Telit Communications S p A LN931NAG Data Card User Manual LN931 NAG HW guide

Telit Communications S.p.A. Data Card LN931 NAG HW guide

User Manual rev2.pdf

- 1 - LN931-NAG Hardware Specification
- 2 - CONTENTS 1. GENERAL DESCRIPTION....................................................................4 1.1 SYSTEM MAIN FEATURE ....................................................................5 1.2 SYSTEM BLOCK DIAGRAM ................................................................8 1.3 PIN DEFINITION .....................................................................................9 1.4 PLATFORM CONNECTION DESIGN ............................................... 14 2. HARDWARE FEATURES ................................................................... 22 2.1 MOBILE DATA MODEM ............................................................................ 22 2.2 RF TRANSCEIVER ..................................................................................... 23 2.3 POWER MANAGEMENT IC ...................................................................... 23 2.4 ANTENNA DESIGN .................................................................................... 24 3. MECHANICAL SPECIFICATIONS .................................................... 27 3.1 OVERVIEW .................................................................................................. 27 3.2 MECHANICAL CONSTRAINTS ................................................................ 27 3.3 M.2 CARD ASSEMBLY .............................................................................. 28 3.4 CONNECTOR ASSEMBLY ....................................................................... 29 4. ELECTRICAL SPECIFICATIONS ...................................................... 30 4.1 RECOMMENDED OPERATING CONDITIONS ...................................... 30 4.2 POWER CONSUMPTION .......................................................................... 30 5. RF PERFORMANCE SPECIFICATIONS .......................................... 31
- 3 - 5.1 RF MAXIMUM TX POWER SPECIFICATIONS ...................................... 31 5.2 RF MIN. RX SENSITIVITY SPECIFICATIONS ........................................ 32 6. SOFTWARE REQUIREMENTS.......................................................... 33
41. General Description T77H468 is designed to enable wireless data connectivity for notebook computer or any other device compatible with the PCI Express M.2 Specification 3042 type slot. T77H468 is the data card solution that delivers wireless wide-area network (WWAN) connectivity for the LTE, UMTS (HSDPA/HSUPA/HSPA+/DC-HSPA+), CDMA 1xRTT/CDMA EV-DOrA/ CDMA EVDO-rB, GSM/GPRS/EDGE and GPS/Glonass protocols in one hardware configuration. WTR1605L SKU NA-1-S3 G C W L QUAD BAND BC 0,1 Band 1,2,4, 5,8 Band 2,4,5,13,17,25 TX_LB1 17 TX_LB2 850/900 TX_LB3 13 TX_LB4 0 5,8 5, 8r TX_MB1 4 4 TX_MB2 1800/1900 TX_MB3 1 1,2 1r, 2,25 TX_MB4 TX_HB PRX_LB1 13,17 PRX_LB2 850/900 8 PRX_LB3 0 5 5 PRX_MB1 1800/1900 PRX_MB2 1 2 2 PRX_MB3 1 PRX_HB 4 4 DRX_LB1 0 5,8 5 DRX_LB2 17 DRX_LB3 13 DRX_MB 1 2 2,25 DRX_HB 1,4 4
51.1 System Main Feature Feature Description Physical PCI express M.2 module, size 3042, 75Pin golden finger Electrical Single VCC supply (3.3V+/-5% follow M.2 standard) Dimension Dimensions (L × W × H): 42 mm × 30 mm × 2.3 mm, maximum height=2.38mm (add PCB tolerance=0.08mm) Shielding design Shield case on board design, no additional shielding requirement Weight Approximately 6.2g USIM Off-board USIM connector supported Operating Bands WCDMA/HSDPA/HSUPA/HSPA+ operating bands: Band 1: 1920 to 1980 MHz (UL), 2110 to 2170 MHz (DL) Band 2: 1850 to 1910 MHz (UL), 1930 to 1990 MHz (DL) Band 4: 1710 to 1755 MHz (UL), 2110 to 2155 MHz (DL) Band 5: 824 to 849 MHz (UL), 869 to 894 MHz (DL) Band 8: 880 to 915 MHz (UL), 925 to 960 MHz (DL) GSM operating bands: GSM850: 824 to 849 MHz (UL), 869 to 894 MHz (DL) E-GSM900: 880 to 915 MHz (UL), 925 to 960 MHz (DL) DCS1800: 1710 to 1785 MHz (UL), 1805 to 1880 MHz (DL) PCS1900: 1850 to 1910 MHz (UL), 1930 to 1990 MHz (DL) LTE FDD operating bands: Band 2: 1850 to 1910 MHz (UL), 1930 to 1990 MHz (DL) Band 4: 1710 to 1755 MHz (UL), 2110 to 2155 MHz (DL) Band 5: 824 to 849 MHz (UL), 869 to 894 MHz (DL) Band 13: 777 to 787 MHz (UL), 746 to 756 MHz (DL) Band 17: 704 to 716 MHz (UL), 734 to 746 MHz (DL) Band 25: 1850 to 1915 MHz (UL), 1930 to 1995 MHz (DL) CDMA 1X/CDMA EV-DOrB operating bands: BC0: 824 to 849 MHz (UL), 869 to 894 MHz (DL) BC1: 1850 to 1910 MHz (UL), 1930 to 1990 MHz (DL) Diversity/2nd Rx All WCDMA/HSDPA/HSUPA/HSPA+ operating bands All CDMA 1X/CDMA EVDO operating bands All LTE operating bands GNSS GPS: L1 (1575.42MHz) GLONASS: L1 (1602MHz) USIM Voltage Support 1.8V and 2.85V, and auto detects follow SIM card type Antenna connectors MAIN and AUX(supports Diversity and GPS simultaneously)
6Throughput GPRS: DL 85.6 kbps /UL 85.6 kbps EDGE: DL 236.8 kbps/UL 236.8 kbps WCDMA CS: DL 64 kbps /UL 64 kbps WCDMA PS: DL 384 kbps /UL 384 kbps HSPA+: DL 21.6 Mbps /UL 5.76 Mbps DC-HSPA+ :DL 42 Mbps/UL 5.76 Mbps CDMA 1x: DL 153.6 kbps/UL 153.6 kbps EVDO Rev.A: DL 3.1 Mbps /UL 1.8 Mbps EVDO Rev.B: DL 14.7 Mbps/UL 5.4 Mbps LTE FDD:DL:100 Mbps/UL 50 Mbps @20M BW cat3 LTE air interface LTE R9, Cat3, 20MHz BW (FDD: up to 100 Mbps downlink, 50 Mbps uplink)  FDD: up to 100 Mbps downlink, 50 Mbps uplink  1.4 to 20 MHz RF bandwidth  1X2 MISO (1Tx and 2Rx for two downlinks simultaneously)  IPv6, QoS WCDMA/HSPA air interface  R99: All modes and data rates for WCDMA FDD  R5 HSDPA PS data speeds up to 7.2 Mbps on the downlink  R6 HSUPA E-DCH data rates of up to 5.76 Mbps for 2 ms TTI (UE category 6) uplink  R7 HSPA+ Downlink 64 QAM; up to 21 Mbps 1X2 MISO (1Tx and 2Rx for two downlinks simultaneously) 2Rx with 16 QAM; up to 28 Mbps Uplink 16 QAM; up to 5.76 Mbps  R8 DC-HSPA+ Downlink dual carrier with 64 QAM; up to 42 Mbps CDMA air interface  1xRTT 153.6 kbps forward link, 153.6 kbps reverse link  1xEV-DOr0 High-speed peak data rates – 2.4 Mbps forward link; 153 kbps reverse link  1xEV-DOrA High-speed peak data rates – 3.1 Mbps forward link; 1.8 Mbps reverse link  1xEV-DOrB
7High-speed peak data rates – 14.7 Mbps forward link; 5.4 Mbps reverse link GSM / GPRS / EDGE air interface  R99 Circuit-switched data: 9.6 k; 14.4 k  GPRS Packet-switched data: DTM (simple class A) operation Multi-slot class 12 data services CS schemes – CS1, CS2, CS3, and CS4 GEA1, GEA2, and GEA3 ciphering Maximum of four Rx timeslots per frame  EDGE  E2 power class for 8 PSK DTM (simple class A), multislot class 12 Downlink coding schemes – CS 1-4, MCS 1-9 Uplink coding schemes – CS 1-4, MCS 1-9 BEP reporting SRB loopback and test mode B 8-bit and 11-bit RACH PBCCH support One-phase/two-phase access procedures Link adaptation and IR NACC, extended UL TBF GNSS  GPS Standalone, MS-A, MS-B, and XTRA GPS  Glonass GLONASS standalone mode GLONASS capability increases the number of satellites available to the positioning engine, resulting in an expanded area of coverage over traditional GPS receivers
81.2 System Block Diagram Figure 1-1 System block diagram Chipsets: MDM9615+WTR1605L+PM8018
91.3 Pin definition 1.3.1 Golden finger Pin sequence Figure 1-2 shows the sequence of pins on the 75-pin signal interface of M.2 3042. 1.3.2 Pin definition Table 1-1 M.2 Pin definition No. M.2 Pin name I/O Description Platform connection 1 CONFIG_3 O Connected to Ground internally. Refer to section ‘1.4.1 Configuration Pins ’ 2 3.3V PI Power supply (3.3V+/-5%) Refer to section ‘1.4.2 Power and ground’ 3 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 4 3.3V PI Power supply (3.3V+/-5%) Refer to section ‘1.4.2 Power and ground’ 5 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 6 Full_Card_Power_Off (0/1.8V or 0/3.3V) I When it is Low, M.2 card powers off. When it is High, M.2 card powers on. Pull down on card, should be tolerant of 3.3V Refer to section ‘1.4.3 Full_Card_Power_Off’ 7 USB_D+ IO USB Data+ defined in the Refer to section ‘1.4.4
10 USB 2.0 Specification. USB interface’ 8 W_DISABLE#1 (0/3.3V) I Active low signal used by the host to turn on/off radio operation. When it is Low, radio off. When it is High, radio on. Refer to section ‘1.4.5 W_DISABLE#’ 9 USB_D- IO USB Data- defined in the USB 2.0 Specification. Refer to section ‘1.4.4 USB interface’ 10 LED#1 O Active low signal, used to allow the M.2 card to provide status indicators via LED devices that will be provided by the system. Refer to section ‘1.4.6 LED Indication’ 11 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 12~19 Notch - Notch 20 AUDIO_0 - Don’t need to connect to platform; Connect to MDM9xxx PRIM_PCM_CLK Reserve for future extension, please contact with us if need to use these Pins 21 CONFIG_0 O Not connect internally. Refer to section ‘1.4.1 Configuration Pins ’ 22 AUDIO_1 - Don’t need to connect to platform; Connect to MDM9xxx PRIM_PCM_SYNC Reserve for future extension, please contact with us if need to use these Pins 23 WoWWAN (0/1.8V) O WWAN to wake up the host, It is active low. Refer to section ‘1.4.7 WoWWAN’ 24 AUDIO_2 - Don’t need to connect to platform; Connect to MDM9xxx PRIM_PCM_DIN Reserve for future extension, please contact with us if need to use these Pins 25 DPR (0/1.8V) I Hardware pin for BodySAR Detection H: No TX power backoff (default) L: TX power backoff Refer to ‘1.4.8 DPR’ 26 W_Disable2 I GPS disable: H:Turn on GPS/GLONASS (default) L: Turn off GPS/GLONASS Refer to section ‘1.4.5 W_DISABLE#’ 27 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 28 AUDIO_3 - Don’t need to connect to platform; Connect to MDM9xxx PRIM_PCM_DOUT Reserve for future extension, please contact with us if need to use these Pins
1129 SSIC-TxN - Don’t need to connect to platform; Connect to MDM9xxx SPI_MOSI Reserve for future extension, please contact with us if need to use these Pins 30 UIM-RESET O UIM-RESET Refer to section ‘1.4.9 USIM’ 31 SSIC-TxP - Don’t need to connect to platform; Connect to MDM9xxx SPI_MISO Reserve for future extension, please contact with us if need to use these Pins 32 UIM-CLK O UIM-CLK Refer to section ‘1.4.9 USIM’ 33 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 34 UIM-DATA IO UIM-DATA Refer to section ‘1.4.9 USIM’ 35 SSIC-RxN - Don’t need to connect to platform; Connect to MDM9xxx SPI_CS_N Reserve for future extension, please contact with us if need to use these Pins 36 UIM-PWR O UIM-PWR Refer to section ‘1.4.9 USIM’ 37 SSIC-RxP - Don’t need to connect to platform; Connect to MDM9xxx SPI_CLK Reserve for future extension, please contact with us if need to use these Pins 38 N/C - Not connect N/A for WWAN 39 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 40 GNSS_SCL (0/1.8V*) IO I2C_CLK, Don’t need to connect to platform Reserve for future extension, please contact with us if need to use these Pins 41 NC - Don’t need to connect to platform; Connect to MDM9xxx UART_CTS_N Reserve for future extension, please contact with us if need to use these Pins 42 GNSS_SDA (0/1.8V*) IO I2C_DATA, Don’t need to connect to platform Reserve for future extension, please contact with us if need to use these Pins 43 NC - Don’t need to connect to platform; Connect to MDM9xxx UART_RFR_N Reserve for future extension, please contact with us if need to use these Pins 44 GNSS_IRQ (0/1.8V*) IO I2C_IRQ, Don’t need to connect to platform Reserve for future extension, please contact with us if need to use these Pins
12 45 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 46 SYSCLK (0/1.8V*) IO Don’t need to connect to platform; Connect to PMIC XO Reserve for future extension, please contact with us if need to use these Pins 47 NC - Don’t need to connect to platform; Connect to MDM9xxx MDM_UART_TX Reserve for future extension, please contact with us if need to use these Pins 48 TX_BLANKING - Don’t need to connect to platform; Reserve for future extension, please contact with us if need to use these Pins 49 NC - Don’t need to connect to platform; Connect to MDM9xxx MDM_UART_RX Reserve for future extension, please contact with us if need to use these Pins 50 NC - Not connect N/A for WWAN 51 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 52 NC - Not connect N/A for WWAN 53 NC - Not connect N/A for WWAN 54 NC - Don’t need to connect to platform; Connect to MDM9xxx GPIO# internally Foxconn use internally to separate different SKus 55 NC - Not connect N/A for WWAN 56 NC - Don’t need to connect to platform; Connect to MDM9xxx GPIO# internally Foxconn use internally to separate different SKus 57 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 58 NC - Don’t need to connect to platform; Connect to MDM9xxx GPIO# internally Foxconn use internally to separate different SKus 59 ANTCTL0 (0/1.8V) O Tunable antenna control signal, bit 0 Refer to section ‘1.4.10 Antenna Control’ 60 COEX3 (0/1.8V) - For LTE/WLAN co-existence; LTE_WLAN_PRIORITY Refer to section ‘1.4.11 Coexistence’ 61 ANTCTL1 (0/1.8V) O Tunable antenna control signal, bit 1 Refer to section ‘1.4.10 Antenna Control’ 62 COEX2 (0/1.8V) - For LTE/WLAN co-existence; LTE_FRAME_SYNC Refer to section ‘1.4.11 Coexistence’ 63 ANTCTL2 (0/1.8V) O Tunable antenna control Refer to section ‘1.4.10
13 signal, bit 2 Antenna Control’ 64 COEX1 (0/1.8V) - For LTE/WLAN co-existence; LTE_ACTIVE Refer to section ‘1.4.11 Coexistence’ 65 ANTCTL3 (0/1.8V) O Tunable antenna control signal, bit 3 Refer to section ‘1.4.10 Antenna Control’ 66 SIM Detect I SIM_SWP Refer to section ‘1.4.9 USIM’ 67 Reset# (0/1.8V) I System reset Refer to section ‘1.4.12 RESET#’ 68 SUSCLK(32kHz) (0/3.3V) I Reserve Qualcomm MDM9xxx solution don’t need external SUSCLK 69 CONFIG_1 O Connected to Ground internally. Refer to section ‘1.4.1 Configuration Pins ’ 70 3.3Vaux PI Power supply (3.3V+/-5%) Refer to section ‘1.4.2 Power and ground’ 71 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 72 3.3Vaux PI Power supply (3.3V+/-5%) Refer to section ‘1.4.2 Power and ground’ 73 GND PI Ground Refer to section ‘1.4.2 Power and ground’ 74 3.3Vaux PI Power supply (3.3V+/-5%) Refer to section ‘1.4.2 Power and ground’ 75 CONFIG_2 O Connected to Ground internally. Refer to section ‘1.4.1 Configuration Pins ’
14 1.4 Platform connection design 1.4.1 Configuration Pins The M.2 module provides 4 configuration pins. T77H468 is configured as WWAN-SSIC 0, refer to PCIe M.2_Rev0.7a. Item Module configuration decodes Module type Port configuration Config Config_0 Config_1 Config_2 Config_3 WWAN-SSIC 0 Pin No. 21 69 75 1 State NC GND GND GND 1.4.2 Power and ground (1) Power Rail Parameters Parameter Min Type Max Units Operating voltage 3.135 3.3 3.465 Vdc The operating voltage was defined in PCIe M.2_Rev0.7a standard as 3.3V+/-5%. (2) 3.135 V is the minimum voltage supplied to LTE M.2 card by the host platform, and VCC must never be under 3.135 V in any case. As our experiment, if we set the VCC=3.0V, the M.2 card will power off when M.2 card working at +23dBm continue mode. (3) Whenever the M.2 module works at 2G mode, the module transmits at the maximum power (like +33dBm), the transient peak current may reach to 2.5 A. We recommended design the VCC supply of host as below: Remark: When the system power restarts, reserve R1 to discharge power. (4) The LTE M.2 module provides 5 power pins and 11 Ground pins. To ensure that the LTE module works normally, all the pins must be connected.
15 1.4.3 Full_Card_Power_Off The M.2 LTE module can be controlled to power on/off by the Full_Card_Power_Of pin. Item State M.2 card state 1 Low Powers off, It’s internally pulled down by 100K ohm resistor 2 High Powers on, it is 3.3V tolerant but can be driven by either 1.8V or 3.3V GPIO. The recommended connections as below 1.4.4 USB interface T77H468 module is compliant with USB2.0 in all three modes (Low speed, Full speed, and high speed). When two devices are connected via a USB interface, one of the devices must act as a host, and the other device must act as a peripheral. The host is responsible for initiating and controlling traffic on the bus. Figure 1-4-4 USB2.0 interface
16 1.4.5 W_DISABLE# This control setting is implementation-specific and represents the collective intention of the host software to manage radio operation. T77H468 provides a hardware pin (W_DISABLE#) to disable or enable the radio. Besides, the radio can also be enabled or disabled through software AT commands. Item State Function (WWAN state) W_DISABLE#1 Low WWAN Disabled (no RF operation allowed) High WWAN Enabled (RF operation allowed), internally pull up W_DISABLE#2 Low GPS Disabled (no RF operation allowed) High GPS Enabled (RF operation allowed), internally pull up 1.4.6 LED Indication The LED signal is provided to enable wireless communication add-in cards to provide status indications to users via system provided indicators (1) State of the LED# pin Item State Definition Interpretation 1 Low The LED is emitting light. Radio is capable of transmitting. 2 High The LED is emitting no light. Radio is incapable of transmitting. (2) Typical LED Connection in Platform/System .
17 1.4.7 WoWWAN The WAKE_ON_WWAN# signal is for power saving. •LTE module always listening at very low power in idle mode •LTE module will wake up mother board via ‘WoWWAN’ signal. •The platform will power on when triggered by the LTE module. The WAKE_ON_WWAN# signal is used to wake up the host. It is open drain and should be pulled up at the host side. When the WWAN needs to wake up the host, it will output a one second low pulse, shown in Figure 1-4-6. Typical Connection in Platform/System
18 1.4.8 DPR (Dynamic Power Reduction) The optional DPR signal is used by wireless devices to assist in meeting regulatory SAR (Specific Absorption Rate) requirements for RF exposure. The signal is provided by a host system proximity sensor to the wireless device to provide an input trigger causing a reduction in the radio transmit output power. The required value of the power reduction will vary between different host systems and is left to the host platform OEM and card vendor to determine, along with the specific implementation details. The assertion and de-assertion of DPR is asynchronous to any system clock. All transients resulting from the proximity sensor need to be de-bounced by system circuitry. (1) State of the DPR Item State Definition Interpretation 1 Low Enable the SAR power back off. Radio is capable of transmitting. 2 High Disable the SAR power back off, internally pull up Radio is incapable of transmitting. (2) Typical Connection in Platform/System Remark: a. The proximity sensor was controlled by the platform side. b. After DPR pin becomes low level, you can set the MAX TX power by AT commands..
19 1.4.9 USIM The UIM contains parameters necessary for the WWAN device’s operation in a wireless wide area network radio environment. The UIM signals are described in the following paragraphs for M.2 add-in cards that support the off-card UIM interface. (1) USIM card socket It is recommended to take electrostatic discharge (ESD) protection measures near the USIM card socket. The USIM socket should be placed near the NGFF interface (<100 mm), because a long circuit may impact signal quality. (2) UIM-PWR UIM_PWR power supply can supply 1.8 V and 2.85 V power to UIM card and auto detects follow SIM card type (3) SIM Detect This signal is used to detect the insertion and removal of a SIM device in the SIM socket. With a Normal Short SIM Card connector, PUSH-PUSH type, the detect switch is normally shorted to ground when no SIM card is inserted. When the SIM is inserted, the SIM_DETECT will transition from logic 0 to logic 1 state. The rising edge will indicate insertion of the SIM card. When the SIM is pulled out, the SIM_DETECT will transition from logic1 to logic 0. This falling edge will indicates the pulling out of the SIM card. The M.2 module monitoring this signal will treat the rising/falling edge or the actual logic state as an interrupt, that when triggered, the module will act accordingly.
20 1.4.10 Antenna Control T77H468 provides GPIO control signals for external antenna tuner application. The function is under development for customization. ANTCTRL (0-3) are provided to allow for the implementation of antenna tuning solutions. The number antenna control lines required will depend on the application and antenna/band requirements. Foxconn general design for WWAN module with two control signals. ANTCTL0 ANTCTL1 Frequency (MHz) Band support 0 0 880 ~ 960 Band8 (WCDMA) + GSM900 + High Bands 0 1 791 ~ 894 Band5 (WCDMA, LTE) + GSM850 + High Bands 1 0 746 ~787 Band13 (LTE) + High Bands 1 1 704 ~746 Band17 (LTE) + High Bands 1.4.11 Coexistence COEX1, COEX2 and COEX3 are provided to allow for the implementation of wireless coexistence solutions between the radio(s) on the M.2 Card and other off-card radio(s). These other radios can be located on another M.2 Card located in the same host platform or as alternate radio implementations (for example, using a PCI Express M.2 CEM or a proprietary form-factor add-in solution). Reserve for future extension, please contact with us if need to use these Pins. Item Signal name GPIO from MDM9x15 Description COEX1 LTE_ACTIVE GPIO_67 TBD COEX2 LTE_FRAME_SYNC GPIO_66 TBD COEX3 LTE_WLAN_PRIORITY GPIO_65 TBD
21 1.4.12 RESET# Asynchronous RESET# pin, active low. Whenever this pin is active, the modem will immediately be placed in a Power On reset condition. Care should be taken not to activate this pin unless there is a critical failure and all other methods of regaining control and/or communication with the WWAN sub-system have failed. The Reset# signal is relatively sensitive, it is recommended to install one capacitor (10~100pF) near to the M.2 card pin.
22 2. Hardware features T77H468 consists of the following key engine components, in addition to the required front-end RF and other discrete components. Modem engine ■ Soft Baseband: MDM-9615 ■ RF: WTR1605L ■ Power: PM8018 Connectivity engine ■ USB: USB2.0 high-speed ■ USIM: located off board ■ Antenna: connectors for the off board antennas 2.1 Mobile Data Modem The MDM9615 chipset solution integrates powerful digital signal processors (DXPs) into any market-proven wireless modem, offering increased processing capacity and lower power consumption. They are complete system solutions that operate on networks worldwide. The major functions of MDM9615 used on T77H468 are listed below: ❒ Processor: - Manufactured in 28nm CMOS process - System uP (Cortex-A5+L2 cache at up to 550MHz) - ARM7 processor for the RPM ❒ Memory: - External memory (16KB for security) EBI1: 1Gb LPDDR1 - External memory EBI2: 2Gb NAND flash ❒ Air interface: - WCDMA (R99, HSDPA, HSUPA, HSPA+, DC-HSPA+) - CDMA (1x, EV-DOr0, EV-DOrA, EV-DOrB) - LTE (R9 Cat3, FDD) - GSM (GSM R99, GPRS, EDGE) - GPS/Glonass ❒ Advance RX operation: - Mobile receive diversity (WCDMA, CDMA and LTE)
23 ❒ Connectivity: - USB 2.0 HS with built-in USB PHY - UART interface - UIM support (dual voltage) 2.2 RF transceiver The WTR1605 device is a highly integrated and versatile RF CMOS transceiver IC that can be used in multimode, multiband applications – including Rx diversity. The WTR1605 IC is the RF transceiver IC within compatible Qualcomm MDM9615 chipsets. The WTR1605 IC integrates advanced receive and transmit features into a 4.91 × 5.47 × 0.63 mm package to simplify handset design, minimize parts count, and reduce DC power consumption. These advanced Rx/Tx features include:  Multimode, multiband RF transceiver functions:  GNSS receiver functions  Fully integrated LO generation and distribution circuits to support all the RF operating band and mode combinations  Primary, diversity, and GNSS receivers that can operate simultaneously  Tx power detector for monitoring the transmit power levels  The GSM receiver can share the secondary paths with CDMA, WCDMA, and LTE diversity receivers  Qualcomm’s intelligent receiver technology for CDMA modes:  Low operating voltages that help save battery current and allows the WTR IC power to be supplied by the PMIC’s switching mode power supply (SMPS) circuits for even greater power savings 2.3 Power management IC T77H468 system uses the Qualcomm PM8018. Qualcomm has worked with Maxim Integrated Products Inc. to develop a custom PMIC solution for use with the T77H468 platform.
24 2.4 Antenna Design 2.4.1 Antenna specification T77H468 also provides connectivity for off board antennas. The antennas and their connection interface for this device satisfy the requirements specified in the PCI Express M.2 Specification Revision 0.7a, Version 1.0 standard. The antenna elements are typically integrated into the notebook/ultrabook /tablet and connected to T77H468 module via flexible RF coaxial cables. T77H468 provides two RF connectors (MHF type), one for the primary transmitter/receiver port and the other for the diversity receiver and GNSS. To ensure stable RF performance, customer must assemble adequate antenna according to the antenna specification. Table 2-1 Main antenna specifications Parameter Min. Typ. Max. Units Notes Cable loss / / 0.5 dB Maximum loss to antenna Impedance / 50 / ohm Antenna load impedance VSWR / / 3:1 / Maximum allowed VSWR of antenna Table 2-2 Aux antenna specifications Parameter Gain Maximum gain and uniform converge in high angle elevation and zenith. Gain in the azimuth is not desired. Average 3D gain >-5dBi VSWR Typical value <3:1 Isolation(diversity to Main) >10dB in all related bands Polarization Any 2.4.2 Antenna location and mechanical design. To ensure customer has a clear knowledge of the two antennas, check below product picture. Figure 2-1 Antenna connector location and type Figure 2-2 RF connectors
25
26 Figure 2-3 RF receptacles
27 3. Mechanical Specifications 3.1 Overview T77H468 is compatible with the PCI Express M.2 Specification 3042 type 75-pin card edge-type connector. Refer to Electromechanical Specification Revision 0.7a, Version 1.0 with Input Power and Voltage Tolerance ECN for more details. 3.2 Mechanical constraints Figure 3-1 shows the mechanical constraints of T77H468 (3042-S3-B)
28 3.3 M.2 card assembly Figure 3-2 shows Stack-up Mid-Line (In-line) Single Sided Module for 1.5 Maximum Component Height, refer to section 2.4.8.3.1 of PCIe M.2_Rev0.7a standard. Remark: a. 2.4mm maximum above mother board b. Cut area of main board under M.2 module c. Need to add thermal pad between M.2 module and mechanical component (like material shielding) for thermal dissipation.
29 3.4 Connector assembly a. Mate the connector vertically as much as possible. Adjusting the mating axis of plug and receptacle. Do not slant mate. . b. Unmating: In case of unmating by pulling tool. Use the pulling tool as the following drawing, and pull plug to vertical direction as directly as possible c. Pulling tool(Unit:mm)
30 4. Electrical Specifications 4.1 Recommended operating conditions Table 4-1 Recommended operating conditions Parameter Min Type Max Units Storage temperature -30 +25 +85 °C Recommend operating temperature (3GPP compliant) -10 +25 +60 °C Extend operating temperature (operational, non-3GPP compliant) -20 +25 +70 °C Operating voltage 3.135 3.3 3.465 Vdc Operating T77H468 device under conditions beyond its absolute maximum ratings (Table 4-1) may damage the device. Absolute maximum ratings are limiting values to be considered individually when all other parameters are within their specified operating ranges. Functional operation and specification compliance under any absolute maximum condition, or after exposure to any of these conditions, is not guaranteed or implied. Exposure may affect device reliability 4.2 Power consumption Table 4-2 Radio system power consumption Test condition Sample Test Estimated power range goal (Typical) Estimated power range goal (Max.) GSM in suspend mode 3.8mA <5mA GSM (Tx=33dBm single slot) 310mA <500mA <2800mA WCDMA in suspend mode 3.3mA <5mA WCDMA (Tx=24dBm) 697mA <800mA <1100mA CDMA in suspend mode 3.3mA <4mA CDMA (Tx=24dBm) 610mA <700mA <1000mA LTE in suspend mode 4.2mA <5mA LTE (16QAM) Tx=23 dBm 735mA <900mA <1200mA GPS/GNSS tracking 135mA <150mA <300mA Connected standby 2.7mA <3mA
31 5. RF performance specifications Radio performance for T77H468 is given in the following sections, including RF receiver, RF transmitter. 5.1 RF maximum Tx power specifications Table 5-1 Maximum transmit power Specification Power class/ control level Min. Typ. Max. unit LTE (B2) Class 3 21 23 24 dBm LTE (B4) Class 3 21 23 24.5 dBm LTE (B5) Class 3 21 23 24 dBm LTE (B13) Class 3 21 23 24.5 dBm LTE (B17) Class 3 21 23 24.5 dBm LTE (B25) Class 3 21 23 24 dBm WCDMA (B1) Class 3 21 24 25 dBm WCDMA (B2) Class 3 21 24 25 dBm WCDMA (B4) Class 3 21 24 25 dBm WCDMA (B5) Class 3 21 24 25 dBm WCDMA (B8) Class 3 21 24 25 dBm CDMA (BC0) Class 3 23 24 25 dBm CDMA (BC1) Class 2 23 24 25 dBm GSM850/900 Class4 31 32 33 dBm GSM1800/1900 Class1 28 31 30 dBm GPRS 850/900 Class4 31 32 33 dBm GPRS 1800/1900 Class1 28 29 30 dBm EDGE 850/900 ClassE2@PCL8 25 26 27 dBm EDGE 1800/1900 ClassE2@PCL2 24 25 26 dBm Remark: Above table is for general application, please inform us if you have any further requirement.
32 5.2 RF min. Rx sensitivity specifications Table 5-2 Conducted min. receiver sensitivity Specification Min. Typ. Max. (compliance with standard) unit LTE (B2)@10MHz / -101 -95 dBm LTE (B4) @10MHz / -102 -97 dBm LTE (B5) @10MHz / -102.5 -95 dBm LTE (B13) @10MHz / -103 -94 dBm LTE (B17) @10MHz / -102.5 -94 dBm LTE (B25) @10MHz / -101 -93.5 dBm WCDMA (B1) / -110 -106 dBm WCDMA (B2) / -109 -104 dBm WCDMA (B4) / -110 -106 dBm WCDMA (B5) / -111 -104 dBm WCDMA (B8) / -110 -103 dBm CDMA (BC0) / -109 -104 dBm CDMA (BC1) / -109 -101 dBm GSM850/900 / -110 -102 dBm GSM1800/1900 / -110 -100 dBm GPRS 850/900 (CS1) / -110 -102 dBm GPRS 1800/1900 (CS1) / -110 -100 dBm EDGE 850/900 (CS5) / -107 -98 dBm EDGE 1800/1900 (CS5) / -105 -98 dBm GPS/GLONASS tracking sensitivity / -157 -152 dBm Remark: a. It has 3dB margin at least refer to 3GPP standard or CDMA standard. b. The typical value of LTE was measured as combine Rx sensitivity which was follow test setup of 3GPP standard (TS36.521 charter 7.2 and charter 7.3.5), the test setup is follow TS36.508 Annex A Figure A.3. SS RX/TX RX UE under Test RX/TX Ior Îor Splitter/ combiner
33 6. Software Requirements The software includes firmware, driver, configuration file and configuration utility for LTE Card based on Qualcomm MDM9615+WTR1605L chipsets. Please refer to main features in below table. # Feature Feature description 1.1 Modem 1.1.1 LTE-FDD - Release 8 1.1.2 LTE-FDD - Release 9 (mandatory features) 1.1.3 DC-HSPA+ - Release 8 1.1.4 1x Advanced 1.1.5 EVDO Rev B 1.1.6 eHRPD 1.1.7 WCDMA 1.1.8 GERAN 1.1.9 SVLTE 1.1.10 WCDMA/GERAN: Protocols – Rel-8: Support for E-UTRA Detection If LTE coverage is available and if UE is able to detect the same (from a state where we didn’t have any sync LTE cells), it will inform upper layers. This is spec requirement 1.1.11 LTE-eHRPD Mobility 1.1.12 Rel8 Fast Dormancy 1.1.13 Rel7 HSPA DTX/DRX 1.1.14 APT - for all modes (LTE FDD/WCDMA, C2K) 1.1.15 Peripheral attachments - WLAN for QCMobileAP and SD card 1.1.16 Data call (Geran, WCDMA, 1X/EVDO, eHRPD and LTE) 1.1.17 SMS (GERAN, WCDMA,1X/EVDO, eHRPD and LTE) 1.1.18 Data interface- QMI QMI commands for UQCN download and selection. Add commands to manage UQCNs, set the device in Download mode. 1.1.19 Power grid /PAM table config support 1.1.20 Support for Gobi RF configs Support for Gobi WTR1605 configurations 1.1.21 UQCN Feature support UQCN Feature support ,Carrier specific UQCNs implementation / UQCN generation tools
34 1.1.22 Configurable RRC band scan order, also add support for LTE cfgs 1.1.23 Saving MRU/ Band scan etc. info while in suspend/resume/power-save states - WCDMA 1.1.24 Gobi - Saving MRU/band scan info (3GPP2) 1.1.25 Gobi - Saving MRU/band scan info (GERAN, WCDMA) 1.1.26 Gobi - Add QMI CAT Command for terminal profile property. Add QMI_CAT_SEND_ENVELOP_CMD_RSP. Add optional TLV in QMI_CAT_SEND_ENVELOP_CMD_RSP to report envelope response from card in raw format and corresponding status words 1.1.27 Multiple carrier support in NV Provides the ability for a single modem image to support multiple carriers via per-carrier configuration files that are downloaded to the modem. This is a Gobi modem capability 1.2 Modem (1X) 1.2.1 Enable complete IS-683C OTA message support FEATURE_IS683C_OTASP makes the following messages compliant with IS683C standard:  Protocol Capability Response message  SSPR Configuration Request/Response message 1.2.2 OTASP support for all band classes Expand the OTASP support to all the bands supported by the 3GPP2 C.S0057-B 1.2.3 Multimode: OTASP/OTAPA –Runtime Detection of OTASP Numbers Provide capability of using custom numbers with OTASP calls via UI through Centralized Call Control support 1.3 Modem (EVDO) 1.3.1 Dedicated Data Transfer Mode (DDTM) Allows the user to control the 1X access at runtime when the 1xEV-DO data call is made 1.3.2 EV-DO Data Activity Based Adaptive Receive Diversity Disable EV-DO diversity when no FL data is arriving. When data resumes, immediately bring up diversity. This saves power during the period of waiting for dormancy for applications that don't explicitly close the connect 1.3.3 Rx Diversity during 1x Access Enable 1x Rx Diversity during 1x Access if Rx Diversity for Traffic Has Been Enabled
35 1.3.4 1X EV-DO Rev B (with QOS for handsets) The multi-carrier version of 1xEV-DO in which up to three carriers are supported on the forward and reverse links; QoS added for handsets 1.3.5 3 Carrier Rev B over 5x Bandwidth 3 Carrier rev B over 5x bandwidth 1.3.6 Max Bandwidth Support Support calls where the AN assigns outer carriers that are 5.16 MHz apart 1.3.7 Rev B physical layer FL rates Enhanced flow rates on FL 1.4 Modem (eHRPD) 1.4.1 eHRPD: eHRPD <-> 1x handoff Allows the mobile to move between areas of eHRPD coverage and 1x coverage (and vice-versa). 1.4.2 eHRPD: eHRPD <-> HRPD handoff When moving from 1x/HRPD to eHRPD, AT should not send ULN. When moving back from eHRPD to HRPD, also AT should not send ULN. 1.5 Modem (Geran) 1.5.1 GERAN 3GPP Rel-8 Spec compliance GERAN compliant with Rel-8 spec versions 1.5.2 NACC, Ext UL TBF Rel Network-Assisted Cell Selection for faster cell reselection and Extended UL TBF Release to extend the UL TBF and reduce the incidence of idle activity between packet transfer activities 1.2.3 PFC/PFI Packet Flow Context/Packet Flow Identifier - Allows identity tagging of RLC blocks to identify separate QoS streams at the radio link layer 1.5.4 EDGE MSC12 Original legacy EDGE support with Multislot Class 12 capability 1.5.5 GPRS/EDGE MSC12-EDA Extended Dynamic Allocation to permit allocation of more than two uplink timeslots for GPRS/EDGE 1.5.6 Enh DL RLC/MAC Segmentation Permits reception of MAC control messages that exceed one radio block capacity in length 1.5.7 Enhanced Ext UL TBF Per Ext UL TBF, with the addition that dummy block transmission is punctured for current saving purposes 1.5.8 2G PS handover Packet-switched equivalent of CS handover to ensure faster cell change and improved throughput 1.5.9 Encryption: GEA3 New packet-switched cipher algorithm 1.5.10 WCDMA/GERAN: Band Scan – Run-time Configurable RRC Band Scan Order Run-time configurable RRC band scan order
36 1.5.11 WCDMA/GERAN: Power and Network Optimizations – Frame Early Termination for Power Optimization With pragmatic reception approach, decode partial TTI and terminate frame early to reduce power consumption 1.5.12 WCDMA/GERAN: Protocols – MRAB-Pack-1 Enhancements These UE enhancements will reduce Multi-RAB Call Drops. The following optimizations are planned under MRAB-Pack-1: 1) Configuration of the minimum set of TFCs: Optimize the way that PS-only TFCs are selected for UL transmission in power limited conditions(2 flavors) 1-EUL) Smart application of minimum E-TFCI : Optimize utilization of Minimum E-TFCI in power limited conditions 4) MRAB Back-off: Preventing, or reducing the establishment of data connections on top of existing voice connections in power limited conditions 6) TVM Back-off : Blocking traffic volume events (Event 4a) for MRAB calls in power limited conditions 1.6 Modem (UMTS) 1.6.1 Cat 10 HSDPA Rel-5 Category 10 HSDPA, allowing for physical layer throughputs up to 14.4 Mbps. 1.6.2 Cat 6 HSUPA Rel-6 Category 6 HSUPA, allowing for physical layer throughputs up to 5.76 Mbps. 1.6.3 Cat 14 HSPA+ Cat 14 HSPA+ 64-QAM HSDPA, allowing for physical layer throughputs up to 21 Mbps 1.6.4 DC-HSPA+ Dual Carrier – HSPA+, allowing for physical layer throughputs up to 42 Mbps 1.6.5 HSUPA 10ms TTI (2 Mbps) HSUPA 10 ms TTI up to 2 Mbps in UL physical layer 1.6.6 HSUPA 2ms TTI (5.76 Mbps) HSUPA 2ms TTI up to 5.76 Mbps in UL physical layer 1.6.7 E-FDPCH E-FDPCH Rel-7 enhancement to the Rel-6 FDPCH (fractional DPCH) in soft handover scenarios; fractional DPCH was added in Rel-6 to optimize the consumption of downlink channelization codes - Allowing more users to share the channel 1.6.8 Enhanced L2 Support for flexible sized PDUs at RLC DL and PDU segmentation at MAC-HS level, on the HSDPA downlink to allow for higher data rates in Rel-7 1.6.9 CPC-DTX Allows for breaks in transmission during
37 HSUPA for power consumption benefit and UL interference reduction. 1.6.10 Q-ICE Advanced UMTS receiver performing iterative equalization and interference cancellation in support of HSPA+ 1.6.11 SCH-IC Cancelling the interference from the synchronization channel for improved HSDPA performance 1.7 Modem (LTE) 1.7.1 Rel-9: Mandatory LTE Features Support for Release 9 Mandatory Features 1.7.2 Bandwidth support 1.4, 3, 5, 10, 15, 20 MHz Per 3GPP standard 1.7.3 Standalone Security NAS & RRC security for LTE 1.7.4 CMAS for LTE Commercial Mobile Alert System for LTE 1.7.5 ETWS (Earthquake Tsunami Warning System) - LTE Support for ETWS notification in LTE 1.7.6 Intra-Freq Connected mode mobility Support for 1X2 MISO (1Tx and 2Rx for two downlinks simultaneously) 1.7.7 Intra-Freq Idle mode mobility Support for 1X2 MISO (1Tx and 2Rx for two downlinks simultaneously) 1.7.8 Inter-Freq mobility Mobility within LTE band/bandwidth 1.7.9 Connected mode DRX Exercising DRX cycle while in LTE Connected mode 1.7.10 Sleep Exercising DRX cycle while in LTE Idle mode 1.7.11 eHRPD -> LTE Idle mode reselection Mobility from eHRPD to LTE in Idle mode based on LTE neighbor cell measurements 1.7.12 E-UTRA RRC_IDLE -> eHRPD Idle Reselection from idle LTE to idle eHRPD 1.7.13 IRAT SON ANR UE IRAT support for Self Organizing Networks and Automatic Neighbor Relation 1.7.14 LTE -> eHRPD (Redirections without measurement gaps - blind) Redirections from LTE connected -> eHRPD Idle without measurements (blind redirection) 1.7.15 LTE -> eHRPD (Redirections based on measurements gaps) Redirections from LTE connected to eHRPD idle based on measurements during gaps intervals 1.7.16 LTE -> 1x Connected mode measurements Perform measurements on 1x side during LTE Connected mode state. 1.7.17 LTE -> 1x Redirection Redirection from LTE connected to 1x idle 1.7.18 LTE -> 1x Reselection Idle mode reselection from LTE idle to 1x idle 1.7.19 UMTS -> LTE Redirections (no measurements) Redirection from UMTS to LTE (blind - no measurements) 1.7.20 UMTS -> LTE Redirections (with measurements) Redirection from UMTS Connected mode to LTE based on LTE measurements
38 during WCDMA Compressed mode gaps 1.7.21 GERAN -> LTE Redirections (no measurements) Redirection from GERAN to LTE (blind - no measurements) 1.7.22 LTE <-> GERAN Idle mode mobility (cell reselection) Idle mode reselection from LTE idle to GERAN idle 1.7.23 LTE <-> UMTS Idle mode mobility (cell reselection) Idle mode reselection from LTE idle to UMTS idle 1.7.24 LTE -> UMTS PS Handover UE does a PS handover under network direction from LTE to UMTS 1.7.25 LTE -> UMTS Redirections (with measurements) 2012 Redirection from LTE connected to UMTS with measurements on UMTS 1.7.26 LTE/GW Data Silent Redial for InterRAT During inter RAT transitions between LTE and WCDMA/GPRS, data calls that are locally rejected on source RAT will be redialed by Data Services mode handler on target RAT 1.7.27 Multimode: LTE – Attach/Detach PS during Voice Call or SMS Support disabling of PS capability during voice call/SMS and removing LTE when PS is removed (Detach) and add LTE again when PS is added (attach) 1.7.28 TDD-LTE 1.8 Modem (System Determination) 1.8.1 Frequency Scan and System Selection within LTE Ability to do band scan and also power-up system selection 1.8.2 LTE BPLMN support Support for PLMN search in background while LTE is active 1.8.3 LTE Connected mode OOS Support System Operation mode (Online, LPM, POWER OFF, etc.) changes in LTE Connected and Idle mode 1.8.4 System Selection across LTE, UMTS, GERAN, 1x/DO Ability to select a particular RAT based on a preferred RAT list 1.8.5 System Selection across RATs, Standalone Security, Dedicated EPS Bearer Mgmt and Dormancy Standard LTE features 1.8.6 Support of 256 UPLMN and 256 OPLMN entries in USIM UE can read 256 entries from each preferred list. Together, it can read a maximum of 512 PLMN entries from preferred list. 1.8.7 Multi-mode System Selection Facilitating system selection when UE supports multiple modes 1.8.8 Multimode: System Selection – Avoiding Unnecessary Attach Requests in A 3GPP+3GPP2 Multimode UE NAS will use a synchronous API call to check with CM whether a PLMN is ok to attach before starting attach procedure. If API returns TRUE, NAS will do the attaching and send SRV_CNF to CM. This will be a preferred system so CM won’t
39 send STOP_MODE for less preferred system. If API returns FALSE, CM_SRV_CNF with No Service 1.8.9 Carrier Specific BSR Requirements Extensions to carrier specific set of requirements for System Selection 1.8.10 Data Services: eHRPD/LTE – Data System Determination for Multiple Radio Systems Re-architect data call arbitration in Data Services layers to remove race conditions between various SW entities in modem and CNE 1.8.11 WCDMA/GERAN: System Selection – Prevent UE from Sending Attach Request Message Infinitely When HPLMN Reject Attach Request with Cause 14 If HPLMN rejects GPRS Registration with cause # GPRS Services Not Allowed in this PLMN (which it shouldn't as per expectation from a well-behaved network), UE keeps on attempting registration again and again on same HPLMN RA. This feature is to cover up for this network misbehavior and reattempt GPRS registration only on RA change 1.9 Modem (Data) 1.9.1 ATCOP 1.9.2 WCDMA/GERAN: ATCOP 3GPP – Enhancing The Interface for Manual PLMN Selection Provide Manual PLMN Selection API between CM/NAS and ATCOP to provide the current serving status of the UE 1.9.3 IPHC IP header compression protocol as RFC 2509 1.9.4 DHCPv4 DHCPv4 This is to support for stateless DHCPv4 protocol to get P-CSCF and DNS addresses 1.9.5 Simple IPv4 Supports IPv4 address allocation and release without IP mobility 1.9.6 Mobile IPv4 1.9.7 4 PDNs Support over Multi-RmNet Provides the capability to an external AP to support 4 PDNs through 4 RmNet Connections to external processor 1.9.8 Dual IP on single RmNet UE shall support tethered RmNet to laptop data call using Dual IP on single RmNet to a single USB-end point 1.9.9 IP only Mode/Raw IP Mode RmNet laptop calls transfer IP packets over USB or shared memory without Ethernet framing; reduces CPU overhead and speeds up call setup times (no ARP duplicate detection) 1.9.10 Multi-RmNet Data Call This is support multiple tethered data calls over multi-RmNet 1.9.11 DHCPv6 1.9.12 RmNet IPv6 1.9.13 Tethered IPv6 using DUN over USB
40 1.10 Modem (Data: EVDO) 1.10.1 RLP: 1x EVDO Rev B This is to support Radio Link Protocol in 1xEV-DO Rev B 1.10.2 CDMA: 1X EVDO Rev B – Enhanced PA Back off for DO Rev B Uses Tx power differential based PA back off for multi-carrier assignment, and improves a) multi-carrier coverage/throughput on FL, and b) RL data rate/throughput when multiple carriers are assigned on FL 1.11 Modem (Data: eHRPD) 1.11.1 EAP-AKA' (prime) Authentication protocol using AKA' (prime) over EAP transport for all air interfaces 1.11.2 eHRPD: Multiple PDN Support Enhanced AMSS implementation to support multiple VSNCP negotiations and multiple VSNP data paths over one PPP instance for eHRPD multiple PDN connectivity; 3GPP2 eHRPD specification (X.P0057-0-EHRPD-EUTRAN) 1.11.3 eHRPD: Optimized Silent Redial and DCTM4.0 Silent Redial of data call on eHRPD system 1.11.4 Data Services: eHRPD – Ignore PDN Inactivity Timer for The Last PDN The UE shall ignore the PDN Inactivity timer when only one PDN connection remains. Upon PDN Inactivity timer expiry, if it is the last PDN connection, the UE shall extend the timer, and shall not initiate PDN disconnection 1.12 Modem (Data: LTE) 1.12.1 LTE: Data Call throttling This is to prevent UE from repeatedly requesting PDN connections to the NW when it encounters a failure in either eHRPD or LTE connections 1.12.2 LTE: Default IPv4 Bearer activation at attach Support for IPv4 data call in LTE 1.12.3 LTE: NW initiated QoS 1.12.4 LTE: UE initiated QoS 1.12.5 Dual IP Continuity Dual IP continuity across LTE and eHRPD 1.12.6 IPv4/IPv6 Continuity Dual IP continuity across LTE and eHRPD 1.12.7 LTE-eHRPD mobility: IPV4 Session Continuity IPv4 session continuity across LTE and eHRPD 1.12.8 LTE-eHRPD mobility: IPV6 Session Continuity IPv4 session continuity across LTE and eHRPD 1.12.9 LTE: W/G IP session Continuity IP session continuity across LTE and W/G 1.12.10 LTE: MIMO – LTE TDD 4-Port Processing LTE TDD 4x2 MIMO antenna configuration support (4x2 transmit diversity) 1.12.11 LTE: MBMS – LTE TDD MBSFN Awareness Ability to ignore MBSFN symbols in LTE TDD subframes while maintaining unicast
41 performance 1.12.12 LTE: Mobility – LTE TDD Inter-Freq Connected Mode Handover LTE TDD inter-frequency connected mode handover with measurements covering multiple EARFCN's in the same or different bands as well as different bandwidths in the same EARFCN 1.12.13 LTE: DRX –LTE TDD Connected Mode DRX without Sleep Improve power consumption by turning off modem/RF components during connected mode DRX periods. No Sleep support 1.12.14 LTE: DRX – LTE TDD Connected Mode DRX with Sleep Enhanced and optimized power consumption over 1.12.13 using sleep support in Connected mode DRX periods 1.12.15 LTE: Emergency Services – LTE NAS Support for Control Plane LTE Positioning Protocol Enable Location Positioning Protocol capabilities through NAS signaling as well as to create an API providing transport services for GPS signaling 1.12.16 Data Services – LTE-eHRPD Mobility Support of APN Class and APN Bearer in Application Profile over LTE To support APN Bearer in Application Profile over LTE 1.13 Modem (VoLTE) 1.13.1 LTE: VoLTE – Forking Support Support for parallel and sequential forking in IMS VoLTE 1.13.2 LTE: QMI – VoLTE: QMI Indication for Remote Party on Hold Indication provided when remote party places call on hold 1.13.3 LTE: VoLTE – Session Timer support on VoLTE Session Timer Support on VoLTE/QIPCall to be implemented/tested for Phase3 1.13.4 LTE: VoLTE – VT Call Supplementary Services Support for VT call supplementary services: 1. Call Hold/Resume 2. Call waiting a. Between two VT/VS calls b. Between VT/VS call and VOIP call c. Between VT/VS call and 1x call 3. Call conference 4. Caller id Presentation/Restriction5. DTMF 1.13.5 LTE: VoLTE – Early Media Support Support for early media in VoLTE 1.13.6 LTE: VoLTE – VoLTE Support in RIL, Android Telephony and QMI_VOICE VoLTE support in RIL, Android Telephony and QMI_VOICE The Linux features described in this chapter are:  Device Drivers  Modem Interface
42  Linux Kernel and BSP  Other  Power Management  USB  Validated Configuration  Development/Debug Table 5-1 Linux features # Feature Feature description 2.1 Device Drivers 2.1.1 UART Driver Peripheral driver for Universal Asynchronous Receiver/Transmitter 2.1.2 I2C Driver Peripheral driver for Inter-IC bus up to 100 kbps or 400 kbps for Fast mode 2.1.3 I2S Driver Peripheral driver for Inter-IC sound bus. I2S is an industry standard (invented by Philips) three-wire interface for streaming stereo audio between devices. Typical applications include digital audio transfer between a CPU/DSP and a DAC/ADC. The I2S core allows a Wishbone master to stream stereo audio to and from I2S capable devices. 2.1.4 SD/MMC Interface Secure digital memory support. 2.1.5 SDIO Secure digital input/output  Two controller ports  Up to 48 MHz  4-bit interface  Interface through Linux MMC stack 2.1.6 WLAN driver Support for wireless networking over SDIO 2.1.7 SPI Driver Peripheral driver for Serial Peripheral Interface bus can use Data Mover and clock up to 26 MHz 2.1.8 SSBI Driver Driver for SSBI (Single-Wire Serial Bus Interface) bus hardware cores 2.1.9 2KB. 4KB, and 8KB size pages SLC NAND x8 and x16 Flash driver support for 8-bit and 16-bit Single Level Cell (SLC) NAND devices with 2k page size 2.2 Modem Interface 2.2.1 AT Command Support (GCF) Support for AT commands required for GCF testing. See document 80-VR432-1 for details. 2.2.2 Dial-up Networking over USB Support for tethered dial-up networking over USB 2.2.3 QMI QMI is to be used by 3rd party operating systems to configure the
43 modem data stack 2.2.4 Multimode: QMI – Add One Field toDetermine if Record is Read Only or Read-Write in QMI_PBM_RECORD_READ_IND Adding a field to know whether the record is read only or read-write in QMI_PBM_RECORD_READ_IND. This is required instead of determining through UIM for this information. This feature tells the clients if a particular phonebook is writeable or not and if not what validation is required 2.2.5 Multimode: QMI – WMS SEND RAW Async Command Add support so raw-send and send-ack can be asynchronous 2.2.6 Data Interface: IMS – VT: Support Rm Socket Interface between AP and Modem Provides a Rm Socket Interface between AP and Modem for VT Support 2.2.7 Modem Interfaces: QMI – Provide Number of USIM Entries per Contact PBM support for providing the number of USIM contacts that can be associated with a contact stored on the SIM card. USIM contacts include E-mail, Additional Number, Group name and SNE 2.2.8 Multimode: Emergency Services – RAT Based ECC Number Handling CM acquires a RAT based on ECC list for emergency call and PBM maintains ECC list per RAT and provide new API for call type resolution 2.2.9 IMS Voice Loopback Mode Support Support loopback mode for voice packets in IMS 2.2.10 IMS – Call Failure Code & Call End Reason Provided to UI through CM Call failure code & Call end reason provided to UI through CM 2.2.11 SIM Hotswap Feature allows inserting or removing a SIM while the device is powered on 2.3 Linux Kernel and BSP 2.3.1 Base Linux Kernel port kernel version supported: 3.0 2.3.2 Secure Boot SBL2 loads all subsystem firmware 2.3.3 Data Mover (DMOV) Driver that interfaces with the Qualcomm Data Mover hardware. 2.3.4 Exception handler Linux kernel handlers for A5 CPU exceptions, kernel panic, etc. 2.3.5 Watchdog No subsystem restart, A5 watchdog bark and bite handlers, modem watchdog bite (system resets), RPM watchdog bite (system resets), restarts in Download mode based on NV flag 2.3.6 Network Stack Support Linux network stack provides IPv4 and IPv6 support 2.3.7 RAM File System RAM file system(s) supported for initrd 2.3.8 FAT32 FAT32 file system (for SD)
44 2.3.9 YAFFS2 NAND 2.3.10 FOTA FOTA is an application used for upgrading firmware image over the air
Federal Communication Commission Interference Statement This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one of the following measures: -Reorient or relocate the receiving antenna.-Increase the separation between the equipment and receiver.- Connect the equipment into an outlet on a circuit different from thatto which the receiver is connected.-Consult the dealer or an experienced radio/TV technician for help.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. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter.
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 20 cm between the radiator & your body. This device is intended only for OEM integrators under the following conditions: 1) The antenna must be installed such that 20cm is maintained between theantenna and users, and2) The transmitter module may not be co-located with any other transmitter orantenna.As long as 2 conditions above are met, further transmitter test will not be required. However, the OEM integrator is still responsible for testing their end-product for any additional compliance requirements required with this module installed IMPORTANT NOTE: In the event that these conditions can not be met (for example certain laptop configurations or co-location with another transmitter), then the FCC authorization is no longer considered valid and the FCC ID can not be used on the final product. In these circumstances, the OEM integrator will be responsible for re-evaluating the end product (including the transmitter) and obtaining a separate FCC authorization. End Product Labeling This transmitter module is authorized only for use in device where the antenna may be installed such that 20cm may be maintained between the antenna and users. The final end product must be labeled in a visible area with the following: “Contains FCC ID: RI7LN931NAG”. The grantee's FCC ID can be used only when all FCC compliance requirements are met. Manual Information To the End User The OEM integrator has to be aware not to provide information to the end user regarding how to install or remove this RF module in the user’s manual of the end product which integrates this module. The end user manual shall include all required regulatory information/warning as show in this manual.

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