Telit Communications S p A HE910NAV2 2G/3.5G module, HE910-NAG V2, HE910-NA V2 User Manual HE910 V2 Hardware User Guide
Telit Communications S.p.A. 2G/3.5G module, HE910-NAG V2, HE910-NA V2 HE910 V2 Hardware User Guide
Contents
- 1. updated SW manual
- 2. Updated Hardware manual
Updated Hardware manual
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Copyright © Telit Communications S.p.A. 2013. Contents 4.2.2. Hardware Shutdown The aim of this document is the description of some hardware solutions useful for developing a product with the Telit HE910-EU/EUG V2 HE910-NA/NAG V2 module. All the features and solutions detailed are applicable to all HE910 V2, whereas “HE910 V2” is intended the modules listed in the applicability table. When a specific feature is applicable to a specific product, it will be clearly highlighted. This document is intended for Telit customers who are about to implement their applications using our HE910 V2 modules. For general contact, technical support, to report documentation errors and to order manuals, contact Telit Technical Support Center (TTSC) at: TS-EMEA@telit.com TS-NORTHAMERICA@telit.com TS-LATINAMERICA@telit.com TS-APAC@telit.com Alternatively, use: http://www.telit.com/en/products/technical-support-center/contact.php For detailed information about where to buy the Telit modules or for recommendations on accessories and components visit: http://www.telit.com To register for product news and announcements or for product questions contact Telit Technical Support Center (TTSC). Our aim is to make this guide as helpful as possible. Please keep us informed of comments and suggestions for improvements. Telit appreciates feedback from the users of our information. This document contains the following chapters: Chapter 1: “Introduction” provides a scope for this document, target audience, contact and support information, and text conventions. Chapter 2: “General Product Description” gives an overview of the features of the product. Chapter 3: “HE910 V2 Module Connections” deals with the pin out configuration and layout. Chapter 4: “Hardware Commands” How to operate the module via hardware. Chapter 5: “Power supply” Power supply requirements and general design rules. Chapter 6: “Antenna” The antenna connection and board layout design are the most important parts in the full product design. Chapter 7: “USB Port” The USB port on the Telit HE910 V2 is the core of the interface between the module and OEM hardware. Chapter 8: “Serial ports” Refers to the serial ports of the Telit HE910 V2. Chapter 9: “Audio Section overview” Refers to the audio blocks of the Base Band Chip of the HE910 V2 Telit Module. Chapter 10: “General Purpose I/O” How the general purpose I/O pads can be configured. Chapter 11: “DAC and ADC section” Deals with these two kinds of converters. Chapter 12: “Mounting the Module on the application board” Mechanical dimensions and recommendations on how to mount the module on the user’s board. Chapter 13: “Packing System” Deals with packing system. Chapter 14: “Application Design Guide” Deals with the application design of host system. Chapter 15: “Conformity Assessment Issues” provides some fundamental hints about the conformity assessment that the final application might need. Chapter 16: “Safety Recommendation” provides some safety recommendations that must be followed by the customer in the design of the application that makes use of the Telit HE910 V2. Chapter 17: “Document History” Danger – This information MUST be followed or catastrophic equipment failure or bodily injury may occur. Caution or Warning – Alerts the user to important points about integrating the module. If these points are not followed, the module and end user equipment may fail or malfunction. Tip or Information – Provides advice and suggestions that may be useful when integrating the module. All dates are in ISO 8601 format, i.e. YYYY-MM-DD. HE910 V2 Product Description, 80418ST10602A HE910 V2 Software User guide, 1vv0301071 HE910 V2 AT command reference guide, 80428ST10592A HE910 V2 Digital Voice Interface Application Note, 80000NT10101A Telit EVK2 User Guide, 1vv0300704 The aim of this document is the description of some hardware solutions useful for developing a product with the Telit HE10 V2 module. In this document all the basic functions of a mobile phone will be taken into account; for each one of them a proper hardware solution will be suggested and eventually the wrong solutions and common errors to be avoided will be evidenced. Obviously this document cannot embrace the whole hardware solutions and products that may be designed. The wrong solutions to be avoided must be considered as mandatory, while the suggested hardware configurations must not be considered mandatory, instead the information given must be used as a guide and a starting point for properly developing your product with the Telit HE10 V2 module. NOTE: The integration of the GSM/GPRS/EGPRS/WCDMA/HSPA+ HE910 V2 cellular module within user application must be done according to the design rules described in this manual. The information presented in this document is believed to be accurate and reliable. However, no responsibility is assumed by Telit Communication S.p.A. for its use, such as any infringement of patents or other rights of third parties. No license is granted by implication or otherwise under any patent rights of Telit Communication S.p.A. other than for circuitry embodied in Telit products. This document is subject to change without notice. Upload Download HSUPA HSDPA (Mbps) (Mbps) EMEA/APAC/Latin American markets HE910-EU V2 5.76 14.4 HE910-EUG V2 5.76 14.4 North American markets HE910-NA V2 5.76 14.4 HE910-NAG V2 5.76 14.4 Variant name HE910 V2 Variants Frequencies Features UMTS/HSPA+ GSM/GPRS/EDGE Data bands(MHz) Quad-band Voice GPS 900, 2100 900, 2100 ■ ■ ■ ■ ■ ■ ■ 850, 1900 850, 1900 ■ ■ ■ ■ ■ ■ ■ The Telit HE910 V2 module overall dimensions are: • Length: 28.2 mm • Width: 28.2 mm • Thickness: 2.2 mm The module weight of HE910 V2 is about 4.0 gram. Operating Temperature Range –40°C ~ +85°C Storage and non-operating Temperature Range –40°C ~ +90°C As a part of Telit’s corporate policy of environmental protection, the HE910 V2 complies with the RoHS (Restriction of Hazardous Substances) directive of the European Union (EU directive 2011/65/EU). The operating frequencies in GSM850, EGSM900, DCS1800, PCS1900, WCDMA modes are conformed to the 3GPP specifications. Mode Freq. TX (MHz) Freq. RX (MHz) Channels TX - RX offset GSM850 824.2 ~ 848.8 869.2 ~ 893.8 128 ~ 251 45 MHz 890.0 ~ 914.8 935.0 ~ 959.8 0 ~ 124 45 MHz 880.2 ~ 889.8 925.2 ~ 934.8 975 ~ 1023 45 MHz DCS1800 1710.2 ~ 1784.8 1805.2 ~ 1879.8 512 ~ 885 95MHz PCS1900 1850.2 ~ 1909.8 1930.2 ~ 1989.8 512 ~ 810 80MHz EGSM900 WCDMA850 (HE910-NA/NAG V2 only) Tx: 4132 ~ 4233 826.4 ~ 846.6 871.4 ~ 891.6 WCDMA900 (HE910-EU/EUG V2 only) 882.4 ~ 912.6 927.4 ~ 957.6 Rx: 2937 ~ 3088 45MHz Tx: 9262 ~ 9538 1852.4 ~ 1907.6 1932.4 ~ 1987.6 WCDMA2100 (HE910-EU/EUG V2 only) 45MHz Tx: 2712 ~ 2863 WCDMA1900 (HE910-NA/NAG V2 only) Rx: 4357 ~ 4458 Rx: 9662 ~ 9938 80MHz Tx: 9612 ~ 9888 1922.4 ~ 1977.6 2112.4 ~ 2167.6 Rx: 10562 ~ 10838 190MHz Pin Signal I/O Function USB HS 2.0 Communication Port I/O USB differential Data(+) B15 USB_D+ I/O USB differential Data(-) C15 USB_DI Power sense for the internal USB transceiver A13 VBUS Asynchronous UART – Prog. / data +HW Flow Control Serial data input from DTE N15 C103/TXD Serial data output to DTE M15 C104/RXD Input for Data terminal ready signal (DTR) from DTE M14 C108/DTR Input for Request to send signal (RTS) from DTE L14 C105/RTS Output for Clear to send signal (CTS) to DTE P15 C106/CTS Output for Data carrier detect signal (DCD) to DTE N14 C109/DCD Output for Data set ready signal (DSR) to DTE P14 C107/DSR Output for Ring indicator signal (RI) to DTE R14 C125/RING Asynchronous Auxiliary UART Auxillary UART (TX Data to DTE) D15 TX_AUX Auxillary UART (RX Data from DTE) E15 RX_AUX RUIM Card Interface(*) SIMVCC External SIM signal - Power supply for the SIM A3 SIMIN External SIM signal – Presence(active low) A4 SIMIO I/O External SIM signal – Data I/O A5 SIMCLK External SIM signal - Clock A6 SIMRST External SIM signal - Reset A7 Digital Voice interface (DVI) DVI_WA0 I/O Digital Voice interface (WA0) B9 DVI_RX Digital Voice interface (RX) B6 DVI_TX Digital Voice interface (TX) B7 DVI_CLK I/O Digital Voice interface (CLK) B8 Digital IO GPIO_01 I/O GPIO_01 / STAT LED C8 GPIO_02 I/O GPIO_02 C9 I/O GPIO_03 C10 GPIO_03 I/O GPIO_04 C11 GPIO_04 I/O GPIO_05 B14 GPIO_05 GPIO_06 I/O GPIO_06 C12 I/O GPIO_07 / DAC_OUT C13 GPIO_07 I/O GPIO_08 K15 GPIO_08 I/O GPIO_09 L15 GPIO_09 I/O GPIO_10 G15 GPIO_10 ADC Section ADC_IN1 AI Analog/Digital converter input B1 Type 5V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V 1.8/2.85V CMOS 1.8V 1.8/2.85V 1.8/2.85V 1.8/2.85V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V CMOS 1.8V A/D Pin Signal RF Section ANTENNA K1 GPS Section ANT_GPS R9 GPS_LNA_EN R7 Miscellaneous Function I/O Function Type I/O CDMA Antenna (50Ohm) RF GPS Antenna (50Ohm) Output enable for External LNA supply RF CMOS 1.8V CMOS 1.8V R13 HW_SHUTDOWN* Hardware unconditional shutdown R12 ON_OFF* Input Command for Power ON/Software shutdown C14 VRTC Power R11 VAUX/PWRMON VRTC Backup Capacitor Supply Output for external accessories / Power ON Monitor Main Power Supply (Baseband) Main Power Supply (Baseband) Main Power Supply (PAM) Main Power Supply (PAM) Main Power Supply (PAM) Main Power Supply (PAM) Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Power Power Power Power Power Power Power Supply VBATT M1 VBATT M2 VBATT_PA N1 VBATT_PA N2 VBATT_PA P1 VBATT_PA P2 GND E1 GND G1 GND H1 GND J1 GND L1 GND A2 GND E2 GND F2 GND G2 GND H2 GND J2 GND K2 GND L2 GND R2 GND M3 GND N3 GND P3 GND R3 GND D4 GND M4 GND N4 GND P4 GND R4 GND N5 GND P5 GND R5 GND N6 Open collector CMOS 1.8V Open collector 1.8V Pin Signal GND P6 GND R6 GND P8 GND R8 GND P9 P10 GND R10 GND M12 GND B13 GND P13 GND E14 GND Reserved Reserved C1 Reserved D1 Reserved B2 Reserved C2 Reserved D2 Reserved B3 Reserved C3 Reserved D3 Reserved E3 Reserved F1 Reserved F3 Reserved G3 Reserved H3 Reserved J3 Reserved K3 Reserved L3 Reserved B4 Reserved C4 Reserved B5 Reserved C5 Reserved C6 Reserved C7 Reserved N7 Reserved P7 Reserved A8 Reserved N8 Reserved A9 Reserved N9 A10 Reserved B10 Reserved B11 Reserved N10 Reserved A11 Reserved N11 Reserved P11 Reserved I/O Function Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Ground Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Type Pin A12 B12 D12 N12 P12 D13 E13 F13 G13 H13 J13 K13 L13 M13 N13 A14 D14 F14 G14 H14 J14 K14 F15 H15 J15 Signal Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved I/O Function Type Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved WARNING: Reserved pins must not be connected. NOTE: The following table is listing the main Pinout differences between the HE910 V2 variants. Product GPS HE910-EUG V2 HE910-EU V2 HE910-NAG V2 HE910-NA V2 Yes NO Yes NO Notes Reserved pads: R7, R9 Reserved pads: R7, R9 NOTE: DTR pin must be connected in order to enter HE910 V2’s power saving mode. RI pin must be connected in order to wake up the host when a call is coming in sleep mode of host. NOTE: Almost all pins not in use must be left disconnected. The only exceptions are the following pins: PAD Signal M1,M2,N1,N2,P1,P2 E1,G1,H1,J1,L1,A2, E2,F2,G2,H2,J2,K2, L2,R2,M3,N3,P3,R3, D4,M4,N4,P4,R4,N5 ,P5,R5,N6,P6,R6,P8, R8,P9,P10,R10,M12, B13,P13,E14 R12 R13 VBATT&VBATT_PA B15 USB_D+ C15 USB_D- A13 VBUS N15 C103/TXD M15 C104/RXD L14 C105/RTS P15 C106/CTS D15 TXD_AUX E15 RXD_AUX K1 Main Antenna ANT_GPS (If supported by If the GPS is not used it could be the product) left unconnected R9 GND ON_OFF* HW_SHUTDOWN* If not used should be connected to a Test Point If not used should be connected to a Test Point If not used should be connected to a Test Point If not used should be connected to a Test Point If not used should be connected to a Test Point If the flow control is not used it should be connected to GND If not used should be connected to a Test Point If not used should be connected to a Test Point If not used should be connected to a Test Point RTS must be connected to the GND (on the module side) if flow control is not used. The above pins are also necessary to debug the application when the module is assembled on it so we recommend connecting them also to dedicated test point. NOTE: The pin defined as RES must be considered RESERVED and not connected on any pin in the application. The related area on the application has to be kept empty. NOTE: The pin defined as RES must be considered RESERVED and not connected on any pin in the application. The related area on the application has to be kept empty. To turn on the HE910 V2, the pad ON_OFF* must be tied low for at least 1 second and then released. The maximum current that can be drained from the ON_OFF* pad is 0.1 mA. A simple circuit to power on the module is illustrated below: Upon turning on HE910 V2 module, the HE910 V2 module is not active yet because the boot sequence of HE910 V2 is still executing internally. It takes about 10 seconds to complete the initialization of the module internally. For this reason, it would be useless to try to access HE910 V2 during the Initialization state as below. The HE910 V2 module needs at least 10 seconds after the PWRMON goes High to become operational by reaching the activation state. During the Initialization state, any kind of AT-command is not available. DTE must wait for the Activation state to communicate with HE910 V2. To check if the HE910 V2 has powered on, the hardware line PWRMON must be monitored. When PWRMON goes high, the module has powered on. NOTE: Do not use any pull up resistor on the ON_OFF* line. It is pulled up internally. Using a pull up resistor may bring latch up problems on the HE910 V2 power regulator and improper power on/off of the module. The line ON_OFF* must be connected only in open collector configuration. NOTE: In this document all the lines are inverted. Active low signals are labeled with a name that ends with "*" or with a bar over the name. NOTE: In order to avoid a back powering effect it is recommended to avoid having any HIGH logic level signal applied to the digital pins of the HE910 V2 module when the module is powered OFF or during an ON/OFF transition. For example: 1. To drive the ON_OFF* pad with a totem pole output of a +3/5 V microcontroller (uP_OUT1): 2. To drive the ON_OFF* pad directly with an ON/OFF button: Turning off the device can be done in two ways: By software command (see HE910 V2 Software User Guide) By hardware shutdown (pad ON_OFF*) When the device is shut down by software command or by hardware shutdown, it issues a detach request to the network that informs the network that the device will no longer be reachable. NOTE: In order to avoid a back powering effect it is recommended to avoid having any HIGH logic level signal applied to the digital pins of the HE910 V2 when the module is powered OFF or during an ON/OFF transition. The following flow chart shows the proper turnoff procedure: The HE910 V2 can be shut down by a software command. When a shutdown command is sent, the HE910 V2 goes into the finalization state and will shut down PWRMON at the end of this state. The period of the finalization state can vary according to the state of the HE910 V2 so it cannot be fixed definitely. Normally it will be above 10 seconds after sending a shutdown command and DTE should monitor the status of PWRMON to see the actual power off. TIP: To check if the device has powered off hardware line PWRMON must be monitored. When PWRMON goes low, the device has powered off. 4.2.2. Hardware Shutdown To turn OFF the HE910 V2 the pad ON_OFF* must be tied low for at least 2 seconds and then released. The same circuitry and timing for the power on must be used. When the hold time of ON_OFF* is above 2 seconds, the HE910 V2 goes into the finalization state and will shut down PWRMON at the end of this state. The period of the finalization state can vary according to the state of the HE910 V2 so it cannot be fixed definitely. Normally it will be above 10 seconds after releasing ON_OFF* and DTE should monitor the status of PWRMON to see the actual power off. TIP: To check if the device has powered off, hardware line PWRMON must be monitored. When PWRMON goes low, the device has powered off. WARNING: The Hardware Reset must not be used during normal operation of the device since it does not detach the device from the network. It shall be kept as an emergency exit procedure to be done in the rare case that the device gets stuck waiting for some network. To unconditionally shutdown the HE910 V2, the pad HW_SHUTDOWN* must be tied low for at least 200 milliseconds and then released. A simple circuit to unconditionally shutdown the module is illustrated below: NOTE: Do not use any pull up resistor on the HW_SHUTDOWN* line or any totem pole digital output. Using a pull up resistor may bring latch up problems on the HE910 V2 power regulator and result in improper functioning of the module. The line HW_SHUTDOWN* must be connected only in open collector configuration. TIP: The unconditional hardware Shutdown must always be implemented on the boards and the software must use it only as an emergency exit procedure. For example: To drive the HW_SHUTDOWN* pad with a totem pole output of a +3/5 V microcontroller (uP_OUT2): The chart below describes the overall sequences for turning the module ON and OFF. The power supply circuitry and board layout are a very important part in the full product design and they strongly reflect on the product’s overall performance. Read carefully the requirements and the guidelines that follow for a proper design. The external power supply must be connected to VBATT & VBATT_PA signals and must fulfill the following requirements: Power Supply 3.8V Nominal Supply Voltage 3.4V ~ 4.2V Normal Operating Voltage Range Extended Operating Voltage Range 3.3V ~ 4.5V Mode SWITCHED OFF Switched Off IDLE mode WCDMA AT+CFUN=1 GSM WCDMA AT+CFUN=4 GSM HE910 V2 Average(mA) 30uA (*1) Mode Description Module supplied but Switched Off Standby mode; no call in progress 15 15 13 13 Normal mode; full functionality of the module Disabled TX and RX; modules is not registered on the network Power saving; CFUN=0 module registered on the 3.2 (512frame) WCDMA 1.0 (64frame) (* ) network and can receive voice call or an SMS; but it is not possible to send AT commands; module wakes up 3.2 (DRX2) AT+CFUN=0 or with an unsolicited code (call or SMS) or rising RTS GSM 1.7 (DRX5) AT+CFUN=5 line. 1.3 (DRX9) (*2) CFN=5 full functionality with power saving; Module registered on the network can receive GPRS 1.7 (DRX5) (*3) incoming call sand SMS WCDMA TX and RX mode Operating mode WCDMA Voice 630 WCDMA voice channel HSPA 640 HSPA data channel GSM TX and RX mode Operating mode 230 GSM850/GSM900 GSM Voice(CSD) 185 DCS1800/PCS1900 390 GSM850/GSM900, class10 GPRS 2TX/3RX 300 DCS1800/PCS1900, class10 Mode Average(mA) GSM TX and RX mode 600 GPRS 4TX/2RX 450 400 EDGE 4TX/2RX 350 GSM peak current 1800 Mode Description Operating mode GSM850/GSM900, class33 DCS1800/PCS1900, class33 GSM850/GSM900, class33 DCS1800/PCS1900, class33 (*1) The off current is the total supply current from the main battery with the PMIC off and the 32 kHz XTAL oscillator on. (*2) Worst/best case depends on network configuration and is not under module control. (*3) GPRS with PDP context active NOTE: The Operating Voltage Range MUST never be exceeded. Special care must be taken when designing the application’s power supply section to avoid having an excessive voltage drop. If the voltage drop is exceeding the limits it could cause a Power Off of the module. Behavior in the extended operating voltage range might deviate from 3GPP3 specification. NOTE: The electrical design for the Power supply must be made ensuring that it will be capable of a peak current output of at least 2A. In GSM/GPRS mode, RF transmission is not continuous and it is packed into bursts at a base frequency of about 216 Hz, and the relative current peaks can be as high as about 2A. Therefore the power supply has to be designed in order to withstand these current peaks without big voltage drops; this means that both the electrical design and the board layout must be designed for this current flow. If the layout of the PCB is not well designed, a strong noise floor is generated on the ground; this will reflect on all the audio paths producing an audible annoying noise at 216 Hz; if the voltage drops during the peak, current absorption is too much. The device may even shut down as a consequence of the supply voltage drop. The principal guidelines for the Power Supply Design embrace three different design steps: the electrical design the thermal design the PCB layout The electrical design of the power supply depends strongly on the power source where this power is drained. We will distinguish them into three categories: +5V input (typically PC internal regulator output) +12V input (typically automotive) Battery The desired output for the power supply is 3.8V, hence there is not a big difference between the input source and the desired output so a linear regulator can be used. A switching power supply will not be suitable because of the low drop-out requirements. When using a linear regulator, a proper heat sink must be provided in order to dissipate the power generated. A Bypass low ESR capacitor of adequate capacity must be provided in order to cut the current absorption peaks close to the HE910 V2. A 100μF tantalum capacitor is usually suited. Make sure the low ESR capacitor on the power supply output (usually a tantalum one) is rated at least 10V. A protection diode must be inserted close to the power input in order to save the HE910 V2 from power polarity inversion. An example of a linear regulator with 5V input: The desired output for the power supply is 3.8V, hence due to the big difference between the input source and the desired output, a linear regulator is not suited and must not be used. A switching power supply will be preferable because of its better efficiency especially with the 2A peak current load represented by HE910 V2. When using a switching regulator, a 500kHz or more switching frequency regulator is preferable because of its smaller inductor size and its faster transient response. This allows the regulator to respond quickly to the current peaks absorption. In any case, the frequency and Switching design selection is related to the application to be developed due to the fact the switching frequency could also generate EMC interferences. For car PB battery the input voltage can rise up to 15.8V and this must be kept in mind when choosing components: all components in the power supply must withstand this voltage. A Bypass low ESR capacitor of adequate capacity must be provided in order to cut the current absorption peaks. A 100μF tantalum capacitor is usually suited for this. Make sure the low ESR capacitor on the power supply output (usually a tantalum one) is rated at least 10V. For Car applications a spike protection diode must be inserted close to the power input, in order to clean the supply from spikes. A protection diode must be inserted close to the power input, in order to save HE910 V2 from power polarity inversion. This can be the same diode as for spike protection. An example of switching regulator with 12V input is in the schematic below: The desired nominal output for the power supply is 3.8V and the maximum voltage allowed is 4.2V. A single 3.7V lithium-ion cell battery type is ideal to supply power to the Telit HE910 V2 module. WARNING: The three battery cells (Ni/Cd or Ni/MH 3.6V nom. battery types or 4V PB types) MUST NOT be used directly because their maximum voltage can rise over the absolute maximum voltage for the HE910 V2 and cause damage. USE only Li-Ion battery types. NOTE: Do not use any Ni-Cd, Ni-MH, and Pb battery types directly connected with HE910 V2. Their use can lead to overvoltage on HE910 V2 and damage it. Use only Li-Ion battery types. A Bypass low ESR capacitor of adequate capacity must be provided in order to cut the current absorption peaks, a 100μF tantalum capacitor is usually suited. Make sure the low ESR capacitor (usually a tantalum one) is rated at least 10V. A protection diode must be inserted close to the power input, in order to save HE910 V2 from power polarity inversion. Otherwise the battery connector must be done in a way to avoid polarity inversions when connecting the battery. The battery capacity must be at least 500mAh in order to withstand the current peaks of 2A; the suggested capacity is from 500mAh to 1000mAh. The thermal design for the power supply heat sink must be done with the following specifications: Average current consumption during HSPA transmission @PWR level max in HE910 V2: 640mA Average current consumption during class10 GPRS transmission @PWR level max: 390mA Average current consumption during class33 GPRS transmission @PWR level max: 600mA Average GPS current during GPS ON (Power Saving disabled) : 65mA NOTE: The average consumption during transmissions depends on the power level at which the device is requested to transmit via the network. The average current consumption hence varies significantly. NOTE: The thermal design for the Power supply must be made keeping an average consumption at the max transmitting level during calls of 640mA(HSPA)/600mA(class33 GPRS) /390mA(class10 GPRS) rms plus 65mA rms for GPS in tracking mode. Considering the very low current during idle, especially if Power Saving function is enabled, it is possible to consider from the thermal point of view that the device absorbs current significantly only during calls. If we assume that the device stays in transmission for short periods of time (let us say few minutes) and then remains for quite a long time in idle (let us say one hour), then the power supply has always the time to cool down between the calls and the heat sink could be smaller than the calculated for 640mA (HSPA)/ 600mA (class33 GPRS)/ 390mA (class10 GPRS) maximum RMS current. There could even be a simple chip package (no heat sink). Moreover in average network conditions the device is requested to transmit at a lower power level than the maximum and hence the current consumption will be less than 640mA (HSPA) / 600mA (class33 GPRS) /390mA (class10 GPRS) (being usually around 250mA). For these reasons the thermal design is rarely a concern and the simple ground plane where the power supply chip is placed can be enough to ensure a good thermal condition and avoid overheating. For the heat generated by the HE910 V2, you can consider it to be during transmission 2W max during class10 GPRS/class33 GPRS upload. This generated heat will be mostly conducted to the ground plane under the HE910 V2; you must ensure that your application can dissipate heat. In the WCDMA/HSPA mode, since HE910 V2 emits RF signals continuously during transmission, you must pay special attention how to dissipate the heat generated. The current consumption will be up to about 640mA in HSPA (630mA in WCDMA) continuously at the maximum TX output power (23dBm). Thus, you must arrange the PCB area as large as possible under HE910 V2 which you will mount. You must mount HE910 V2 on the large ground area of your application board and make many ground vias to dissipate the heat. The peak current consumption in the GSM mode is higher than that in WCDMA. However, considering the heat sink is more important in case of WCDMA. As mentioned before, a GSM signal is bursty, thus, the temperature drift is more insensible than WCDMA. Consequently, if you prescribe the heat dissipation in the WCDMA mode, you don’t need to think more about the GSM mode. As seen in the electrical design guidelines, the power supply must have a low ESR capacitor on the output to cut the current peaks and a protection diode on the input to protect the supply from spikes and polarity inversion. The placement of these components is crucial for the correct working of the circuitry. A misplaced component can be useless or can even decrease the power supply performances. The Bypass low ESR capacitor must be placed close to the Telit HE910 V2 power input pads, or in the case the power supply is a switching type, it can be placed close to the inductor to cut the ripple if the PCB trace from the capacitor to HE910 V2 is wide enough to ensure a drop-less connection even during the 2A current peaks. The protection diode must be placed close to the input connector where the power source is drained. The PCB traces from the input connector to the power regulator. IC must be wide enough to ensure no voltage drops to occur when the 2A current peaks are absorbed. Note that this is not made in order to save power loss but especially to avoid the voltage drops on the power line at the current peaks frequency of 216 Hz that will reflect on all the components connected to that supply (also introducing the noise floor at the burst base frequency.) For this reason while a voltage drop of 300-400 mV may be acceptable from the power loss point of view, the same voltage drop may not be acceptable from the noise point of view. If your application does not have audio interface but only uses the data feature of the Telit HE910 V2, then this noise is not so disturbing and power supply layout design can be more forgiving. The PCB traces to HE910 V2 and the Bypass capacitor must be wide enough to ensure no significant voltage drops to occur when the 2A current peaks are absorbed. This is a must for the same above-mentioned reasons. Try to keep this trace as short as possible. The PCB traces connecting the Switching output to the inductor and the switching diode must be kept as short as possible by placing the inductor and the diode very close to the power switching IC (only for switching power supply). This is done in order to reduce the radiated field (noise) at the switching frequency (usually 100-500 kHz). The use of a good common ground plane is suggested. The placement of the power supply on the board must be done in a way to guarantee that the high current return paths in the ground plane are not overlapped to any noise sensitive circuitry as the microphone amplifier/buffer or earphone amplifier. The power supply input cables must be kept separately from noise sensitive lines such as microphone/earphone cables. The antenna connection and board layout design are the most important parts in the full product design and they strongly reflect on the product’s overall performances. Read carefully and follow the requirements and the guidelines for a proper design. The antenna for a Telit HE910 V2 device must fulfill the following requirements: GSM / WCDMA Antenna Requirements Frequency range Bandwidth Impedance Input power Depending by frequency band(s) provided by the network operator, the customer must use the most suitable antenna for that/those band(s) HE910-EU/EUG V2 HE910-NA/NAG V2 GSM850 : 70 MHz GSM850 : 70 MHz GSM900 : 80 MHz GSM900 : 80 MHz GSM1800(DCS) : 170 MHz GSM1800(DCS) : 170 MHz GSM1900(PCS) : 140 MHz GSM1900(PCS) : 140 MHz WCDMA band I(2100) : 250 MHz WCDMA band II(1900) : 140 MHz WCDMA band VIII(900) : 80 MHz WCDMA band V(850) : 70 MHz 50 Ohm > 33dBm(2 W) peak power in GSM > 24dBm Average power in WCDMA <= 5:1(limit to avoid permanent damage) VSWR absolute max <= 2:1(limit to fulfill all regulatory requirements) VSWR recommended When using the Telit HE910 V2, since there’s no antenna connector on the module, the antenna must be connected to the HE910 V2 antenna pad (K1) by means of a transmission line implemented in the PCB. In the case that the antenna is not directly connected at the antenna pad of the HE910 V2, then a PCB line is required in order to connect with it or with its connector. This transmission line shall fulfill the following requirements: Antenna Line on PCB Requirements Characteristic Impedance 50Ohm Max Attenuation 0.3dB Coupling with other signals shall be avoided Cold End (Ground Plane) of antenna shall be equipotential to the HE910 V2 ground pads Furthermore if the device is developed for the US and/or Canada market, it must comply with the FCC and/or IC approval requirements: This device is to be used only for mobile and fixed application. In order to re-use the Telit FCC/IC approvals the antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter. If antenna is installed with a separation distance of less than 20 cm from all persons or is co-located or operating in conjunction with any other antenna or transmitter then additional FCC/IC testing may be required. End-Users must be provided with transmitter operation conditions for satisfying RF exposure compliance. OEM integrators must ensure that the end user has no manual instructions to remove or install the HE910 V2 module. Antennas used for this OEM module must not exceed 7.43dBi gain for 850MHz bands and 3dBi for 1900MHz bands for mobile and fixed operating configurations. Make sure that the transmission line’s characteristic impedance is 50ohm. Keep line on the PCB as short as possible since the antenna line loss shall be less than around 0.3dB. Line geometry should have uniform characteristics, constant cross section, avoid meanders and abrupt curves. Any kind of suitable geometry/structure can be used for implementing the printed transmission line afferent the antenna. If a Ground plane is required in line geometry, that plane has to be continuous and sufficiently extended so the geometry can be as similar as possible to the related canonical model. Keep, if possible, at least one layer of the PCB used only for the Ground plane; If possible, use this layer as reference Ground plane for the transmission line. It is wise to surround (on both sides) of the PCB transmission line with Ground. Avoid having other signal tracks facing directly the antenna line track. Avoid crossing any un-shielded transmission line footprint with other tracks on different layers. The Ground surrounding the antenna line on PCB has to be strictly connected to the main Ground plane by means of via holes (once per 2mm at least) placed close to the ground edges facing line track. Place EM noisy devices as far as possible from HE910 V2 antenna line. Keep the antenna line far away from the HE910 V2 power supply lines. If EM noisy devices are present on the PCB hosting the HE910 V2, such as fast switching ICs, take care of shielding them with a metal frame cover. If EM noisy devices are not present around the line use of geometries like Micro strip or Grounded Coplanar Waveguide are preferred since they typically ensure less attenuation when compared to a Strip line having same length. Install the antenna in a place covered by the GSM/WCDMA signal. The Antenna shall be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter; If the device antenna is located greater then 20cm from the human body and there are no co-located transmitter then the Telit FCC/IC approvals can be re-used by the end product. If the device antenna is located less then 20cm from the human body or there are no co-located transmitter then the additional FCC/IC testing may be required for the end product (Telit FCC/IC approvals cannot be reused) Antenna shall not be installed inside metal cases; Antenna shall be installed also according Antenna manufacturer instructions. The use of an active GPS/GNSS antenna is required to achieve better performance. The module is provided with a Digital Output signal to enable the external LNA (pad R7). Parameter Output high level Output low level Min 1.35V 0V Max 1.8V 0.45V The use of combined RF/GPS/GNSS antenna is NOT recommended. This solution could generate extremely poor GPS/GNSS reception and also the combined antenna requires additional diplexer and adds a loss in the RF route. In addition, the combination of antennas requires an additional diplexer, which adds significant power losses in the RF path. Using this type of antenna introduces at least 3dB of loss if compared to a circularly polarized (CP) antenna. Having a spherical gain response instead of a hemispherical gain response could aggravate the multipath behaviour & create poor position accuracy. Depending on the characteristics and requirements unique to the customer’s designs, the use of an external LNA or an external active antenna may be required to achieve best performance. The optional external LNA should be dimensioned to avoid an excessive LNA gain that can introduce jamming, spurious, degrade IIP3, and saturate the receiver. The configurations of an external device must fulfill the following requirements: An external passive antenna (GPS only) An external active antenna (GPS or GNSS) An external passive antenna, GNSS pre-Filter and GNSS LNA (GPS or GNSS) NOTE: The external GNSS LNA and GNSS pre-Filter shall be required for GLONASS application. GNSS LNA requirement shall fulfill the following specifications. Frequency = 1565 – 1606MHz Power Gain|S21|2 = 14 – 17dB NF < 1dB GNSS pre-Filter requirement shall fulfill the following requirements. Source and Load Impedance = 50Ohm Insertion Loss (1575.42 – 1576.42MHz) = 1.4dB (Max) Insertion Loss (1565.42 – 1585.42MHz) = 2.0dB (Max) Insertion Loss (1597.5515 – 1605.886MHZ) = 2.0dB (Max) WARNING: The HE910 V2 software is implemented differently depending on the configurations of an external device. Please refer to the AT command User Guide in detail. The external active antenna for the Telit HE910 V2 device must fulfill the following requirements: ACTIVE GPS/GNSS Antenna Requirements Frequency range Bandwidth Impedance LNA NF LNA Gain LNA Input Voltage GNSS(GPS L1 & GLONASS) : 1565 MHz ~ 1606 MHz GPS L1 : 1575.42MHz GLONASS : 1597.55 – 1605.89MHz GPS L1 : +/- 1.023MHz GLONASS : 8.34MHz 50 Ohm < 1dB 14 ~ 17dB 3.0V or 5.0V NOTE: The maximum DC voltage applicable to ANT_GPS pin is 5V. In case this is exceeded, a series capacitor has to be included in the design to avoid exceeding the maximum input DC level. An example of GNSS antenna supply circuit is shown in the following image: When using the Telit HE910 V2, since there’s no antenna connector on the module, the antenna must be connected to the HE910 V2 through the PCB with the antenna pad. In the case that the antenna is not directly connected at the antenna pad of the HE910 V2, then a PCB line is required. This line of transmission shall fulfill the following requirements: Antenna Line on PCB Requirements Characteristic Impedance 50Ohm Max Attenuation 0.3dB Coupling with other signals shall be avoided Cold End (Ground Plane) of antenna shall be equipotential to the HE910 V2 ground pads Furthermore if the device is developed for the US and/or Canada market, it must comply with the FCC and/or IC requirements. This device is to be used only for mobile and fixed application. Ensure that the antenna line impedance is 50ohm. Keep line on the PCB as short as possible to reduce the loss. Antenna line must have uniform characteristics, constant cross section, avoid meanders and abrupt curves. Keep one layer of the PCB used only for the Ground plane; if possible. Surround (on the sides, over and under) the antenna line on PCB with Ground. Avoid having other signal tracks directly facing the antenna line track. The Ground around the antenna line on PCB has to be strictly connected to the main Ground plane by placing vias once per 2mm at least. Place EM noisy devices as far as possible from HE910 V2 antenna line. Keep the antenna line far away from the HE910 V2 power supply lines. If EM noisy devices are around the PCB hosting the HE910 V2, such as fast switching ICs, take care of shielding of antenna line by burying it inside the layers of PCB and surround it with Ground planes; or shield it with a metal frame cover. If you do not have EM noisy devices around the PCB of HE910 V2, use a strip line on the superficial copper layer for the antenna line. The line attenuation will be lower than a buried one. The HE910 V2, due to its sensitivity characteristics, is capable of performing a fix inside buildings. (In any case the sensitivity could be affected by the building characteristics i.e. shielding) The Antenna must not be co-located or operating in conjunction with any other antenna or transmitter. Antenna shall not be installed inside metal cases. Antenna shall be installed also according antenna manufacture instructions. The HE910 V2 module includes a Universal Serial Bus (USB) transceiver, which operates at USB high-speed (480Mbits/sec). It is compliant with the USB 2.0 specification and can be used for diagnostic monitoring, control and data transfers. The table below describes the USB interface signals: Pin Signal I/O Function B15 USB_D+ I/O USB differential Data(+) C15 USB_D- I/O USB differential Data(+) A13 VBUS Power sense for the internal USB transceiver Type 5V The USB_DPLUS and USB_DMINUS signals have a clock rate of 480MHz. The signal traces should be routed carefully. Trace lengths, number of vias and capacitive loading should be minimized. The impedance value should be as close as possible to 90 Ohms differential. WARNING: Consider a mechanical design and a low-capacitance ESD protection device to protect HE910 V2 or customer specific requirements from ESD event to USB lines (B15, C15 and A13). The serial ports on the Telit HE910 V2 are the interface between the module and OEM hardware. 2 serial ports are available on the module: Modem Serial Port 1 (Main) Modem Serial Port 2 (Auxiliary) Several configurations can be designed for the serial port on the OEM hardware. The most common are: RS232 PC comport Microcontroller UART@1.8V(Universal Asynchronous Receiver Transmit) Microcontroller UART@5V or other voltages different from 1.8V Depending on the type of serial port on the OEM hardware, a level translator circuit may be needed to make the system work. Serial port 1 is a +1.8V UART with all the 7 RS232 signals. Serial port 2 is a +1.8V Auxiliary UART. The electrical characteristics of the serial port are explained in the following tables: Absolute Maximum Ratings -Not Functional Parameter Input level on non-power pin with respect to ground Operating Range - Interface levels Parameter Min Max Input high level 1.5V 2.1 V Input low level -0.3V 0.35V Output high level 1.35V 1.8V Output low level 0V 0.45V Min Max -0.3 +2.3V Serial port 1 on the HE910 V2 is a +1.8V UART with all 7 RS232 signals. It differs from the PC-RS232 in the signal polarity (RS232 is reversed) and levels. Pin Signal I/O Function Type N14 DCD - dcd_uart Data Carrier Detect 1.8V M15 RXD - Tx_uart Transmit line *see Note 1.8V N15 TXD - Rx_uart Receive line *see Note 1.8V M14 DTR - dtr_uart Data Terminal Ready 1.8V P14 DSR - dsr_uart Data Set Ready 1.8V L14 RTS - rts_uart Request to Send 1.8V P15 CTS - cts_uart Clear to Send 1.8V R14 RI - ri_uart Ring Indicator 1.8V NOTE: For minimum implementation, only the TXD and RXD lines must be connected, the other lines can be left open provided a software flow control is implemented. NOTE: In order to avoid a back powering effect it is recommended to avoid having any HIGH logic level signal applied to the digital pins of the HE910 V2 when the module is powered off or during an ON/OFF transition. NOTE: According to V.24, RX/TX signal names are referred to the application side. Therefore, on the HE910 V2 side these signals are in the opposite direction: TXD on the application side will be connected to the receive line (here named TXD/ rx_uart) of the HE910 V2 serial port and vice versa for RX. NOTE: High-speed UART supports up to 4Mbps. Please refer to the AT command User Guide in detail. WARNING: Consider a mechanical design and a low-capacitance ESD protection device to protect HE910 V2 or customer specific requirements from ESD event to UART port (M15, N15, P15 and L14). Serial port 2 on the HE910 V2 is a +1.8V UART with only the RX and TX signals. The signals of the HE910 V2 serial port are: PAD Signal I/O Function Type D15 TX_AUX Auxillary UART (TX Data to DTE) 1.8V E15 RX_AUX Auxillary UART (RX Data from DTE) 1.8V NOTE: In order to avoid a back powering effect it is recommended to avoid having any HIGH logic level signal applied to the digital pins of the HE910 V2 when the module is powered off or during an ON/OFF transition. In order to interface the Telit HE910 V2 with a PC com port or a RS232 (EIA/TIA-232) application, a level translator is required. This level translator must: Invert the electrical signal in both directions Change the level from 0/1.8V to +/-15V Actually, the RS232 UART 16450, 16550, 16650 & 16750 chipsets accept signals with lower levels on the RS232 side (EIA/TIA-562), allowing a lower voltage-multiplying ratio on the level translator. Note that the negative signal voltage must be less than 0V and hence some sort of level translation is always required. The simplest way to translate the levels and invert the signal is by using a single chip level translator. There are a multitude of them, differing in the number of drivers and receivers and in the levels (be sure to get a true RS232 level translator not a RS485 or other standards). By convention the driver is the level translator from the 0-1.8V UART to the RS232 level. The receiver is the translator from the RS232 level to 0-1.8V UART. In order to translate the whole set of control lines of the UART you will need: 5 drivers 3 receivers An example of RS232 level adaption circuitry could be accomplished using a MAXIM transceiver (MAX218). In this case the chipset is capable of translating directly from 1.8V to the RS232 levels (Example on 4 signals only). NOTE: In this case the length of the lines on the application has to be taken into account to avoid problems in case of High-speed rates on RS232. The RS232 serial port lines are usually connected to a DB9 connector with the following layout: The HE910 V2 module doesn’t support an analog audio interface and supports one Digital Audio bus. In order to develop an application including an Analog Audio it is necessary to add a dedicated CODEC on the Application design. For further information, please refer to the “Digital Voice Interface Application Note”. The product is providing one Digital Audio Interface (DVI) on the following Pins: Pin Signal I/O Function B9 DVI_WA0 I/O Digital Voice interface (WA0) B6 DVI_RX Digital Voice interface (RX) B7 DVI_TX Digital Voice interface (TX) B8 DVI_CLK I/O Digital Voice interface (CLK) Type 1.8V Please refer to the Digital Voice Interface Application note. The general-purpose I/O pads can be configured to act in three different ways: Input Output Alternate function (internally controlled) Input pads can only be read and report the digital value (high or low) present on the pad at the read time. Output pads can only be written to set the value of the pad or queried. An alternate function pad is internally controlled by the HE910 V2 firmware and acts depending on the function implemented. The following GPIOs are available on the HE910 V2. Pin Signal I/O Function Drive Strength Type C8 GPIO_01 I/O Configurable GPIO 2 mA 1.8V C9 GPIO_02 I/O Configurable GPIO 2 mA 1.8V C10 GPIO_03 I/O Configurable GPIO 2 mA 1.8V C11 GPIO_04 I/O Configurable GPIO 2 mA 1.8V B14 GPIO_05 I/O Configurable GPIO 2 mA 1.8V C12 GPIO_06 I/O Configurable GPIO 2 mA 1.8V C13 GPIO_07 I/O Configurable GPIO 2 mA 1.8V K15 GPIO_08 I/O Configurable GPIO 2 mA 1.8V L15 GPIO_09 I/O Configurable GPIO 2 mA 1.8V G15 GPIO_10 I/O Configurable GPIO 2 mA 1.8V Where not specifically stated, all the interface circuits work at 1.8V CMOS logic levels. The following table shows the logic level specifications used in the HE910 V2 interface circuits: Absolute Maximum Ratings -Not Functional Parameter Min Max Input level on any digital pin (CMOS 1.8) with respect to ground -0.3V 2.3V Operating Range - Interface levels (1.8V CMOS) Parameter Min Max Input high level 1.5V 2.1V Input low level 0.0V 0.35V Output high level 1.35V 1.8V Output low level 0.0V 0.45V Current characteristics Parameter Typical Output Current 2mA Input Current 30uA The GPIO pads, when used as inputs, can be connected to a digital output of another device and report its status, provided this device has interface levels compatible with the 1.8V CMOS levels of the GPIO. If the digital output of the device is connected with the GPIO input, the pad has interface levels different from the 1.8V CMOS. It can be buffered with an open collector transistor with a 4.7KΩ pull-up resistor to 1.8V. NOTE: In order to avoid a back powering effect it is recommended to avoid having any HIGH logic level signal applied to the digital pins of the module when it is powered OFF or during an ON/OFF transition. The GPIO pads, when used as outputs, can drive 1.8V CMOS digital devices or compatible hardware. When set as outputs, the pads have a push-pull output and therefore the pull-up resistor may be omitted. The Temperature Monitor is a function of the module that permits control of its internal temperature and if properly set (see the #TEMPMON command on AT Interface guide) raises to High Logic level a GPIO when the maximum temperature is reached. The STAT_LED pin status shows information on the network service availability and Call status. In the HE910 V2 modules, the STAT_LED usually needs an external transistor to drive an external LED. Because of the above, the status indicated in the following table is reversed with respect to the pin status: Device Status LED status Device off Not registered Registered in idle Permanently off Permanently on Blinking 1 sec on + 2 sec off Registered in idle + power saving It depends on the event that triggers the wakeup (In sync with network paging) Voice Call Active Dial-Up Permanently on Blinking 1 sec on + 2 sec off A schematic example could be: The VRTC pin brings out the Real Time Clock supply, which is separate from the rest of the digital part, allowing only RTC to be active when all the other parts of the device are off. To this power output a backup capacitor can be added in order to increase the RTC autonomy during power off of the battery. NOTE: NO devices must be powered from this pin. A regulated power supply output is provided in order to supply small devices from the module. This output is active when the module is ON and goes OFF when the module is shut down. The operating range characteristics of the supply are: Operating Range – VAUX/PWRMON power supply Parameter Output voltage Min Typical Max 1.77V 1.8V 1.83V 100mA Output current Output bypass capacitor (Inside the module) 1.0μF The HE910 V2 module provides a Digital to Analog Converter. The signal (named DAC_OUT) is available on pin C13 of the HE910 V2 module and on pin 6 of PL302 on Interface Board (CS1467D). The on board DAC is in the range from 0 to 1023. However, an external low-pass filter is necessary. Parameter Min Max Units Voltage range (filtered) 1.8 Volt Range 1023 Steps The precision is 1023 steps, so since the maximum voltage is 2V, the integrated voltage could be calculated with the following formula: Integrated output voltage = 2 * value / 1023 DAC_OUT line must be integrated (for example with a low band pass filter) in order to obtain an analog voltage. An AT command is available to use the DAC function. The command is: AT#DAC[=[, ]] - scale factor of the integrated output voltage (0..1023 ~ 10 bit precision) it must be present if =1 Refer to SW User Guide or AT Commands Reference Guide for the full description of this function. NOTE: The DAC frequency is selected internally. D/A converter must not be used during POWERSAVING. The on board ADC is 8-bit converter. It is able to read a voltage level in the range of 0 ~ 1.2 volts applied on the ADC pin input and store and convert it into 8 bit word. Parameter Min Max Units Input Voltage range 1.2 Volt AD conversion bits Resolution < 10 mV Input Resistance Mohm The HE910 V2 provides one Analog to Digital Converter. The input lines are: ADC available on pin B1 and Pin 7 of PL102 on Interface Board (CS1467D) An AT command is available to use the ADC function. The command is AT#ADC=1,2. The read value is expressed in mV Refer to SW User Guide or AT Commands Reference Guide for the full description of this function. The HE910 V2 has been designed in order to be compliant with a standard lead-free SMT process. Top view Bottom view (Dimensions in mm) 144 pins < Top View > In order to easily rework the HE910 V2 it is suggested to consider having a 1.5 mm placement inhibit area around the module on the application. It is also suggested, as a common rule for an SMT component, to avoid having a mechanical part of the application in direct contact with the module. NOTE: In the customer application, the region under WIRING INHIBIT (see figure) must be clear from signal or ground paths. Stencil’s apertures layout can be the same as the recommended footprint (1:1), we suggest a thickness of stencil foil ≥ 120 µm. Non solder mask defined (NSMD) type is recommended for the solder pads on the PCB. The recommendation for the PCB pads dimensions are described in the following image (dimensions in mm) It is not recommended to place via or micro-via not covered by solder resist in an area of 0,3 mm around the pads unless it carries the same signal of the pad itself (see following figure). Holes in pad are allowed only for blind holes and not for through holes. Recommendations for PCB Pad Surfaces: Finish Electro-less Ni / Immersion Au Layer thickness (um) 3 ~ 7 / 0.05 ~ 0.15 Properties good solder ability protection, high shear force values The PCB must be able to resist the higher temperatures which are occurring at the lead-free process. This issue should be discussed with the PCB-supplier. Generally, the wettability of tin-lead solder paste on the described surface plating is better compared to lead-free solder paste. It is not necessary to panel the application’s PCB, however in that case it is suggested to use milled contours and predrilled board breakouts; scoring or v-cut solutions are not recommended. Lead free Solder Paste Sn/Ag/Cu We recommend using only “no clean” solder paste in order to avoid the cleaning of the modules after assembly. Recommended solder reflow profile: Profile Feature Average ramp-up rate(TL to Tp) Preheat - Temperature Min(Tsmin) - Temperature Max(Tsmax) - Time (min to max) (ts) Tsmax to TL - Ramp-up Rate Time maintained above: - Temperature (TL) - Time(tL) Peak Temperature (Tp) Time within 5℃ of actual Peak Temperature(tp) Ramp-down Rate Time 25℃ to Peak Temperature Pb-Free Assembly 3℃/second max 150℃ 200℃ 60 - 180 seconds 3℃/second max 217℃ 60 - 150 seconds 245 +0/-5℃ 10 - 30 seconds 6℃/sec max 8 minutes max NOTE: All temperatures refer to topside of the package, measured on the package body surface. WARNING: The HE910 V2 module withstands one reflow process only. The HE910 V2 modules are packaged on trays of 20 pieces each. These trays can be used in SMT processes for pick & place handling. WARNING: These trays can withstand a maximum temperature of 65℃. The HE910 V2 is a Moisture Sensitive Device level 3, in accordance with standard IPC/JEDEC J-STD-020, take care all the relatives requirements for using this kind of components. Moreover, the customer has to take care of the following conditions: a) Calculated shelf life in sealed bag: 12 months at <40°C and <90% relative humidity (RH). b) Environmental condition during the production: 30°C / 60% RH according to IPC/JEDEC J-STD-033A paragraph 5. c) The maximum time between the opening of the sealed bag and the reflow process must be 168 hours if condition b) “IPC/JEDEC J-STD-033A paragraph 5.2” is respected d) Baking is required if conditions b) or c) are not respected e) Baking is required if the humidity indicator inside the bag indicates 10% RH or more To test and debug the mounting of HE910 V2, we strongly recommend foreseeing test pads on the host PCB, in order to check the connection between the HE910 V2 itself and the application and to test the performance of the module connecting it with an external computer. Depending on the customer application, these pads include, but are not limited to the following signals: TXD RXD ON_OFF HW_SHUTDOWN GND VBATT and VBATT_PA TX_AUX RX_AUX VAUX/PWRMON VBUS USB_D+ USB_D- When a sudden voltage is asserted to or cut from the power supplies, The steep transition makes some reactions such as the overshoot and undershoot. This abrupt voltage transition can affect the device not to work or make it malfunction. The bypass capacitors are needed to alleviate this behavior and it can be affected differently according to the various applications. The customers have to pay special attention to this when they design their application board. The length and width of the power lines need to be considered carefully and the capacitance of the capacitors needs to be selected accordingly. The capacitor will also avoid the ripple of the power supplies and the switching noise caused in TDMA system like GSM. Especially the suitable bypass capacitor must be mounted on the VBATT and VBATT_PA lines in the application board. The recommended values can be presented as; 100uF for VBATT and VBATT_PA But the customers still have to consider that the capacitance mainly depends on the conditions of their application board. Generally more capacitance is required as the power line is longer. This section deals with the recommended schematics for the design of SIM interfaces on the application boards. Figure 1 illustrates in particular how the application side should be designed, and what values the components should have. NOTE FOR R1: The resistor value on SIMIO pulled up to SIMVCC should be defined accordingly in order to be compliant to 3GPP specification. For HE910-EUG V2/NAG V2/EU V2/NA V2 contain an internal pull-up resistor on SIMIO. However, the un-mounted option in application design can be recommended in order to tune R1 if necessary. The following Table lists the values of C1 to be adopted with the HE910 V2 product: Product P/N HE910-EUG/NAG V2 HE910-EU/NA V2 Refer to the following document for the detail; C1 range (nF) 100 nF Telit_SIM_Integration_Design_Guide_Application_Note One of the following options should be chosen in the design of host system in order to download or upgrade the Telit’s software and debug HE910 V2 when HE910 V2 is already mounted on a host system. Users who use both of UART and USB interfaces to communicate HE910 V2 Must implement a download method in a host system for upgrading HE910 V2 when it’s mounted. Users who use USB interface only to communicate HE910 V2 Must arrange UART port in a host system for debugging or upgrading HE910 V2 when it’s mounted. Users who use UART interface only to communicate HE910 V2 Must arrange USB port in a host system for debugging or upgrading HE910 V2 when it’s mounted. The HE910-EU V2 and HE910-EUG V2 modules have been assessed in order to satisfy the essential requirements of the R&TTE Directive 1999/05/EC (Radio Equipment & Telecommunications Terminal Equipments) to demonstrate the conformity against the harmonized standards with the final involvement of a Notified Body. In order to satisfy the essential requirements of 1999/5/EC Directive, the HE910-EUG V2 is compliant with the following standards: RF spectrum use (R&TTE art. 3.2) EN 300 440-2 V1.4.1 EN 301 511 V9.0.2 EN 301 908-1 V5.2.1 EN 301 908-2 V5.2.1 EMC (R&TTE art. 3.1b) EN 301 489-1 V1.9.2 EN 301 489-3 V1.4.1 EN 301 489-7 V1.3.1 EN 301 489-24 V1.5.1 Health & Safety (R&TTE art. 3.1a) EN 60950-1:2006 + A11:2009 + A1:2010 + A12:2011+AC:2011 The HE910-EU V2 module is compliant with the following standards: RF spectrum use (R&TTE art. 3.2) EN 301 511 V9.0.2 EN 301 908-1 V5.2.1 EN 301 908-2 V5.2.1 EMC (R&TTE art. 3.1b) EN 301 489-1 V1.9.2 EN 301 489-7 V1.3.1 EN 301 489-24 V1.5.1 Health & Safety (R&TTE art. 3.1a) EN 60950-1:2006 + A11:2009 + A1:2010 + A12:2011+AC:2011 The conformity assessment procedure referred to in Article 10 and detailed in Annex IV of Directive 1999/5/EC has been followed with the involvement of the following Notified Body: AT4 wireless, S.A. Parque Tecnologico de Andalucía C/ Severo Ochoa 2 29590 Campanillas – Málaga SPAIN Notified Body No: 1909 Thus, the following marking is included in the product: The full declaration of conformity can be found on the following address: http://www.telit.com There is no restriction for the commercialization of the HE910-EU V2 and HE910-EUG V2 modules in all the countries of the European Union. Final product integrating this module must be assessed against essential requirements of the 1999/5/EC (R&TTE) Directive. It should be noted that assessment does not necessarily lead to testing. Telit Communications S.p.A. recommends carrying out the following assessments: RF spectrum use (R&TTE art. 3.2) EMC (R&TTE art. 3.1b) Health & Safety (R&TTE art. 3.1a) It will depend on the antenna used on the final product. Testing Testing Alternately, assessment of the final product against EMC (Art. 3.1b) and Electrical safety (Art. 3.1a) essential requirements can be done against the essential requirements of the EMC and the LVD Directives: Low Voltage Directive 2006/95/EC and product safety Directive EMC 2004/108/EC for conformity for EMC Modification statement Telit has not approved any changes or modifications to this device by the user. Any changes or modifications could void the user’s authority to operate the equipment. Telit n’approuve aucune modification apportée à l’appareil par l’utilisateur, quelle qu’en soit la nature. Tout changement ou modification peuvent annuler le droit d’utilisation de l’appareil par l’utilisateur. Interference statement This device complies with Part 15 of the FCC Rules and Industry Canada licence-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. This Class B digital apparatus complies with Canadian ICES-0003. Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio exempts de licence. L'exploitation est autorisée aux deux conditions suivantes : (1) l'appareil ne doit pas produire de brouillage, et (2) l'utilisateur de l'appareil doit accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible d'en compromettre le fonctionnement. Wireless notice This equipment complies with FCC and IC radiation exposure limits set forth for an uncontrolled environment. The antenna should be installed and operated with minimum distance of 20 cm between the radiator and your body. Antenna gain must be below: Frequency band GSM/GPRS850 FDD V GSM/GPRS1900 / FDD II HE910-NA V2 7.43 dBi 8.45 dBi 3.0 dBi HE910-NAG V2 7.43 dBi 8.45 dBi 3.0 dBi This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter. Cet appareil est conforme aux limites d'exposition aux rayonnements de la IC pour un environnement non contrôlé. L'antenne doit être installé de façon à garder une distance minimale de 20 centimètres entre la source de rayonnements et votre corps. Gain de l'antenne doit être ci-dessous: Bande de fréquence GSM/GPRS850 FDD V GSM/GPRS1900 / FDD II HE910-NA V2 7.43 dBi 8.45 dBi 3.0 dBi HE910-NAG V2 7.43 dBi 8.45 dBi 3.0 dBi L'émetteur ne doit pas être colocalisé ni fonctionner conjointement avec à autre antenne ou autre émetteur. FCC Class B digital device notice This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures: - Reorient or relocate the receiving antenna. - Increase the separation between the equipment and receiver. - Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. - Consult the dealer or an experienced radio/TV technician for help. Information To Be Supplied to the End User by the OEM or Integrator notice Modular information form OEM Information to Be Supplied to the End User by the OEM or Integrator The following regulatory and safety notices must be published in documentation supplied to the end user of the product or system incorporating an adapter in compliance with local regulations. Host system must be labeled with "Contains IC: 5131A-HE910NAV2 " or "Contains FCCID:RI7HE910NAV2 ", FCC ID/IC displayed on label. READ CAREFULLY Be sure about that the use of this product is allowed in your country and in the environment required. The use of this product may be dangerous and has to be avoided in the following areas: Where it can interfere with other electronic devices in environments such as hospitals, airports, aircrafts, etc. Where there is risk of explosion such as gasoline stations, oil refineries, etc. It is responsibility of the user to enforce the country regulation and the specific environment regulation. Do not disassemble the product; any mark of tampering will compromise the warranty validity. We recommend following the instructions of the hardware user guides for a correct wiring of the product. The product has to be supplied with a stabilized voltage source and the wiring has to be conforming to the security and fire prevention regulations. The product has to be handled with care, avoiding any contact with the pins because electrostatic discharges may damage the product itself. Same cautions have to be taken for the SIM, checking carefully the instruction for its use. Do not insert or remove the SIM when the product is in power saving mode. The system integrator is responsible of the functioning of the final product; therefore, care has to be taken to the external components of the module, as well as of any project or installation issue, because the risk of disturbing the GSM network or external devices or having impact on the security. Should there be any doubt, please refer to the technical documentation and the regulations in force. Every module has to be equipped with a proper antenna with specific characteristics. The antenna has to be installed with care in order to avoid any interference with other electronic devices and has to be installed with the guarantee of a minimum 20 cm distance from the body. In case of this requirement cannot be satisfied, the system integrator has to assess the final product against the SAR regulation. The European Community provides some Directives for the electronic equipments introduced on the market. All the relevant information are available on the European Community website: http://europa.eu.int/comm/enterprise/rtte/dir99-5.htm The text of the Directive 99/05 regarding telecommunication equipments is available, while the applicable Directives (Low Voltage and EMC) are available at: http://europa.eu.int/comm/enterprise/rtte/dir99-5.htm Revision Date 2013-05-14 2013-11-08 2013-11-27 Changes First issue Updated 6.1 GSM/WCDMA Antenna Requirements Updated 8.1 Modem Serial Port 1 Updated 10.5 Indication of Network Service Availability Updated 14.3 SIM Interface Updated 15 Conformity Assessment Issues Updated 2.5 Environmental requirements Updated 6.1 GSM/WCDMA Antenna Requirements Updated 15.2 FCC/IC Regulatory notices
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