch  64 inner ground pads, 1.0x1.0mm, pitch 1.825mm/1.475mm  4 inner corner ground pads, 1x1mm  4 outer corner ground pads, 1x0.9mm 4117047 Rev 2.1 December 10, 2015 16 Product Technical Specification 1.8. Introduction ESD Refer to the following table for ESD Specifications. Note: Information specified in the following table is preliminary and subject to change. Table 3. ESD Specifications Category Connection Specification Operational RF ports IEC-61000-4-2 — Level (Electrostatic Discharge Immunity Test) Unless otherwise specified: Non-operational Host connector interface SIM connector Signals Other host signals 1.9.  JESD22-A114 +/- 1kV Human Body Model  JESD22-A115 +/- 200V Machine Model  JESD22-C101C +/- 250V Charged Device Model ESD protection is highly recommended at the point where the USIM contacts are exposed, and for any other signals that would be subjected to ESD by the user. Environmental and Certifications 1.9.1. Environmental Specifications The environmental specification for both operating and storage conditions are defined in the table below. Table 4. Environmental Specifications Conditions Range Operating Class A -30°C to +70°C Operating Class B -40°C to +85°C Storage -40°C to +85°C Note: The upper limit of Class A is subject to module PCB temperature. A progressive 3G output power reduction feature is implemented for when PCB temperatures are above +80°C. This leads to a calibrated 3G TX power output up to +80°C for the PCB temperature and automatic decrease at higher temperatures. Therefore, depending on module activity and customer design, the upper limit of Class A could be lower than 70°C. Class A is defined as the operating temperature ranges that the device:  Shall exhibit normal function during and after environmental exposure.  Shall meet the minimum requirements of 3GPP or appropriate wireless standards. Class B is defined as the operating temperature ranges that the device:  Shall remain fully functional during and after environmental exposure  Shall exhibit the ability to establish a voice, SMS or DATA call (emergency call) at all times even when one or more environmental constraint exceeds the specified tolerance.  Unless otherwise stated, full performance should return to normal after the excessive constraint(s) have been removed. 4117047 Rev 2.1 December 10, 2015 17 Product Technical Specification 1.9.2. Introduction Regulatory The AirPrime HL8518, HL8528 and HL8529 modules are compliant with the following regulations:  R&TTE directive 1999/5/EC  FCC  IC These compliances will be reflected on the AirPrime HL8518, HL8528 and HL8529 modules labels when applicable. Table 5. Regulation Compliance Document Current Version Title NAPRD.03 v5.18 or later Overview of PCS Type certification review board (PTCRB) Mobile Equipment Type Certification and IMEI control GCF-CC v3.51.1 or later GCF Conformance Certification Criteria TS 51.010-1 V10.0.0 (2012-03) 3rd Generation Partnership Project; Technical Specification Group GSM/EDGE Radio Access Network; Digital cellular telecommunications system (Phase 2+); Mobile Station (MS) conformance specification; Part 1: Conformance specification TS 51.010-2 V10.0.0 (2012-03) 3rd Generation Partnership Project; Technical Specification Group GSM/EDGE Radio Access Network; Mobile Station (MS) conformance specification; Part 2: Protocol Implementation Conformance Statement (PICS) proforma specification EN 301511 V9.0.2 (2003-03) Global System for Mobile Communications (GSM); Harmonized EN for Mobile Stations in the GSM 900 and GSM 1800 Bands Covering Essential Requirements Under Article 3.2 of the R&TTE Directive (1999/5/EC) EN 301489-1 V1.9.2 (2011-09) Electromagnetic compatibility and Radio spectrum Matters (ERM); ElectroMagnetic Compatibility (EMC) standard for radio equipment and services; Part 1: Common technical requirements EN 301489-3 V1.4.1 (2002-08) Electromagnetic compatibility and Radio spectrum Matters (ERM); ElectroMagnetic Compatibility (EMC) standard for radio equipment and services; Part 3: Specific conditions for Short-Range Devices (SRD) operating on frequencies between 9 kHz and 40 GHz EN 301489-7 V1.3.1 (2005-11) Electromagnetic Compatibility and Radio Spectrum Matters (ERM); ElectroMagnetic Compatibility (EMC) Standard for Radio Equipment and Services; Part 7: Specific Conditions for Mobile and Portable Radio and Ancillary Equipment of Digital Cellular Radio Telecommunications Systems (GSM and DCS) EN 60950-1 NA IEC 60950-1:2005/A1:2009 EN 60950-1:2006/A11:2009/A1:2010/A12:2011/AC :2011 Information technology equipment – safety- and general requirements EN 300440-1 v1.6.1 (2012-08) Electromagnetic compatibility and Radio spectrum Matters (ERM); Short range devices; Radio equipment to be used in the 1 GHz to 40 GHz frequency range; Part 1: Technical characteristics and test methods EN 300440-2 V1.4.1 (2012-08) Electromagnetic compatibility and Radio spectrum Matters (ERM); Short range devices; Radio equipment to be used in the 1 GHz to 40 GHz frequency range; Part 2: Harmonized EN under article 3.2 of the R&TTE Directive 4117047 Rev 2.1 December 10, 2015 18 Product Technical Specification Introduction Document Current Version Title FCC Part 22H NA Cellular Radiotelephone Service; Subpart H: Cellular Radiotelephone Service FCC Part 24E NA Personal Communications Service; Subpart E: Broadband PCS. 1.9.3. RoHS Directive Compliant The AirPrime HL8518, HL8528 and HL8529 modules are compliant with RoHS Directive 2011/65/EU which sets limits for the use of certain restricted hazardous substances. This directive states that “from 1st July 2006, new electrical and electronic equipment put on the market does not contain lead, mercury, cadmium, hexavalent chromium, polybrominated biphenyls (PBB) or polybrominated diphenyl ethers (PBDE)”. 1.9.4. Disposing of the Product This electronic product is subject to the EU Directive 2012/19/EU for Waste Electrical and Electronic Equipment (WEEE). As such, this product must not be disposed of at a municipal waste collection point. Please refer to local regulations for directions on how to dispose of this product in an environmental friendly manner. 1.10. References [1] AirPrime HL Series Customer Process Guidelines Reference Number: 4114330 [2] AirPrime HL6 and HL8 Series AT Commands Interface Guide Reference Number: 4114680 [3] AirPrime HL Series Dual SIM Single Standby Application Note Reference Number: 2174034 4117047 Rev 2.1 December 10, 2015 19 2. Pad Definition AirPrime HL8518, HL8528 and HL8529 pins are divided into 3 functional categories.  Core functions and associated pins cover all the mandatory features for M2M connectivity and will be available by default across all CF 3 family of modules. These Core functions are always available and always at the same physical pin locations. A customer platform using only these functions and associated pins is guaranteed to be forward and/or backward compatible with the next generation of CF3 modules.  Extension functions and associated pins bring additional capabilities to the customer. Whenever an Extension function is available on a module, it is always at the same pin location.  Custom functions and associated pins are specific to a given module, and make an opportunistic use of specific chipset functions and I/Os. Custom features should be used with caution as there is no guarantee that the custom functions available on a given module will be available on other CF3 modules. Other pins marked as “not connected” or “reserved” should not be used. Table 6. Pad Definition Pin # Signal Name Function I/O I/O HW Reset State** Driver Pad Class* 1 GPIO1 General purpose input/output I/O I, T E 2 UART1_RI UART1 Ring indicator O I, T/PD A 3 UART1_RTS UART1 Request to send I I, T/PD 4 UART1_CTS UART1 Clear to send O I, T/PD 5 UART1_TX UART1 Transmit data I I, T/PD 6 UART1_RX UART1 Receive data O I, T/PD 7 UART1_DTR UART1 Data terminal ready I I, T/PD 8 UART1_DCD UART1 Data carrier detect/ O I, L A 9 UART1_DSR UART1 Data set ready O I, T/PD A 10 GPIO2 General purpose input/output I/O I, T/PD A 4117047 Rev 2.1 A Active Low / High Power Supply Domain Recommendation for Unused Pins Type 1.8V Left Open Extension 1.8V Left Open Core L 1.8V Connect to UART1_CTS Core L 1.8V Connect to UART1_RTS Core 1.8V Mandatory connection Core 1.8V Mandatory connection Core L 1.8V Connect to UART1_DSR Core L 1.8V Left Open Core L 1.8V Connect to UART1_DTR Core 1.8V Left Open Core A December 10, 2015 20 Product Technical Specification Pad Definition Pin # Signal Name Function I/O I/O HW Reset State** Active Low / High Power Supply Domain Recommendation for Unused Pins Type 11 RESET_IN_N Input reset signal I I, T/PU L 1.8V Left Open Core 12 USB_D- I/O T Left Open Extension 13 USB_D+ I/O T Left Open Extension 14 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 15 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 16 USB_VBUS USB VBUS 17 NC Not Connected (Reserved for future use) 5V Left Open Extension - - - - - Left Open Not connected 18 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 19 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 20 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 21 BAT_RTC Power supply for RTC backup I/O N/A 1.8V Left Open Extension 22 23 26M_CLKOUT 26MHz System Clock Output O I, T/PD B 1.8V Left Open Extension 32K_CLKOUT 32.768kHz System Clock Output O I, T/PD B 1.8V Left Open Extension 24 ADC1 Analog to digital conversion I N/A 1.2V Left Open Extension 25 ADC0 Analog to digital conversion I N/A 1.2V Left Open Extension 26 UIM1_VCC 1.8V/3V SIM1 Power supply O N/A 1.8V/3V Mandatory connection Core 27 UIM1_CLK 1.8V/3V SIM1 Clock O O, L E 1.8V/3V Mandatory connection Core 28 UIM1_DATA 1.8V/3V SIM1 Data I/O O, L/PD E 1.8V/3V Mandatory connection Core 29 UIM1_RESET 1.8V/3V SIM1 Reset O O, L E 1.8V/3V Mandatory connection Core 4117047 USB Data Negative (Low / Full Speed) USB Data Negative (High Speed) USB Data Positive (Low / Full Speed) USB Data Positive (High Speed) Driver Pad Class* 3.3V 0.38V 3.3V 0.38V I Rev 2.1 L December 10, 2015 21 Product Technical Specification Pad Definition Pin # Signal Name Function I/O I/O HW Reset State** Driver Pad Class* Active Low / High Power Supply Domain Recommendation for Unused Pins Type 30 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 31 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 32 NC Not Connected (Reserved for future use) - - - - - Left Open Not connected 33 PCM_OUT PCM data out O I, T/PD C 1.8V Left Open Extension 34 PCM_IN PCM data in I I, T/PD 1.8V Left Open Extension 35 PCM_SYNC PCM sync out I/O I, T/PD C 1.8V Left Open Extension 36 PCM_CLK PCM clock I/O I, T/PD C 1.8V Left Open Extension 37 GND Ground 0V 0V Mandatory connection Core 38 NC Not Connected - - Left Open Not connected 39 GND Ground 0V 0V Mandatory connection Core 40 GPIO7 General purpose input/output I/O O, L A 1.8V Left Open Core 41 GPIO8 General purpose input/output I/O I, T/PD A 1.8V Left Open Core 42 NC Not Connected - - - - - Left Open Not connected 43 NC Not Connected - - - - - Left Open Not connected 44 DEBUG_TX Debug transmit data O I, T/PD A 1.8V Left Open Extension 45 VGPIO GPIO voltage output O N/A 1.8V Left Open Core 46 GPIO6 General purpose input/output I/O O, L 1.8V Left Open Core 47 TP1 Test Point 1 0 - Download Mode Open - Normal Mode I O, L 1.8V Left Open Extension 48 GND Ground 0V 0V Mandatory connection Core 49 RF_MAIN RF GSM Input/output Mandatory connection Core 50 GND Ground 0V 0V Mandatory connection Core 51 DEBUG_RX Debug receive data I 1.8V Left Open Extension 4117047 - - - A L N/A Rev 2.1 I, T/PD December 10, 2015 22 Product Technical Specification Pad Definition Pin # Signal Name Function I/O I/O HW Reset State** Driver Pad Class* 52 GPIO10 General purpose input/output I/O I, T/PD 53 GPIO11 General purpose input/output I/O 54 GPIO15 General purpose input/output I/O 55 NC1 Reserved for future use 56 NC2 Reserved for future use 57 PWM1 Pulse Width Modulation O I, T/PD A 58 PWM2 / GPIO12 Pulse Width Modulation / General purpose input/output I/O L A 59 PWR_ON_N Active Low Power On control signal I 60 2G_TX_ON 2G TX burst indicator O I, T/PD Power Supply Domain Recommendation for Unused Pins Type A 1.8V Left Open Extension I, T/PD A 1.8V Left Open Extension I, T/PD A 1.8V Left Open Extension Left Open Not connected Left Open Not connected 1.8V Left Open Extension 1.8V Left Open Extension L 1.8V Mandatory connection Core H 1.8V Left Open Extension 61 VBATT_PA Power supply (refer to section 3.1 Power Supply for more information) I N/A 3.2V (min) 3.7V (typ) 4.5V (max) Mandatory connection Core 62 VBATT_PA Power supply (refer to section 3.1 Power Supply for more information) I N/A 3.2V (min) 3.7V (typ) 4.5V (max) Mandatory connection Core 63 VBATT Power supply I N/A 3.2V (min) 3.7V (typ) 4.5V (max) Mandatory connection Core 64 UIM1_DET / GPIO3 UIM1 Detection / General purpose input/output I/O I, T/PD A H 1.8V Left Open Core 65 GPIO4 General purpose input/output I/O I, T/PD A H 1.8V Left Open Extension 66 GPIO5 General purpose input/output I/O I, T/PU E 1.8V Left Open Extension 67-70 GND Ground 0V 71 166 Note: 167234 GND Ground 0V 236 JTAG_RESET JTAG RESET I 4117047 A Active Low / High 0V Core 0V Core These pins are not available on the AirPrime HL8518, HL8528 and HL8529 modules. Rev 2.1 I, T L 1.8V Left Open December 10, 2015 Extension 23 Product Technical Specification Pad Definition Pin # Signal Name Function I/O I/O HW Reset State** 237 JTAG_TCK JTAG Test Clock I I, PD 238 JTAG_TDO JTAG Test Data Output O O, T 239 JTAG_TMS JTAG Test Mode Select I I, PU 240 JTAG_TRST JTAG Test Reset I I, PU 241 JTAG_TDI JTAG Test Data Input I I, PU 242 JTAG_RTCK JTAG Returned Test Clock O O, L Driver Pad Class* Active Low / High A L A * Refer to Table 22 Digital I/O Electrical Characteristics for more information. ** I = Input, O = Output, PU = Pull up, PD = Pull down, H = High, L = Low, T = High impedance, N/A = Not applicable 2.1. Table 7. Power Supply Domain Recommendation for Unused Pins Type 1.8V Left Open Extension 1.8V Left Open Extension 1.8V Left Open Extension 1.8V Left Open Extension 1.8V Left Open Extension 1.8V Left Open Extension Pin Types Pin Type Codes Type Definition I Digital Input O Digital Output I/O Digital Input / Output L Active High H Active Low T Tristate T/PU Tristate with pull-up enabled T/PD Tristate with pull-down enabled 4117047 Rev 2.1 December 10, 2015 24 Product Technical Specification 200 173 189 212 227 234 231 220 201 174 188 211 226 233 232 221 202 175 225 209 185 224 208 184 223 207 183 222 206 182 203 205 181 176 204 180 179 178 JTAG_TDO JTAG_TCK JTAG_RESET GPIO5 JTAG_TMS 66 242 241 240 239 238 237 236 65 GPIO4 64 UIM1_DET/GPIO3 Core pin 63 VBATT Extension pin 62 VBATT_PA 61 VBATT_PA 60 2G_TX_ON 59 PWR_ON_N 58 PWM2/GPIO12 57 PWM1 56 NC2 55 NC1 54 GPIO15 53 GPIO11 52 GPIO10 70 GND DEBUG_RX GND RF_MAIN GND TP1 GPIO6 VGPIO NC DEBUG_TX NC GPIO8 GPIO7 GND NC GND PCM_CLK PCM_IN 4117047 GND 170 PCM_SYNC 169 Figure 3. 67 177 51 210 1 2 3 219 50 69 4 230 49 GND 172 229 36 33 199 228 35 32 171 213 187 34 NC 236 190 186 PCM_OUT 218 48 31 5 NC 217 237 198 47 30 6 NC 238 197 46 29 7 UIM1_RESET 239 45 28 8 UIM1_DATA 9 27 240 44 26 UIM1_CLK 216 43 UIM1_VCC 10 25 215 241 196 42 ADC0 11 24 214 195 41 ADC1 12 32K_CLKOUT 23 191 194 40 22 13 26M_CLKOUT 193 39 21 14 BAT_RTC 192 38 20 15 19 NC 37 NC 16 68 17 GND 18 242 JTAG_TRST 167 JTAG_TDI 168 JTAG_RTCK GPIO1 UART1_RI UART1_RTS UART1_CTS UART1_TX UART1_RX UART1_DTR UART1_DCD UART1_DSR RESET_IN_N GPIO2 USB_D- USB_D+ NC NC USB_VBUS NC Pin Configuration (Top View, Through Module) NC 2.2. Pad Definition Pin Configuration Rev 2.1 December 10, 2015 25 3. Detailed Interface Specifications Note: If not specified, all electrical values are given for VBATT=3.7V and an operating temperature of 25°C. For standard applications, VBATT and VBATT_PA must be tied externally to the same power supply. For some specific applications, AirPrime HL8518, HL8528 and HL8529 modules support separate VBATT and VBATT_PA connection if requirements below are fulfilled. 3.1. Power Supply The AirPrime HL8518, HL8528 and HL8529 modules are supplied through the VBATT signal. 3.1.1. Electrical Characteristics The following table describes the electrical characteristics of the Power Supply interface. Table 8. Power Supply Supply Minimum Typical Maximum VBATT voltage (V) 3.21 3.7 4.5 VBATT_PA voltage (V) Full Specification 3.21 3.7 4.5 VBATT_PA voltage (V) Extended Range 2.82 3.7 4.5 1 This value has to be guaranteed during the burst 2 No guarantee of 3GPP performances over extended range Note: Load capacitance for VBATT is around 30µF ± 20% embedded inside the module. Load capacitance for VBATT_PA is around 20µF ± 20% embedded inside the module. 3.1.2. Pin Description The following table describes the pin description of the Power Supply interface. Table 9. Power Supply Pin Description Pin Number Signal Name I/O Description 63 VBATT I Power supply (base band) 61, 62 VBATT_PA I Power supply (radio frequency) 37, 39, 48, 67-70, 167-234 GND 4117047 Rev 2.1 Ground December 10, 2015 26 Product Technical Specification 3.1.3. Detailed Interface Specifications Burst Transmission Current Requirements The power supply must be able to deliver high current peaks in a short time due to the burst transmission nature of GSM. For supply filtering recommendations, please refer to section 3.3 Decoupling of Power Supply Signals. The following table describes radio burst rates in connected mode. For detailed power consumption figures, refer to section 3.4 Current DC Power Consumption. Radio Burst Rates – Connected Mode Table 10. GSM/GPRS Multislot Class Class 10 Class 12 RF Power Amplifier Current Slot Duration Period Rising Time 2.2A peak 577 μs 4.615 ms 10 μs The corresponding radio burst rates in connected mode are as follows:  GSM/GPRS class 2 terminals emit 577 µs radio bursts every 4.615 ms  GPRS class 10 terminals emit 1154 µs radio bursts every 4.615 ms  GPRS class 12 terminals emit 2308 µs radio bursts every 4.615 ms In connected mode, the RF Power Amplifier current (2.2A peak in GSM /GPRS mode) flows with a ratio of:  1/8 of the time (around 577 µs every 4.615 ms for GSM /GPRS cl 2 – 2RX/1TX), and  4/8 of the time (around 2308 µs every 4.615 ms for GSM /GPRS cl 12 – 4RX/1TX) with the rising time at around 10 µs. V Voltage Behavior during TX Transmissions 3.8V VBATT Residual Noise 3.7V Voltage Drop Uripp 3.6V t I Peak Current at Max RF Transmissions Example: PCL5 33dBm (GSM900) T = 577uS T = 4.615mS Figure 4. 4117047 t Power Supply During Burst Transmission Rev 2.1 December 10, 2015 27 Product Technical Specification 3.1.4. Detailed Interface Specifications Power Input (VBATT) An external power supply uses the VBATT pins to:  Supply the AirPrime HL8518, HL8528 and HL8529 modules.  Directly supply the RF components.  It is essential to keep the voltage ripple to a minimum at this connection to avoid any phase error or spectrum modulation degradation.  An inadequate power supply can significantly affect RF performance (TX power, modulation spectrum, EMC performance, spurious emission, frequency error, etc.).  Provide reference voltage VGPIO (through internal regulators) for the baseband signals. When the AirPrime HL8518, HL8528 and HL8529 modules are supplied with a battery, the total impedance (battery + protections + PCB) should be such that the supply will be >= 3.2 V during GSM burst mode operation drawing a maximum peak current of 2.2 A for 577 µs (one slot) or 1154 µs (two slots) TX. 3.2. Ground Connection The AirPrime HL8518, HL8528 and HL8529 modules shielding case is the grounding. The ground must be connected on the motherboard through a complete layer on the PCB. The ground connection is made by soldering the LGA ground pins and rectangular ground pad to the ground plane of the application board. 3.3. Decoupling of Power Supply Signals The ETSI standard defines specific requirements for phase error and spectrum modulation. Both are mandatory and can be affected by the choice of power supply filtering. It is highly recommended to provide multiple capacitor values to solve an eventual Amplitude and Phase Modulation issue. AirPrime HL8518, HL8528 and HL8529 modules already here embedded decoupling capacitors on the VBATT lines, but additional external decoupling may be required. EMI/RFI issues – Add a capacitor (10pF~33pF) close to the VBATT pins.  TDMA noise (217 Hz) – Place a low ESR decoupling capacitors (at least 100 µF) as close to the module as possible to reduce noise. Mandatory Not Mandatory Recommended  AirPrime HL8518, HL8528 and HL8529 10 – 33pF ≥ 100µF > 1mF VBATT GND Figure 5. 4117047 Power Supply Requirements Rev 2.1 December 10, 2015 28 Product Technical Specification Detailed Interface Specifications The figure below shows the power supply voltage drop shapes during GSM 2G transmission. V V Not Critical Critical 3.8V 3.8V VBATT VBATT 3.7V 3.7V 3.6V 3.6V Phase Error Risk t t V V Not Critical Not Critical 3.8V 3.8V VBATT VBATT Residual Noise 3.7V 3.7V 3.6V 3.6V Spectrum Modulation Risk t t Figure 6. 3.4. Power Supply Voltage Drops Shapes During Burst Transmission Current DC Power Consumption The following table lists the current consumption of the AirPrime HL8518, HL8528 and HL8529 modules at different conditions. Note: The following data is under the setup recommended in section 5.5 Power Supply Design. The USB is disconnected for the lowest current consumption. Typical values are measured at ambient temperature, and maximum values are measured over the entire operating temperature range. (The measurements are done with a CMU200 and with a 50Ω load.) For a description of input voltage requirements, see section 3.1 Power Supply. Table 11. Current Consumption (at nominal voltage, 3.7V) Parameters Typical Off mode 50 µA Sleep mode - GSM DRX2 (registered to the network) Sleep mode - GSM DRX9 (registered to the network) Sleep mode - WCDMA DRX6 (registered to the network) 4117047 Rev 2.1 Maximum GSM900 1.5 mA 3.15 mA DCS1800 1.5 mA 3.15 mA GSM850 1.6 mA 3.4 mA PCS1900 1.6 mA 3.4 mA GSM900 1.15 mA 2.7 mA DCS1800 1.0 mA 2.7 mA GSM850 1.3 mA 2.9 mA PCS1900 1.25 mA 2.95 mA Band 1 1.75 mA 3.45 mA Band 2 2 mA 3.75 mA Band 5 2 mA 3.8 mA Band 8 1.75 mA 3.5 mA December 10, 2015 29 Product Technical Specification Detailed Interface Specifications Parameters Sleep mode - WCDMA DRX9 (registered to the network) WCDMA in communication mode (Voice Call) WCDMA in communication mode (HSDPA) WCDMA in communication mode (HSUPA) GSM in communication mode GPRS (2 TX,3 RX) Peak current consumption Table 12. Typical Maximum Band 1 1.1 mA 2.7 mA Band 2 1.3 mA 2.9 mA Band 5 1.3 mA 3.2 mA Band 8 1.1 mA 2.7 mA Band 1 620 mA 735 mA Band 2 620 mA 735 mA Band 5 500 mA 650 mA Band 8 500 mA 650 mA Band 1 700 mA 880 mA Band 2 680 mA 900 mA Band 5 550 mA 760 mA Band 8 580 mA 800 mA Band 1 700 mA 880 mA Band 2 665 mA 900 mA Band 5 550 mA 760 mA Band 8 580 mA 800 mA GSM900 / GSM850 (PCL=5) 220 mA 250 mA DCS / PCS (PCL=0) 165 mA 175 mA GSM900 / GSM850 (PCL=5) 425 mA 460 mA DCS / PCS (PCL=0) 300 mA 335 mA GSM900 / GSM850 1.9 A 2.2A DCS / PCS 1.8 A 2.0A Typical Maximum Current Consumption per Power Supply (VBATT_PA and VBATT) Parameters Average current GSM in communication mode E-GSM 900 / GSM 850 (PCL=5) 185 mA 210 mA DCS 1800/ PCS 1900 (PCL=0) 130 mA 135 mA Average current GPRS (2 TX,3 RX) E-GSM 900 / GSM 850 (PCL=5) 370 mA 395 mA DCS 1800/ PCS 1900 (PCL=0) 245 mA 270 mA Band 1 520 mA 615 mA Band 2 520 mA 615 mA Band 5 405 mA 530 mA Band 8 405 mA 530 mA Average current GSM in communication mode E-GSM 900 / GSM 850 (PCL=5) 35 mA 40 mA DCS 1800/ PCS 1900 (PCL=0) 35 mA 40 mA Average current GPRS (2 TX,3 RX) E-GSM 900 / GSM 850 (PCL=5) 55 mA 65 mA DCS 1800/ PCS 1900 (PCL=0) 55 mA 65 mA Band 1 100 mA 120 mA Band 2 100 mA 120 mA Band 5 95 mA 120 mA Band 8 95 mA 120 mA VBATT_PA Average current WCDMA in communication mode (Voice Call) VBATT Average current WCDMA in communication mode (Voice Call) 4117047 Rev 2.1 December 10, 2015 30 Product Technical Specification 3.5. Detailed Interface Specifications VGPIO The VGPIO output can be used to:  Pull-up signals such as I/Os  Supply the digital transistors driving LEDs  Act as a voltage reference for the ADC interfaces, ADC0 and ADC1 The VGPIO output is available when the AirPrime HL8518, HL8528 and HL8529 module is switched ON. 3.5.1. Electrical Characteristics The following table describes the electrical characteristics of the VGPIO interface. Table 13. VGPIO Electrical Characteristics Parameter Min Typ Max Remarks Voltage level (V) 1.7 1.8 1.9 Both active mode and sleep mode Current capability active mode (mA) - - 50 Power Management support up to 50mA output. Rise Time(ms) - - 1.5 Start-Up time from 0V 3.5.2. Pin Description The following table describes the pin description of the VGPIO interface. Table 14. VGPIO Pin Description Pin Number Signal Name I/O I/O Type Function 45 VGPIO O 1.8V (Power supply) GPIO voltage output 3.6. BAT_RTC The AirPrime HL8518, HL8528 and HL8529 modules provide an input/output to connect a Real Time Clock power supply. This pin is used as a back-up power supply for the internal Real Time Clock. The RTC is supported when VBATT is available but a back-up power supply is needed to save date and hour when VBATT is switched off. If VBATT is available, the back-up battery can be charged by the internal 1.8V power supply regulator. 4117047 Rev 2.1 December 10, 2015 31 Product Technical Specification 3.6.1. Detailed Interface Specifications Electrical Characteristics The following table describes the electrical characteristics of the BAT_RTC interface. Table 15. BAT_RTC Electrical Characteristics Parameter Minimum Typical Maximum Unit Input voltage -5% 1.8 +5% V Input current consumption - 2.5 - µA Output current capability 7 - - mA Output voltage -5% 1.8 +5% V Max charging current (@VBATT=3.7V) - 25 - mA Note: When used with the HL Series snap-in socket, or when compatibility with HL6528x is needed, Sierra Wireless recommends adding a 10µF capacitor to the BAT_RTC pin. 3.6.2. Pin Description The following table describes the pin description of the BAT_RTC interface. Table 16. BAT_RTC Pin Description Pin Number Signal Name I/O Function 21 BAT_RTC I/O Power supply for RTC backup 3.7. SIM Interface The AirPrime HL8518, HL8528 and HL8529 modules have one physical SIM interface, UIM1, which has optional support for dual SIM application with an external SIM switch. Refer to Section 5.8 Dual SIM Application for more information regarding dual SIM. The UIM1 interface allows control of a 1.8V/3V SIM and is fully compliant with GSM 11.11 recommendations concerning SIM functions. The five signals used by this interface are as follows:  UIM1_VCC: power supply  UIM1_CLK: clock  UIM1_DATA: I/O port  UIM1_RST: reset  UIM1_DET:SIM detection (optional) 4117047 Rev 2.1 December 10, 2015 32 Product Technical Specification 3.7.1. Detailed Interface Specifications Electrical Characteristics The following table describes the electrical characteristics of the UIM1 interface. Table 17. Electrical Characteristics of UIM1 Parameter Min Typ Max Remarks UIM1 Interface Voltage : (V) ( VCC, CLK, IO, RST ) 2.7 3.0 3.15 1.65 1.80 1.95 The appropriate output voltage is auto detected and selected by software. VIH : Input Voltage-High (VDD=1.8V) VDD*0.7 - 1.95 VIL : Input Voltage-Low (VDD=1.8V) 0 - VDD*0.2 VOH : Output Voltage-High (VDD=1.8V) VDD*0.7 - 1.95 VOL : Output Voltage-Low (VDD=1.8V) 0 - VDD*0.2 VIH : Input Voltage-High (VDD=3.0V) VDD*0.7 - 3.15 VIL : Input Voltage-Low (VDD=3.0V) 0 - VDD*0.2 VOH : Output Voltage-High (VDD=3.0V) VDD*0.7 - 3.15 VOL : Output Voltage-Low (VDD=3.0V) 0 - VDD*0.2 UIM1 DET 1.33 1.80 2.1 High active UIM1_VCC Current (mA) - - 10 Max output current in sleep mode = 3 mA UIM1_VCC Line Regulation (mV/V) - - 50 At Iout Max. UIM1_VCC Power-up Setting Time (µs) from power down - 10 - UIM1 Interface Voltage: (V) (VCC, CLK, IO, RESET ) 3.7.2. Pin Description The following table describes the pin description of the UIM1 interface. Table 18. UIM1 Pin Description Pin Number Signal Name I/O I/O Type Function 26 UIM1_VCC O 1.8V/3V UIM1 Power supply 27 UIM1_CLK O 1.8V/3V UIM1 Clock 28 UIM1_DATA I/O 1.8V/3V UIM1 Data 29 UIM1_RESET O 1.8V/3V UIM1 Reset 64 UIM1_DET I 1.8V UIM1 detection 4117047 Rev 2.1 Multiplex GPIO3 December 10, 2015 33 Product Technical Specification 3.7.3. Detailed Interface Specifications UIM1_DET UIM1_DET is used to detect and notify the application about the insertion and removal of a SIM device in the SIM socket connected to the main SIM interface (UIM1). When a SIM is inserted, the state of UIM1_DET transitions from logic 0 to logic 1. Inversely, when a SIM is removed, the state of UIM1_DET transitions from logic 1 to logic 0. The GPIO used for UIM1_DET is GPIO3. Enabling or disabling this SIM detect feature can be done using the AT+KSIMDET command. For more information about this command, refer to document [2] AirPrime HL6 and HL8 Series AT Commands Interface Guide. 3.7.4. Application 3.7.4.1. Reference Schematic J1 UIM1_VCC 1 6 AirPrime HL8518, HL8528 and HL8529 VGPIO 8 UIM1_CLK 3 UIM1_DET 4 UIM1_DATA 7 UIM1_RESET 2 2 1 NC_D2-6 VPP CC8 CLK CC4 I/O RST GND C2 470 nF 6 R1 4 100 kΩ 3 C1 1 470 pF 5 D2 VCC D1 3 4 6 2 GND 5 GND GND Figure 7. UIM1 Application Reference Schematic 3.7.4.2. USIM Socket Pin Description The following table describes the required USIM socket pins. Table 19. USIM Socket Pin Description Pin Number Signal Name Description 1 UIM1_VCC UIM1 Power supply 2 UIM1_RESET UIM1 Reset 3 UIM1_CLK UIM1 Clock 4 UIM1_DET UIM1 detection 5 GROUND GND 6 - - 7 UIM1_DATA UIM1 Data 8 VGPIO Power supply 4117047 Rev 2.1 December 10, 2015 34 Product Technical Specification 3.8. Detailed Interface Specifications USB The AirPrime HL8518, HL8528 and HL8529 modules have one USB interface. 3.8.1. Electrical Characteristics The following table describes the electrical characteristics of the USB interface. Table 20. Electrical Characteristics of USB Signal I/O I/O Type USB_D+ I/O USB_D- I/O USB data (DP, DM) I/O USB_VBUS I 3.8.2. Min. Typ. Max. Unit Analog 3.06 3.3 3.6 V Analog 3.06 3.3 3.6 V VIH: Input Voltage-High 2 - 3.2 V VIL: Input Voltage-Low -0.3 - 0.8 V VOL: Static Output Voltage-Low - - 0.45 V VOH: Static Output Voltage-High 2.45 - - V Voltage input 4.75 5.0 5.25 V Analog Analog Parameter USB_VBUS Input current consumption mA Pin Description The following table describes the pin description of the USB interface. Table 21. USB Pin Description Pin Number Signal Name I/O I/O Type Function 12 USB_D- I/O 3.3V USB data negative line pad 13 USB_D+ I/O 3.3V USB data positive line pad 16 USB_VBUS I 5V USB VBUS Note: When the 5V USB supply is not available, connect USB_VBUS to VBATT to supply the USB interface. 3.9. Electrical Information I/O The AirPrime HL8518, HL8528 and HL8529 modules support different groups of digital interfaces with varying current drain limits. The following table enumerates these interface groupings and enumerates the electrical characteristics of each digital interface. The DC characteristics of the pads are compatible with CMOS JEDEC standard EIA/JESD8-5. Table 22. Digital I/O Electrical Characteristics Parameter Min Typ Max VIL: Input voltage for general digital pad (V) -0.2 - VDD*0.2 4117047 Rev 2.1 Conditions December 10, 2015 35 Product Technical Specification Detailed Interface Specifications Parameter Min Typ Max Conditions VIH: Input voltage for general digital pad (V) VDD*0.7 - VDD + 0.2 Input / Output leakage Current (µA) - - ±0.7 VDD (V) 1.7 1.8 1.9 - - 0.2 IOL = + 0.1mA - - 0.35 IOL = +6.0mA VDD-0.35 - - IOH = - 6.0mA VDD-0.2 - - IOH = - 0.1mA - - 0.2 IOL = + 0.1mA - - 0.35 IOL = +4.0 mA VDD-0.35 - - IOH = - 4.0mA VDD-0.2 - - IOH = - 0.1mA - - 0.2 IOL = + 0.1mA - - 0.35 IOL = +2.0mA VDD-0.35 - - IOH = - 2.0mA VDD-0.2 - - IOH = - 0.1mA - - 0.2 IOL = + 0.1mA - - 0.35 IOL = +1.0mA VDD-0.35 - - IOH = - 1.0mA VDD-0.2 - - IOH = - 0.1mA - - 0.2 IOL = + 0.1mA - - 0.35 IOL = +1.0mA VDD-0.35 - - IOH = - 1.0mA VDD-0.2 - - IOH = - 0.1mA Driver Pad Class A VOLA: Output Voltage-Low (V) VOHA: Output Voltage-High (V) Driver Pad Class B VOLB: Output Voltage-Low (V) VOHB: Output Voltage-High (V) Driver Pad Class C VOLC: Output Voltage-Low (V) VOHC: Output Voltage-High (V) Driver Pad Class D VOLD: Output Voltage-Low (V) VOHD: Output Voltage-High (V) Driver Pad Class E VOLE: Output Voltage-Low (V) VOHE: Output Voltage-High (V) 3.10. General Purpose Input/Output (GPIO) The AirPrime HL8518, HL8528 and HL8529 modules provide 12 GPIOs, 2 of which have multiplexes. Table 23. GPIO Pin Description Pin Number Signal Name 1 I/O Power Supply Domain GPIO1 I/O 1.8V 10 GPIO2* I/O 1.8V 40 GPIO7 I/O 1.8V 41 GPIO8 I/O 1.8V 46 GPIO6 I/O 1.8V 52 GPIO10 I/O 1.8V 4117047 Multiplex Rev 2.1 December 10, 2015 36 Product Technical Specification Pin Number Signal Name 53 Detailed Interface Specifications I/O Power Supply Domain GPIO11 I/O 1.8V 54 GPIO15 I/O 1.8V 58 GPIO12 PWM2 I/O 1.8V 64 GPIO3 UIM1_DET I/O 1.8V 65 GPIO4 I/O 1.8V 66 GPIO5 I/O 1.8V * Multiplex This pin can be used to trigger the module to wake up from Sleep Mode. 3.11. Main Serial Link (UART1) The main serial link (UART1) is used for communication between the AirPrime HL8518, HL8528 and HL8529 modules and a PC or host processor. It consists of a flexible 8-wire serial interface that complies with RS-232 interface. The supported baud rates of the UART1 are 300, 1200, 2400, 4800, 9600, 19200, 38400, 57600, 115200, 230400, 460800, 500000, 750000, 921600, 1843200, 3000000, 3250000 and 6000000 bit/s. The signals used by UART1 are as follows:  TX data (UART1_TX)  RX data (UART1_RX)  Request To Send (UART1_RTS)  Clear To Send (UART1_CTS)  Data Terminal Ready (UART1_DTR)  Data Set Ready (UART1_DSR)  Data Carrier Detect (UART1_DCD)  Ring Indicator (UART1_RI) Note: Signal names are according to PC view. 3.11.1. Pin Description The following table describes the pin description of the UART1 interface. Table 24. UART1 Pin Description Pin # Signal Name* I/O* Description 2 UART1_RI O Signal incoming calls (voice and data), SMS, etc. 3 UART1_RTS I Wakes the module up when AT+KSLEEP=1 is used 4 UART1_CTS O Ready to receive AT commands 5 UART1_TX I Transmit data 6 UART1_RX O Receive data 7 UART1_DTR I (active low) Prevents the module from entering sleep mode, switches between data mode and command mode, and wakes the module up. 8 UART1_DCD O Signal data connection in progress 9 UART1_DSR O Signal UART interface is ON * 4117047 According to PC view. Rev 2.1 December 10, 2015 37 Product Technical Specification Detailed Interface Specifications 3.11.2. 8-wire Application VGPIO AirPrime HL8518, HL8528 and HL8529 Figure 8. Level shifter use TP UART1_RX TP UART1_CTS TP UART1_DSR TP UART1_DCD TP UART1_RI TP UART1_DTR TP UART1_TX TP UART1_RTS TP R R R R R R R R RXD CTS DSR DCD RI Customer Application DTR TXD RTS 8-wire UART Application Example 3.11.3. 4-wire Application VGPIO AirPrime HL8518, HL8528 and HL8529 Level shifter use TP TP UART1_CTS TP UART1_DSR TP DSR UART1_DCD TP DCD UART1_RI TP RI UART1_TX TP TXD UART1_RTS TP R R CTS Customer Application DTR UART1_DTR Figure 9. RXD UART1_RX R R RTS 4-wire UART Application Example 3.11.4. 2-wire Application VGPIO AirPrime HL8518, HL8528 and HL8529 4117047 RXD UART1_RX TP UART1_CTS TP CTS UART1_DSR TP DSR UART1_DCD TP DCD UART1_RI TP RI R UART1_DTR DTR UART1_RTS RTS UART1_TX Figure 10. Level shifter use TP TP R Customer Application TXD 2-wire UART Application Example Rev 2.1 December 10, 2015 38 Product Technical Specification Detailed Interface Specifications 3.12. POWER ON Signal (PWR_ON_N) A low level signal has to be provided to switch the AirPrime HL8518, HL8528 and HL8529 modules ON. It is internally connected to the permanent 1.8V supply regulator inside the HL8518, HL8528 and HL8529 via a pull-up resistor. Once VBAT is supplied to the module, this 1.8V supply regulator will be enabled and so the PWR_ON_N signal is by default at high level. The PWR_ON_N signal’s characteristics are listed in the table below. Table 25. PWR_ON_N Electrical Characteristics Parameter Min Input Voltage-Low (V) Typical Max - 0.51 Input Voltage-High (V) 1.33 - 2.2 Power-up period (ms) from PWR_ON_N falling edge 2000 - - PWR_ON_N assertion time (ms) 25 As PWR_ON_N is internally pulled up with 200kΩ, a simple open collector or open drain transistor must be used for ignition. Note: The software starts operating when the module is ON, but “AT Command Ready” will depend on whether UART or USB is used. PWR_ON_N PWR_ON_N assertion time > 25 ms Figure 11. PWR_ON_N Assertion Time VGPIO is an output from the module that can be used to check if the module is active.  When VGPIO = 0V, the module is OFF.  When VGPIO = 1.8V, the module is ON (it can be in idle, communication or sleep mode) Note: PWR_ON_N cannot be used to power the module off. To power the module off, use AT command AT+CPOF. 3.13. Reset Signal (RESET_IN_N) To reset the module, a low level pulse must be sent on the RESET_IN_N pin for 10ms. This action will immediately restart the AirPrime HL8518, HL8528 and HL8529 modules with the PWR_ON_N signal at low level. (If the PWR_ON_N signal is at high level, the module will be powered off.) As RESET_IN_N is internally pulled up, a simple open collector or open drain transistor can be used to control it. The RESET_IN_N signal will reset the registers of the CPU and reset the RAM memory as well, for the next power on. 4117047 Rev 2.1 December 10, 2015 39 Product Technical Specification Note: Detailed Interface Specifications As RESET_IN_N is referenced to the VGPIO domain (internally to the module), it is impossible to reset before the module starts or to try to use RESET_IN_N as a way to start the module. Another more costly solution would be to use MOS transistor to switch the power supply off and restart the power up procedure using the PWR_ON_N input line. Table 26. RESET_IN_N Electrical Characteristics Parameter Min Input Voltage-Low (V) Typical Max - 0.51 Input Voltage-High (V) 1.33 - 2.2 Power-up period (ms) from RESET_IN_N falling edge* 2000 - - * With the PWR_ON_N Signal at low level 3.14. ADC Two Analog to Digital Converter inputs, ADC0 and ADC1, are provided by the AirPrime HL8518, HL8528 and HL8529 modules. These converters are 10-bit resolution ADCs ranging from 0 to 1.2V. Typically, the ADCx input can be used to monitor external temperature. This is very useful for monitoring the application temperature and can be used as an indicator to safely power the application OFF in case of overheating (for Li-Ion batteries). 3.14.1. Electrical Characteristics The following table describes the electrical characteristics of the ADC interface. Table 27. ADC Electrical Characteristics Parameter Min Typ Max Remarks ADC Resolution (bits) - 10 - Input Voltage Range (V) 0 - 1.2 Update rate per channel (kHz) - - 125 Integral Nonlinearity (bits) - - ±2 LSB Offset Error (bits) - - ±1 LSB Gain 849 853 858 Input Resistance (MΩ) 1 - - Input Capacitance (pF) - 1 - General purpose input 3.14.2. Pin Description The following table describes the pin description of the ADC interface. Table 28. ADC Pin Description Pin Number Signal Name I/O I/O Type Description 25 ADC0 I 1.2V Analog to digital conversion 4117047 Rev 2.1 December 10, 2015 40 Product Technical Specification Detailed Interface Specifications Pin Number Signal Name I/O I/O Type Description 24 ADC1 I 1.2V Analog to digital conversion 3.15. PWM The AirPrime HL8518, HL8528 and HL8529 modules provide two PWM signals that can be used in conjunction with an external transistor for driving a vibrator, or a backlight LED. Each PWM uses two 7-bit unsigned binary numbers: one for the output period and one for the pulse width or the duty cycle. The relative timing for the PWM output is shown in the figure below. Figure 12. Relative Timing for the PWM Output 3.15.1. Electrical Characteristics The following table describes the electrical characteristics of the PWM interface. Table 29. PWM Electrical Characteristics Parameter Conditions Minimum Typical Maximum Unit VOH High impedance load -- 1.8 - V VOL - - - 0.2 V IPEAK - - - 8 mA Frequency - 25.6 - 1625 kHz Duty cycle - 1 - 99 % 3.15.2. Pin Description The following table describes the pin description of the PWM interface. Table 30. PWM Pin Description Pin Number Signal Name I/O I/O Type Description 57 PWM1 I/O 1.8V PWM output 58 PWM2 I/O 1.8V PWM output multiplexed with GPIO12 4117047 Rev 2.1 December 10, 2015 41 Product Technical Specification Detailed Interface Specifications 3.15.3. Application Both PWM1 and PWM2 signals can be used in conjunction with an external transistor for driving a vibrator, or a backlight LED. Figure 13. Example of an LED Driven by either the PWM1 or PWM2 Output The value of R607 can be harmonized depending on the LED (D605) characteristics. The recommended digital transistor to use for T601 is the DTC144EE from ROHM. Figure 14. Example of a BUZZER Driven by either the PWM1 or PWM2 Output The recommended MOS transistor to use for T1 is the RUM003N02 from ROHM; and the recommended diode to use for D1 is the BAS16W from NXP. 4117047 Rev 2.1 December 10, 2015 42 Product Technical Specification Detailed Interface Specifications 3.16. Clock Interfaces The AirPrime HL8518, HL8528 and HL8529 modules support two digital clock interfaces. 3.16.1. Electrical Characteristics The following table describes the pin description of the clock out interfaces. Table 31. 32.768Khz Clock Interface Pin Description Parameter Conditions Minimum Typical Maximum Unit Duty cycle - - 50 - % Clock frequency - -120ppm 32768 +120ppm Hz Table 32. 26Mhz Clock Interface Pin Description Parameter Conditions Minimum Typical Maximum Unit Duty cycle - 45 - 55 % Clock frequency - - 26 - MHz Period - 38.457 - 38.465 ns Clock accuracy - -100 - 100 ppm 3.16.2. Pin Description Table 33. Clock Interface Pin Description Pin Number Signal Name I/O I/O Type Description 22 26M_CLKOUT O 1.8V 26MHz Digital Clock output 23 32K_CLKOUT O 1.8V 32.768kHz Digital Clock output Enabling or disabling the clock out feature can be done using AT commands. For more information about AT commands, refer to document [2] AirPrime HL6 and HL8 Series AT Commands Interface Guide. 3.17. PCM The Digital Audio (PCM) Interface allows connectivity with standard audio peripherals. It can be used, for example, to connect an external audio codec. The programmability of this interface allows addressing a large range of audio peripherals. The signals used by the Digital Audio Interface are as follows:  PCM_SYNC: The frame synchronization signal delivers an 8 kHz frequency pulse that synchronizes the frame data in and the frame data out.  PCM_CLK: The frame bit clock signal controls data transfer with the audio peripheral.  PCM_OUT: The frame “data out” relies on the selected configuration mode.  PCM_IN: The frame “data in” relies on the selected configuration mode. 4117047 Rev 2.1 December 10, 2015 43 Product Technical Specification Detailed Interface Specifications The PCM interface is a high speed full duplex interface that can be used to send and receive digital audio data to external audio ICs. The Digital Audio Interface also features the following:  PCM master or slave  16 bits data word length, linear mode  MSB first  Configurable PCM bit clock rate on 256kHz, 384kHz or 512kHz  Long frame sync Refer to the following table for the electrical characteristics of the digital audio interface. 3.17.1. Electrical Characteristics Table 34. Digital Audio PCM Electrical Characteristics Signal Description Tsync_low + Tsync_high PCM_SYNC frequency 8 Khz Tsync_low + Tsync_high PCM_SYNC period 125 µs Tsync_low PCM_SYNC low time 124 µs Tsync_high PCM_SYNC high time 1 µs TCLK-cycle PCM_CLK period - 3.9 - µs TIN-setup PCM_IN setup time 59.6 - - ns TIN-hold PCM_IN hold time 12 - - ns TOUT-delay PCM_OUT delay time - - 21.6 ns TSYNC-delay PCM_SYNC output delay -24 - 31.2 ns VDD PCM Signaling Voltage 1.1 1.2 1.3 V VIH I/O Voltage input low 0.65*VDD - VDD+0.3 V VIL I/O Voltage input high -0.3 - 0.35*VDD V VOL I/O Voltage output low - - 0.45 V VOH I/O Voltage output high VDD-0.45 - - V IL I/O Leakage current - - ±0.7 µA 4117047 Rev 2.1 Minimum Typical Maximum December 10, 2015 Unit 44 Product Technical Specification Detailed Interface Specifications 3.17.2. PCM Waveforms The following figure shows the PCM timing waveform. Figure 15. PCM Timing Waveform 3.17.3. PCM Master Mode Figure 16. PCM Master Mode Timing Table 35. PCM Master Mode Parameters Symbol Description Min Typ Max Unit tI2Sbs1 PCM_CLK clock period T-4 T - ns tI2Sbs2 PCM_CLK low time T/2 – 20 T/2 - ns tI2Sbs3 PCM_CLK high time T/2 – 20 T/2 - ns tI2Sbs4 PCM_SYNC high begin after clock PCM_CLK high begin -24 - 2 x tCP + 12 ns tI2Sbs5 PCM_SYNC high end after PCM_CLK how end -24 - 2 x tCP + 12 ns tI2Sbs6 PCM_OUT invalid before PCM_CLK low-end - - 24 ns 4117047 Rev 2.1 December 10, 2015 45 Product Technical Specification Detailed Interface Specifications Symbol Description Min Typ Max Unit tI2Sbs7 PCM_OUT valid after PCM_CLK high begin - - tCP + 12 ns tI2Sbs8 PCM_IN setup time before PCM_CLK high end tCP + 50 - - ns tI2Sbs9 PCM_IN hold time after PCM_CLK low begin 12 - - ns Note: T corresponds to the audio sampling rate (48 kHz, 44.1 kHz, 32 kHz, 24 kHz, 22.05 kHz, 16 kHz, 12 kHz, 11.025 kHz and 8 kHz) and to the frame length (17 bit, 18bit, 32bit, 48bit or 64 bit). 3.17.4. PCM Slave Mode Figure 17. PCM Master Mode Timing Table 36. PCM Slave Mode Parameters Symbol Description Min Typ Max Unit tI2Sbs1 PCM_CLK clock period T - - n tI2Sbs2 PCM_CLK low time 120 - - ns tI2Sbs3 PCM_CLK high time 120 - - ns tI2Sbs4 PCM_SYNC high begin before PCM_CLK low begin (latching edge of PCM_CLK ) 2 x tCP + 17 - - ns tI2Sbs5 PCM_SYNC low begin before PCM_CLK low begin (latching edge of PCM_CLK ) 2 x tCP + 17 - - ns tI2Sbs6 PCM_OUT invalid before PCM_CLK rising edge (shifting edge of PCM_CLK ) - - 12 ns tI2Sbs7 PCM_OUT valid after PCM_CLK rising edge (shifting edge of PCM_CLK ) - - 3 x tCP + 12 ns tI2Sbs8 PCM_IN setup time before PCM_CLK falling edge tCP + 12 - - ns tI2Sbs9 PCM_IN hold time after PCM_CLK falling edge 24 - - ns Note: 4117047 T corresponds to the audio sampling rate (48 kHz, 44.1 kHz, 32 kHz, 24 kHz, 22.05 kHz, 16 kHz, 12 kHz, 11.025 kHz and 8 kHz) and to the frame length (17 bit, 18bit, 32bit, 48bit or 64 bit). Rev 2.1 December 10, 2015 46 Product Technical Specification Detailed Interface Specifications 3.17.5. Pin Description Table 37. Digital Audio PCM Pin Description Pin Number Signal Name I/O I/O Type Description 36 PCM_CLK O 1.8V PCM clock 35 PCM_SYNC O 1.8V PCM synchronization 34 PCM_IN I 1.8V PCM data in 33 PCM_OUT O 1.8V PCM data out 3.18. Debug Interfaces The AirPrime HL8518, HL8528 and HL8529 modules provide 2 interfaces for a powerful debug system. 3.18.1. Debug Port The AirPrime HL8518, HL8528 and HL8529 modules provides a 2-wire debug port interface, providing real-time instruction and data trace of the Modem Core. Table 38. SW Trace Pin Description Pin Number Signal Name* I/O* 44 DEBUG_TX O 1.8V Debug Transmit Data 51 DEBUG_RX I 1.8V Debug Receive Data * Note: I/O Type Function According to module view. It is strongly recommended to provide access through Test Points to this interface. 3.18.2. JTAG The JTAG interface provides debug access to the core of the AirPrime HL8518, HL8528 and HL8529 modules. These JTAG signals are accessible through solder-able test points. 3.18.2.1. Table 39. Electrical Characteristic JTAG Pin Connection Symbol Parameter Min Typ Max Unit tc1 JTAG_TCK clock period -- 38 - ns tc2 JTAG_TCK clock period high 12 - - ns tc3 JTAG_TCK clock period low 12 - - ns tc4 JTAG_TDI setup time to JTAG_TCK 12 - - ns tc5 JTAG_TDI hold time from JTAG_TCK 10 - - ns 4117047 Rev 2.1 December 10, 2015 47 Product Technical Specification Detailed Interface Specifications Symbol Parameter Min Typ Max Unit tc6 JTAG_TDO valid before JTAG_TCK low-end - 0 - s tc7 JTAG_TDO valid after JTAG_TCK high begin - 20 - ns 3.18.2.2. Figure 18. JTAG Timing Waveform 3.18.2.3. Table 40. JTAG Waveforms Pin Description JTAG Pin Description Pin Number Signal Name I/O I/O Type Function 47 TP1 O 1.8V Test Point 1 236 JTAG_RESET I 1.8V JTAG RESET 237 JTAG_TCK I 1.8V JTAG Test Clock 238 JTAG_TDO O 1.8V JTAG Test Data Output 239 JTAG_TMS I 1.8V JTAG Test Mode Select 240 JTAG_TRST I 1.8V JTAG Test Reset 241 JTAG_TDI I 1.8V JTAG Test Data Input 242 JTAG_RTCK O 1.8V JTAG Returned Test Clock Note: It is recommended to provide access through Test Points to this interface (for Failure Analysis debugging). All signals listed in table above shall be outputs on the customer board to allow JTAG debugging. 3.19. RF Interface The GSM RF interface of the AirPrime HL8518, HL8528 and HL8529 modules allows the transmission of RF signals. This interface has a 50Ω nominal impedance. 3.19.1. RF Connection A 50Ω (with maximum VSWR 1.1:1, and 0.5dB loss) RF track is recommended to be connected to standard RF connectors such as SMA, UFL, etc. for antenna connection. 4117047 Rev 2.1 December 10, 2015 48 Product Technical Specification Table 41. Detailed Interface Specifications RF Pin Connection Pin Number RF Signal Impedance VSWR Rx (max) VSWR Tx (max) 49 RF_MAIN 50Ω 3:1 3:1 3.19.2. RF Performances RF performances are compliant with the ETSI recommendation GSM 05.05. Table 42. RF Performance Frequency Band Typical Sensitivity (dBm) GSM850/EGSM -109 DCS/PCS -108 UMTS B1 -110 UMTS B2 -110 UMTS B5 -110 UMTS B8 -110 3.19.3. TX Burst Indicator (2G_TX_ON) The AirPrime HL8518, HL8528 and HL8529 modules provide a signal, 2G_TX_ON, for TX Burst indication. The 2G_TX_ON is a 1.8V signal and its status signal depends on the module transmitter state. Refer to the following table for the status of the 2G_TX_ON signal depending on the embedded module’s state. Table 43. Burst Indicator States Embedded Module State 2G_TX_ON During TX burst High No TX Low During TX burst, there is a higher current drain from the VBATT_PA power supply which causes a voltage drop. This voltage drop from VBATT_PA is a good indication of a high current drain situation during TX burst. The blinking frequency is about 217Hz. The output logic high duration, Tduration, depends on the number of TX slots and is computed as follows: T duration = T advance + (0.577ms x number of TX slots) + T delay Table 44. 2G_TX_ON Burst Characteristics Parameter Minimum Tadvance 30µs 4117047 Rev 2.1 Typical Maximum December 10, 2015 49 Product Technical Specification Detailed Interface Specifications Parameter Minimum Tdelay 5µs Figure 19. 2G_TX_ON State during TX Burst Table 45. 2G_TX_ON Burst Pin Description Typical Maximum Pin Number Signal Name I/O I/O Type Function 60 2G_TX_ON O 1.8V 2G TX burst indicator 4117047 Rev 2.1 December 10, 2015 50 4. Mechanical Drawings Figure 20. 4117047 Schematic Diagram Rev 2.1 December 10, 2015 51 Product Technical Specification Figure 21. 4117047 Mechanical Drawings Footprint Rev 2.1 December 10, 2015 52 5. Design Guidelines 5.1. Power-Up Sequence Apply a LOW level logic to the PWR_ON_N pin (pin 59); within 25ms, VGPIO will appear to be at 1.8V. Either a USB or UART1 interface could be used to send AT commands. Note that for USB connections, the time when AT commands can be sent will depend on the initialization time used for the USB connection with the USB host. Figure 22. Note: PWR_ON_N Sequence with VGPIO Information As PWR_ON_N is internally pulled up with 200kΩ, a simple open collector or open drain transistor must be used for ignition. The PWR_ON_N pin has the minimum assertion time requirement of 25ms, with LOW active. Once the valid power on trigger is detected, the PWR_ON_N pin status can be left open. VBATT has to ramp up within 32 ms to reach the value of 3.2V; otherwise, the module may not power up. Figure 23. 5.2. PWR_ON_N Sequence with Trampup Module Switch-Off AT command AT+CPOF enables the user to properly switch the AirPrime HL8518, HL8528 and HL8529 modules off. The PWR_ON signal must be set to high (inactive) before the AT+CPOF command is sent. Note: If the PWR_ON signal is active (low level) when the AT+CPOF command is sent, the module will not power off. If required, the module can be switched off by controlling the power supply. This can be used, for example, when the system freezes and no reset line is connected to the AirPrime HL8518, HL8528 and HL8529 modules. In this case, the only way to get control over the module back is to switch off the power line. 4117047 Rev 2.1 December 10, 2015 53 Product Technical Specification AT+CPOF Module is ON Design Guidelines PWR_ON_N Internal pull-up to 1V8 (must be High) Module is OFF 2 seconds VGPIO Figure 24. Power OFF Sequence for PWR_ON_N, VGPIO Note: PWR_ON_N is internally pulled up by 200kΩ to 1.8V. Caution: Ensure that no external pull-ups are applied on IO pins while the module is OFF. 5.3. Emergency Power OFF If required, the module can be switched off by controlling the RESET_IN_N pin (pin 11). This must only be used in emergency situations if the system freezes (not responding to AT commands). To perform an emergency power off, a low level pulse must be sent on the RESET_IN_N pin for 10ms while the PWR_ON signal is inactive (high level). This action will immediately shut the HL8518, HL8528 and HL8529 modules down and the registers of the CPU and RAM memory will be reset for the next power on. 5.4. Sleep Mode Management 5.4.1. Using UART AT command AT+KSLEEP enables sleep mode configuration. AT+KSLEEP=0:  The module is active when DTR signal is active (low electrical level).  When DTR is deactivated (high electrical level), the module will enter sleep mode after a while.  On DTR activation (low electrical level), the module wakes up. AT+KSLEEP=1:  The module determines when it enters sleep mode (when no more tasks are running).  “0x00” character on the serial link wakes the module up. AT+KSLEEP=2:  The module never enters sleep mode. 5.4.2. Using USB Use AT+KSLEEP=1 to allow the module to automatically enter sleep mode while the USB interface is in use. 4117047 Rev 2.1 December 10, 2015 54 Product Technical Specification 5.5. Design Guidelines Power Supply Design The AirPrime HL8518, HL8528 and HL8529 modules should not be supplied with voltage over 4.5V even temporarily or however briefly. If the system’s main board power supply unit is unstable or if the system’s main board is supplied with over 4.5V, even in the case of transient voltage presence on the circuit, the module’s power amplifier may be severely damaged. To avoid such issues, add a voltage limiter to the module’s power supply lines so that VBATT and VBATT_PA signal pads will never receive a voltage surge over 4.5V. The voltage limiter can be as simple as a Zener diode with decoupling capacitors as shown in the diagram below. Power Supply Figure 25. 5.6. + C405 150 µF C407 100 nF + C404 1.5 mF D405 D404 0.5 pF VBATT/VBATT_PA Voltage Limiter Example ESD Guidelines for SIM Card Decoupling capacitors must be added as close as possible to the SIM card connectors on UIM1_CLK, UIM1_RST, UIM1_VCC and UIM1_DATA signals to avoid EMC issues and to pass the SIM card type approval tests, according to the drawings below. A typical schematic for hardware SIM detection is provided below. Figure 26. 4117047 EMC and ESD Components Close to the SIM Rev 2.1 December 10, 2015 55 Product Technical Specification 5.7. Design Guidelines ESD Guidelines for USB CONNECTOR When the USB interface is externally accessible, it is required to have ESD protection on the USB_VBUS, USB_D+ and USB_D- signals. USB_VBUS USB_D+ USB_D- 1 2 2 3 Figure 27. 1 AirPrime HL8518, HL8528 and HL8529 3 ESD Protection for USB Note: It is not recommended to have an ESD diode with feedback path from USB_VBUS to either USB_D+ or USB_D-. 5.8. Dual SIM Application Using an external switch and GPIOs, the AirPrime HL8518, HL8528 and HL8529 modules can support Dual SIM Single Standby with fast network switching. Refer to document [2] AirPrime HL6 and HL8 Series AT Commands Interface Guide for related AT commands. Figure 28. 4117047 Reference Design for Dual SIM Application Rev 2.1 December 10, 2015 56 Product Technical Specification 5.9. Design Guidelines Radio Frequency Integration The AirPrime HL8518, HL8528 and HL8529 modules are equipped with an external antenna. A 50Ω line matching circuit between the module, the customer’s board and the RF antenna is required, for GSM feed path, as shown in the example below. Antenna Detection 15kΩ 1% VGPIO 100kΩ 1% ADC0 15kΩ 1% GPIO5 AirPrime HL8518, HL8528 and HL8529 22pF 33kΩ 1% 47nH 5.6kΩ 1% GSM antenna TBD RF_MAIN TBD Figure 29. Note: 4117047 TBD 33pF Rant 10kΩ GSM Antenna Connection with Antenna Detection Antenna detection circuit is optional. Rant is the equivalent DC terminating resistor of the antenna. Rant should be close to 10KΩ. Rev 2.1 December 10, 2015 57 6. Reliability Specification The AirPrime HL8518, HL8528 and HL8529 modules are tested against the Sierra Wireless Automotive Reliability Specification defined below. 6.1. Reliability Compliance The AirPrime HL8518, HL8528 and HL8529 modules connected on a development kit board application is compliant with the following requirements. Table 46. Standards Conformity Abbreviation Definition IEC International Electro technical Commission ISO International Organization for Standardization 6.2. Reliability Prediction Model 6.2.1. Life Stress Test The following tests the AirPrime HL8518, HL8528 and HL8529 modules’ product performance. Table 47. Life Stress Test Designation Condition Performance Test PT3T° & PT Standard: N/A Special conditions:  Temperature:  Class A: -30°C to +70°C  Class B: -40°C to +85°C  Rate of temperature change: ± 3°C/min  Recovery time: 3 hours Operating conditions: Powered Duration: 14 days 4117047 Rev 2.1 December 10, 2015 58 Product Technical Specification 6.2.2. Reliability Specification Environmental Resistance Stress Tests The following tests the AirPrime HL8518, HL8528 and HL8529 modules’ resistance to extreme temperature. Table 48. Environmental Resistance Stress Tests Designation Condition Cold Test Active COTA Standard: IEC 680068-2-1, Test Ad Special conditions:  Temperature: -40°C  Temperature variation: 1°C/min Operating conditions: Powered ON with a power cycle of 1 minute ON and 2 minutes OFF Duration: 3 days Resistance to Heat Test RH Standard: IEC 680068-2-2, Test Bb Special conditions:  Temperature: +85°C  Temperature variation: 1°C/min Operating conditions: Powered ON with a power cycle of 15 minutes ON and 15 minutes OFF Duration: 50 days 6.2.3. Corrosive Resistance Stress Tests The following tests the AirPrime HL8518, HL8528 and HL8529 modules’ resistance to corrosive atmosphere. Table 49. Corrosive Resistance Stress Tests Designation Condition Humidity Test HUT Standard: IEC 60068-2-3, Test Ca Special conditions:  Temperature: +65°C  RH: 95%  Temperature variation: 3 ± 0.6°C/min Operating conditions: Powered on, DUT is powered up for 15 minutes and OFF for 15 minutes Duration: 10 days 4117047 Rev 2.1 December 10, 2015 59 Product Technical Specification Reliability Specification Designation Condition Moist Heat Cyclic Test MHCT Standard: IEC 60068-2-30, Test Db Special conditions:  Upper temperature: +40 ± 2°C  Lower temperature: +25 ± 5°C  RH:  Upper temperature: 93%  Lower temperature: 95%  Number of cycles: 21 (1 cycle/24 hours) Operating conditions: Powered ON for 15 minutes during each 3 hours ramp up and 3 hours ramp down (in middle) for every cycle Duration: 21 days 6.2.4. Thermal Resistance Cycle Stress Tests The following tests the AirPrime HL8518, HL8528 and HL8529 modules’ resistance to extreme temperature cycling. Table 50. Thermal Resistance Cycle Stress Tests Designation Condition Standard: IEC 60068-2-14, Test Na Thermal Shock Test TSKT Special conditions:  Temperature: -30°C to +80°C  Temperature Variation: less than 30s  Number of cycles: 600  Dwell Time: 10 minutes Operating conditions: Un-powered Duration: 9 days Standard: IEC 60068-2-14, Test Nb Temperature Change TCH Special conditions:  Temperature: -40°C to +90°C  Temperature Variation: 3 ± 0.6°C/min  Number of cycles: 400  Dwell Time: 10 minutes Operating conditions: Un-powered Duration: 29 days 4117047 Rev 2.1 December 10, 2015 60 Product Technical Specification 6.2.5. Reliability Specification Mechanical Resistance Stress Tests The following tests the AirPrime HL8518, HL8528 and HL8529 modules’ resistance to vibrations and mechanical shocks. Table 51. Mechanical Resistance Stress Tests Designation Condition Standard: IEC 60068-2-6, Test Fc Special conditions: Sinusoidal Vibration Test SVT   Frequency range: 16 Hz to 1000 Hz  Acceleration:  5G from 16 to 62 Hz  3G from 62 to 200 Hz  1G from 200 to 1000 Hz  Sweep rate: 1 octave / cycle  Number of Sweep: 20 sweeps / axis  Sweep direction: ± X, ± Y, ± Z Displacement: 0.35mm (peak-peak) Operating conditions: Un-powered Duration: 42 days Standard: IEC 60068-2-64, Test Fh Special conditions: Random Vibration Test RVT  Frequency range: 10 Hz – 2000 Hz  Power Spectral Density in [(m/s²)²/Hz]  0.1 g2/Hz at 10Hz  0.01 g2/Hz at 250Hz  0.005 g2/Hz at 1000Hz  0.005 g2/Hz at 2000Hz  Peak factor : 3  Duration per Axis : 1 hr / axis Operating conditions: Un-powered Duration: 1 day Standard: IEC 60068-2-27, Test Ea Special conditions:  Shock Test 1:  Wave form: Half sine  Peak acceleration: 30g  Duration: 11ms  Number of shocks: 8  Direction: ±X, ±Y, ±Z  Shock Test 2:  Wave form: Half sine  Peak acceleration: 100g  Duration: 6ms  Number of shocks: 3  Direction: ±X, ±Y, ±Z Mechanical Shock Test MST Operating conditions: Un-powered Duration: 72 hours 4117047 Rev 2.1 December 10, 2015 61 Product Technical Specification 6.2.6. Reliability Specification Handling Resistance Stress Tests The following tests the AirPrime HL8518, HL8528 and HL8529 modules’ resistance to handling malfunctions and damage. Table 52. Handling Resistance Stress Tests Designation ESDC Test Condition Standard: JESD22-A114, JESD22-A115, JEDEC JESD 22 – C101C Special conditions:  HBM (Human Body Model) : 1kV (Class 1C)  MM (Machine Model): 200V (Class B)  CDM (Charged Device Model) : 250V (Class C1) Operating conditions: Powered Duration: 3 days Free Fall Test FFT Standard : IEC 60068-2-32, Test Ed Special conditions:  Number of drops: 2 drops per unit and per axis (total 12 drops)  Height: 1m Operating conditions: Un-powered Duration: 6 hours 4117047 Rev 2.1 December 10, 2015 62 7. Legal Information Note: 7.1. This section is only applicable to the AirPrime HL8528 and HL8529 modules. FCC Regulations FCC Caution: Any changes or modifications not expressly approved by the party responsible for compliance could void the user's authority to operate this equipment. IMPORTANT NOTE – FCC Radiation Exposure Statement: This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance 20cm between the radiator & your body. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter. The AirPrime HL8528 and HL8529 modules are currently pending modular approval for mobile applications. Once approved, integrators may use the AirPrime HL8528 and HL8529 in their final products without additional FCC certification if they meet the following conditions. Otherwise, additional FCC approvals must be obtained. 1. At least 20 cm separation distance between the antenna and the user’s body must be maintained at all times. 2. To comply with FCC regulations limiting both maximum RF output power and human exposure to RF radiation, the maximum antenna gain including cable loss in a mobile-only exposure condition must not exceed:  TBD dBi in the cellular band  TBD dBi in the PCS band 3. The AirPrime HL8528 and HL8529 must not transmit simultaneously with other collocated radio transmitters within a host device. 4. The RF signal must be routed on the application board using tracks with a 50Ω characteristic impedance. Basically, the characteristic impedance depends on the dielectric, the track width and the ground plane spacing. In order to respect this constraint, Sierra Wireless recommends using MicroStrip or StripLine structure and computing the Tracks width with a simulation tool (like AppCad shown in the figure below and that is available free of charge at http://www.agilent.com). 4117047 Rev 2.1 December 10, 2015 63 Product Technical Specification Legal Information If a multi-layered PCB is used, the RF path on the board must not cross any signal (digital, analog or supply). If necessary, use StripLine structure and route the digital line(s) "outside" the RF structure. An example of proper routing is shown in the figure below. Stripline and Coplanar design requires having a correct ground plane at both sides. Consequently, it is necessary to add some vias along the RF path. It is recommended to use Stripline design if the RF path is fairly long (more than 3cm), since MicroStrip design is not shielded. Consequently, the RF signal (when transmitting) may interfere with neighbouring electronics (AF amplifier, etc.). In the same way, the neighbouring electronics (microcontrollers, etc.) may degrade the reception performances. The GSM/GPRS connector is intended to be directly connected to a 50Ω antenna and no matching is needed. 5. A label must be affixed to the outside of the end product into which the AirPrime HL8528 and HL8529 modules are incorporated, with a statement similar to the following: This device contains FCC ID: N7NHL8528 (for devices using the HL8528) This device contains FCC ID: N7NHL8529 (for devices using the HL8529) 6. A user manual with the end product must clearly indicate the operating requirements and conditions that must be observed to ensure compliance with current FCC RF exposure guidelines. The end product with an AirPrime HL8528 and HL8529 modules may also need to pass the FCC Part 15 unintentional emission testing requirements and be properly authorized per FCC Part 15. Note: If this module is intended for use in a portable device, you are responsible for separate approval to satisfy the SAR requirements of FCC Part 2.1093. 7.2. IC Regulations IC Radiation Exposure Statement: This equipment complies with IC RSS-102 radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance 20cm between the radiator & your body. This device and its antenna(s) must not be co-located or operating in conjunction with any other antenna or transmitter. This Class B digital apparatus complies with Canadian ICES-003. Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type and maximum (or lesser) gain approved for the transmitter by Industry Canada. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p) is not more than necessary for successful communication. Labeling Requirements for the Host Device (from Section 7.2 of RSP-100, Issue 10, November 2014): The host device shall be properly labeled to identify the module within the host device. The Industry Canada certification label of a module shall be clearly visible at all times when installed in the host device, otherwise the host device must be labeled to display the Industry Canada certification number of the module, preceded by the words – Contains 4117047 Rev 2.1 December 10, 2015 64 Product Technical Specification Legal Information transmitter module, or the word – Contains, or similar wording expressing the same meaning, as follows: Contains transmitter module IC: 2417C-HL8528 (for devices using the HL8528) Contains transmitter module IC: 2417C-HL8529 (for devices using the HL8529) This device complies with Industry Canada license-exempt RSS standard(s). Operation is subject to the following two conditions: (1) this device may not cause interference, and (2) this device must accept any interference, including interference that may cause undesired operation of the device. Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio exempts de licence. This radio transmitter (identify the device by certification number, or model number if Category II) has been approved by Industry Canada to operate with the antenna types listed below with the maximum permissible gain and required antenna impedance for each antenna type indicated. Antenna types not included in this list, having a gain greater than the maximum gain indicated for that type, are strictly prohibited for use with this device.   TBD dBi in Band 2 TBD dBi in Band 5 Antenna types having a gain greater than the maximum gain indicated for that type are strictly prohibited for use with this device. 7.3. CE Regulation The minimum distance between the user and/or any bystander and the radiating structure of the transmitter is 20 cm. Assessment of compliance of the product with the requirements relating to the Radio and Telecommunication Terminal Equipment Directive (EC Directive 1999/5/EC) was performed by PHOENIX TESTLAB (Notified Body No.0700). 4117047 Rev 2.1 December 10, 2015 65 8. Conformance with ATEX The AirPrime HL8518, HL8528 and HL8529 modules are intended for use in telecommunication equipment. Table 53. ATEX Conformance Module 2G Bands 3G Bands Sum of All Capacitors* Sum of All Inductors* HL8518 EGSM/DCS Band I, Band VIII 140 µF 9.8 µH HL8528 GSM850/PCS Band II, Band V 142 µF 9.8 µH HL8529 N/A Band II, Band V 130 µF 9.8 µH * Including worst case tolerance rating 20%. The AirPrime HL8518, HL8528 and HL8529 modules have a maximum potential difference, internally generated, of 30 V. This voltage may be reached under fault conditions; for example, on the RF feed in 850 and 900 MHz bands when the module is emitting at its maximum power, and only under certain circumstances (for instance very poor VSWR). There are no cells, batteries or piezo electric devices (with the exception of commonly used radio parts such as quartz filters and SAW filters) inside the module. The maximum RF output is 2W/1W in bands 850/900 and 1800/1900 at the RF output of the module when connected to a 50 Ω load. Note: 4117047 The AirPrime HL8518, HL8528 and HL8529 are not certified for ATEX environment usage. Rev 2.1 December 10, 2015 66 9. Ordering information Table 54. Ordering Information Model Name Part Number Designation HL8518 1102589 HL8518 HL8528 1102576 HL8528 HL8529 1102578 HL8529 DEV-KIT 6000620 DEV-KIT, HL series 4117047 Rev 2.1 December 10, 2015 67 10. Terms and Abbreviations Abbreviation Definition ADC Analog to Digital Converter AGC Automatic Gain Control AT Attention (prefix for modem commands) CDMA Code Division Multiple Access CF3 Common Flexible Form Factor CLK Clock CODEC Coder Decoder CPU Central Processing Unit DAC Digital to Analog Converter DTR Data Terminal Ready EGNOS European Geostationary Navigation Overlay Service EMC Electromagnetic Compatibility EMI Electromagnetic Interference EN Enable ESD Electrostatic Discharges ETSI European Telecommunications Standards Institute FDMA Frequency-division multiple access GAGAN GPS aided geo augmented navigation GLONASS Global Navigation Satellite System GND Ground GNSS Global Navigation Satellite System GPIO General Purpose Input Output GPRS General Packet Radio Service GSM Global System for Mobile communications Hi Z High impedance (Z) IC Integrated Circuit IMEI International Mobile Equipment Identification I/O Input / Output LED Light Emitting Diode LNA Low Noise Amplifier MAX Maximum MIN Minimum MSAS Multi-functional Satellite Augmentation System N/A Not Applicable PA Power Amplifier PC Personal Computer PCB Printed Circuit Board PCL Power Control Level PLL Phase Lock Loop PWM Pulse Width Modulation 4117047 Rev 2.1 December 10, 2015 68 Product Technical Specification Terms and Abbreviations Abbreviation Definition QZSS Quasi-Zenith Satellite System RF Radio Frequency RFI Radio Frequency Interference RMS Root Mean Square RST Reset RTC Real Time Clock RX Receive SCL Serial Clock SDA Serial Data SIM Subscriber Identification Module SMD Surface Mounted Device/Design SPI Serial Peripheral Interface SW Software PSRAM Pseudo Static RAM TBC To Be Confirmed TBD To Be Defined TP Test Point TX Transmit TYP Typical UART Universal Asynchronous Receiver-Transmitter UICC Universal Integrated Circuit Card USB Universal Serial Bus UIM User Identity Module VBATT Main Supply Voltage from Battery or DC adapter VSWR Voltage Standing Wave Ratio WAAS Wide Area Augmentation System 4117047 Rev 2.1 December 10, 2015 69