Cinterion® ALAS5V Hardware Interface Description Version: DocId: 00.030a ALAS5V_HID_v00.030a GEMALTO.
Cinterion® ALAS5V Hardware Interface Description Page 2 of 124 2 Document Name: Cinterion® ALAS5V Hardware Interface Description Version: 00.030a Date: 2019-03-20 DocId: ALAS5V_HID_v00.030a Status Confidential / Preliminary GENERAL NOTE THE USE OF THE PRODUCT INCLUDING THE SOFTWARE AND DOCUMENTATION (THE "PRODUCT") IS SUBJECT TO THE RELEASE NOTE PROVIDED TOGETHER WITH PRODUCT. IN ANY EVENT THE PROVISIONS OF THE RELEASE NOTE SHALL PREVAIL.
Cinterion® ALAS5V Hardware Interface Description Page 3 of 124 Contents 124 Contents 1 Introduction ................................................................................................................. 8 1.1 Product Variants ................................................................................................ 8 1.2 Key Features at a Glance .................................................................................. 9 1.2.1 Supported Frequency Bands ..........................
Cinterion® ALAS5V Hardware Interface Description Page 4 of 124 Contents 124 2.4 Sample Application .......................................................................................... 58 2.4.1 Prevent Back Powering....................................................................... 60 2.4.2 Sample Level Conversion Circuit........................................................ 61 2.4.3 Sample Circuit for Antenna Detection................................................. 62 3 GNSS Interface ..
Cinterion® ALAS5V Hardware Interface Description Page 5 of 124 Contents 124 5.2.4 5.3 Durability and Mechanical Handling.................................................. 103 5.2.4.1 Storage Conditions............................................................ 103 5.2.4.2 Processing Life.................................................................. 103 5.2.4.3 Baking ............................................................................... 104 5.2.4.4 Electrostatic Discharge ................
Cinterion® ALAS5V Hardware Interface Description Page 6 of 124 Tables 124 Tables Table 1: Table 2: Table 3: Table 4: Table 5: Table 6: Table 7: Table 8: Table 9: Table 10: Table 11: Table 12: Table 13: Table 14: Table 15: Table 16: Table 17: Table 18: Table 19: Table 20: Table 21: Table 22: Table 23: Table 24: Table 25: Table 26: Table 27: Table 28: Table 29: Table 30: Table 31: Table 32: Table 33: Table 34: Table 35: Table 36: Table 37: Table 38: Table 39: Table 40: Supported frequency bands for eac
Cinterion® ALAS5V Hardware Interface Description Page 7 of 124 Figures 124 Figures Figure 1: Figure 2: Figure 3: Figure 4: Figure 5: Figure 6: Figure 7: Figure 8: Figure 9: Figure 10: Figure 11: Figure 12: Figure 13: Figure 14: Figure 15: Figure 16: Figure 17: Figure 18: Figure 19: Figure 20: Figure 21: Figure 22: Figure 23: Figure 24: Figure 25: Figure 26: Figure 27: Figure 28: Figure 29: Figure 30: Figure 31: Figure 32: Figure 33: Figure 34: Figure 35: Figure 36: Figure 37: Figure 38: Figure 39: Figure
Cinterion® ALAS5V Hardware Interface Description Page 8 of 124 1 Introduction 16 1 Introduction This document1 describes the hardware of the Cinterion® ALAS5V module. It helps you quickly retrieve interface specifications, electrical and mechanical details and information on the requirements to be considered for integrating further components. 1.
Cinterion® ALAS5V Hardware Interface Description Page 9 of 124 1.2 Key Features at a Glance 16 1.2 Key Features at a Glance Feature Implementation General Frequency bands Note: Not all of the frequency bands (and 3GPP technologies) mentioned throughout this document are supported by every ALAS5V product variant. Please refer to Section 1.2.1 for an overview of the frequency bands supported by each ALAS5V product variant.
Cinterion® ALAS5V Hardware Interface Description Page 10 of 124 1.2 Key Features at a Glance 16 Feature Implementation UMTS features 3GPP Release 8 PS data rate – 384 kbps DL / 384 kbps UL TD-SCDMA features 3GPP Release 4 2.8 Mbps DL / 2.
Cinterion® ALAS5V Hardware Interface Description Page 11 of 124 1.2 Key Features at a Glance 16 Feature Implementation Antenna 50. GSM/UMTS/LTE main antenna, LTE Diversity/MIMO antenna, (active/passive) GNSS antenna USB USB 2.0 High Speed (480Mbit/s) device interface or USB 3.
Cinterion® ALAS5V Hardware Interface Description Page 12 of 124 1.2 Key Features at a Glance 16 1.2.1 Supported Frequency Bands The following table lists the supported frequency bands for each of the ALAS5V product variants mentioned in Section 1.1. Supported CA configurations can be found in Section 1.2.2.
Cinterion® ALAS5V Hardware Interface Description Page 13 of 124 1.2 Key Features at a Glance 16 Table 1: Supported frequency bands for each product variant Band ALAS5V-W ALAS5V-CN ALAS5V-E ALAS5V-US LTE-TDD Bd.38 (2600MHz) x x Bd.39 (1900MHz) x x Bd.40 (2300MHz) x x Bd.41 (2600MHz)1 x x 1. Note: Out of the 3GPP specified frequency range for LTE Band 41, only that part which is used in China and Japan (2545MHz to 2655MHz) is supported by ALAS5V.
Cinterion® ALAS5V Hardware Interface Description Page 14 of 124 1.2 Key Features at a Glance 16 Table 2: Supported CA configurations Downlink CA Bandwidth combination set Product variant (ALAS5V-...
Cinterion® ALAS5V Hardware Interface Description Page 15 of 124 1.3 ALAS5V System Overview 16 Table 2: Supported CA configurations Downlink CA Bandwidth combination set Product variant (ALAS5V-...) CA_20A-38A 0 W CA_20A-40A 0 W CA_28A-40A 0 W CA_29A-66A 0 US 1.
Cinterion® ALAS5V Hardware Interface Description Page 16 of 124 1.4 Circuit Concept 16 1.
Cinterion® ALAS5V Hardware Interface Description Page 17 of 124 2 Interface Characteristics 67 2 Interface Characteristics ALAS5V is equipped with an SMT application interface that connects to the external application. The SMT application interface incorporates the various application interfaces as well as the RF antenna interface. 2.1 Application Interface 2.1.1 Pad Assignment The SMT application interface on the ALAS5V provides connecting pads to integrate the module into external applications.
Cinterion® ALAS5V Hardware Interface Description Page 18 of 124 2.1 Application Interface 67 Table 3: Overview: Pad assignments Pad No. Signal Name Pad No.
Cinterion® ALAS5V Hardware Interface Description Page 19 of 124 2.
Cinterion® ALAS5V Hardware Interface Description Page 20 of 124 2.
Cinterion® ALAS5V Hardware Interface Description Page 21 of 124 2.1 Application Interface 67 2.1.2 Signal Properties Please note that the reference voltages listed in Table 4 are the values measured directly on the ALAS5V module. They do not apply to the accessories connected. Table 4: Signal description Function Signal name IO Power sup- BATT+ ply BATT+_RF I Signal form and level Comment VImax = 4.2V VImin = 3.
Cinterion® ALAS5V Hardware Interface Description Page 22 of 124 2.1 Application Interface 67 Table 4: Signal description Function Signal name IO Signal form and level Comment Ignition IGT RPU 200k VOHmax = 1.84V VIHmax =2.00V VIHmin = 1.30V VILmax = 0.50V This signal switches the module on. I Low impulse width > 100ms It is required to drive this line low by an open drain or open collector driver connected to GND. Test point recommended. Emergency off EMERG_ OFF I RPU 40k VOHmax = 1.
Cinterion® ALAS5V Hardware Interface Description Page 23 of 124 2.1 Application Interface 67 Table 4: Signal description Function Signal name IO Signal form and level Comment 2.85V SIM card interfaces CCRST1 CCRST2 VOLmax = 0.4V at I = 2mA VOLnom = 0.1V at I = 100µA VOHmin = 2.2V at I = -2mA VOHnom = 2.65V at I = -100µA VOHmax = 2.91V Maximum cable length or copper track should be not longer than 100mm to SIM card holder. O CCCLK1 CCCLK2 CCIO1 CCIO2 I/O RPU 6.7..8.5k VILmax = 0.
Cinterion® ALAS5V Hardware Interface Description Page 24 of 124 2.1 Application Interface 67 Table 4: Signal description Function Signal name IO Signal form and level Comment Serial Modem Interface ASC1 RXD1 O CTS1 O VOLmax = 0.45V at I = 2mA VOLnom = 0.1V at I = 100µA VOHmin = 1.30V at I = -2mA VOHnom = 1.65V at I = -100µA VOHmax = 1.84V Test points recommended for RXD1, TXD1, CTS1, RTS1.
Cinterion® ALAS5V Hardware Interface Description Page 25 of 124 2.1 Application Interface 67 Table 4: Signal description Function Signal name IO Signal form and level Comment USB VUSB_IN VINmin = 3.0V VINmax = 5.75V USB detection. I Test point recommended. IImax = 100µA Cin=1µF USB_DN USB_DP I/O Full and High speed signal (differential) characteristics according to USB I/O 2.0 specification. If unused keep lines open. Test point recommended.
Cinterion® ALAS5V Hardware Interface Description Page 26 of 124 2.1 Application Interface 67 Table 4: Signal description Function Signal name IO GPIO interface GPIO1, GPIO3...8, GPIO11...17, GPIO22 Signal form and level Comment I/O VOLmax = 0.45V at I = 2mA VOLnom = 0.1V at I = 100µA VOHmin = 1.30V at I = -2mA VOHnom = 1.65V at I = -100µA VOHmax = 1.84V GPIO3, GPIO5...GPIO7, GPIO8, and GPIO16 are interrupt enabled. They can be used to for instance wake up the module (see Section 2.1.12).
Cinterion® ALAS5V Hardware Interface Description Page 27 of 124 2.1 Application Interface 67 Table 4: Signal description Function Signal name IO Signal form and level PCIe PCIE_RX_N According to PCI Express Specification, Revision 2.0/2.1 (one lane, 5 GBit/s) I PCIE_RX_P PCIE_TX_N Comment O PCIE_TX_P PCIE_CLK_N I/O PCIE_CLK_P PCIE_CLK_REQ IO PCIE_HOST_ O RST PCIE_HOST_ I WAKE I2C interface I2CDAT1 I2CCLK1 VOLmax = 0.45V at I = 2mA VOLnom = 0.1V at I = 100µA VOHmin = 1.
Cinterion® ALAS5V Hardware Interface Description Page 28 of 124 2.1 Application Interface 67 Table 4: Signal description Function Signal name IO Signal form and level Comment eMMC interface EMMC_ DETECT VOLmax = 0.45V at I = 2mA VOLnom = 0.1V at I = 100µA VOHmin = 1.30V at I = -2mA VOHnom = 1.65V at I = -100µA VOHmax = 1.84V eMMC I VILmax = 0.50V VIHmin = 1.30V VIHmax = 2.0V IIHPD = 27.5µA…97.5µA IILPU = -27.5µA…-97.5µA IHigh-Z max= ±1µA 1.8V eMMC EMMC_PWR O VOUT (nom) = 2.95V / 1.
Cinterion® ALAS5V Hardware Interface Description Page 29 of 124 2.1 Application Interface 67 2.1.2.1 Absolute Maximum Ratings The absolute maximum ratings stated in Table 5 are stress ratings under any conditions. Stresses beyond any of these limits will cause permanent damage to ALAS5V. Table 5: Absolute maximum ratings (TBD.) Parameter Min Max Unit Supply voltage BATT+ -0.3 +5.5 V Voltage at all digital lines in Power Down mode (except VEXT) -0.3 +0.
Cinterion® ALAS5V Hardware Interface Description Page 30 of 124 2.1 Application Interface 67 2.1.3 USB Interface ALAS5V supports a USB 3.0 Super Speed (5Gbps) device interface, and alternatively a USB 2.0 device interface that is High Speed compatible. The USB interface is primarily intended for use as command and data interface, and for downloading firmware. The USB host is responsible for supplying the VUSB_IN line. This line is for voltage detection only.
Cinterion® ALAS5V Hardware Interface Description Page 31 of 124 2.1 Application Interface 67 2.1.4 Serial Interface ASC0 ALAS5V offers an 8-wire (plus GND) unbalanced, asynchronous modem interface ASC0 conforming to ITU-T V.24 protocol DCE signaling. The electrical characteristics do not comply with ITU-T V.28. The significant levels are 0V (for low data bit or active state) and 1.8V (for high data bit or inactive state). For electrical characteristics please refer to Table 4.
Cinterion® ALAS5V Hardware Interface Description Page 32 of 124 2.1 Application Interface 67 Table 6: DCE-DTE wiring of ASC0 V.24 circuit DCE DTE Line function Signal direction Line function Signal direction 103 TXD0 Input TXD Output 104 RXD0 Output RXD Input 105 RTS0 Input RTS Output 106 CTS0 Output CTS Input 108/2 DTR0 Input DTR Output 107 DSR0 Output DSR Input 109 DCD0 Output DCD Input 125 RING0 Output RING Input 2.1.
Cinterion® ALAS5V Hardware Interface Description Page 33 of 124 2.1 Application Interface 67 2.1.6 Inter-Integrated Circuit Interface ALAS5V provides an Inter-Integrated Circuit (I2C) interface. I2C is a serial, 8-bit oriented data transfer bus for bit rates up to 400kbps in Fast mode. It consists of two lines, the serial data line I2CDAT and the serial clock line I2CCLK. The module acts as a single master device, e.g. the clock I2CCLK is driven by the module. I2CDAT is a bi-directional line.
Cinterion® ALAS5V Hardware Interface Description Page 34 of 124 2.1 Application Interface 67 2.1.7 UICC/SIM/USIM Interface ALAS5V has two UICC/SIM/USIM interfaces compatible with the 3GPP 31.102 and ETSI 102 221. These are wired to the host interface in order to be connected to an external SIM card holder. Five pads on the SMT application interface are reserved for each of the two SIM interfaces. The UICC/SIM/USIM interface supports 2.85V and 1.8V SIM cards.
Cinterion® ALAS5V Hardware Interface Description Page 35 of 124 2.1 Application Interface 67 open: Card removed closed: Card inserted SMT application interface CCIN1 Module CCRST1 SIM / UICC 1n CCCLK1 GND CCIO1 CCVCC1 220n Figure 9: First UICC/SIM/USIM interface The total cable length between the SMT application interface pads on ALAS5V and the pads of the external SIM card holder must not exceed 100mm in order to meet the specifications of 3GPP TS 51.
Cinterion® ALAS5V Hardware Interface Description Page 36 of 124 2.1 Application Interface 67 2.1.8 Enhanced ESD Protection for SIM Interfaces To optimize ESD protection for the SIM interfaces it is possible to add ESD diodes to the interface lines of the first and second SIM interface as shown in the example given in Figure 11. The example was designed to meet ESD protection according ETSI EN 301 489-1/7: Contact discharge: ± 4kV, air discharge: ± 8kV.
Cinterion® ALAS5V Hardware Interface Description Page 37 of 124 2.1 Application Interface 67 2.1.9 Digital Audio Interface ALAS5V has two digital audio interfaces (DAIs) that can be employed as inter pulse code modulation (PCM) or Inter-IC Sound (I2S) interface. Default setting is pulse code modulation. Please note that the first DAI is reserved for future use. 2.1.9.1 Pulse Code Modulation Interface (PCM) ALAS5V's PCM interface can be used to connect audio devices capable of pulse code modulation.
Cinterion® ALAS5V Hardware Interface Description Page 38 of 124 2.1 Application Interface 67 2.1.9.2 Inter-IC Sound Interface The Inter-IC Sound Interface is a standardized bidirectional I2S based digital audio interface for transmission of mono voice signals for telephony services. An activation of the I2S line is possible only out of call and out of tone presentation.
Cinterion® ALAS5V Hardware Interface Description Page 39 of 124 2.1 Application Interface 67 2.1.10 Analog-to-Digital Converter (ADC) ALAS5V provides four unbalanced ADC input lines: ADC[1-2...4-5]_IN. They can be used to measure four independent, externally connected DC voltages in the range of 0.1V to 1.7V. As described in Section 2.2.4 and Section 5.2 they can be used especially for antenna diagnosing.
Cinterion® ALAS5V Hardware Interface Description Page 40 of 124 2.1 Application Interface 67 2.1.13 2.1.13.1 Control Signals PWR_IND Signal PWR_IND notifies the on/off state of the module. High state of PWR_IND indicates that the module is switched off. The state of PWR_IND immediately changes to low when IGT is pulled low. For state detection an external pull-up resistor is required.
Cinterion® ALAS5V Hardware Interface Description Page 41 of 124 2.1 Application Interface 67 2.1.13.2 Remote Wakeup If no call, data or message transfer is in progress, the external host application may shut down its own module interfaces or other components in order to save power. If a call, data, or other request (URC) arrives, the external application can be notified of this event and be woken up again by a state transition of a configurable remote wakeup line.
Cinterion® ALAS5V Hardware Interface Description Page 42 of 124 2.1 Application Interface 67 2.1.15 eMMC Interface ALAS5V has an eMMC interface that can be used for development and test purposes, e.g., to write crash dumps from the module’s FFS to eMMC. To connect an eMMC a separate, additional power supply is required as described in Section 2.1.15.1. 2.1.15.1 eMMC Power Supply An eMMC requires two separate power supplies normally named VCC (3V3) and VCCQ (3V3 / 1V8).
Cinterion® ALAS5V Hardware Interface Description Page 43 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 2.2 GSM/UMTS/LTE Antenna Interface The ALAS5V GSM/UMTS/LTE antenna interface comprises a GSM/UMTS/LTEmain antenna as well as a UMTS/LTE Rx diversity/MIMO antenna to improve signal reliability and quality1. The interface has an impedance of 50. ALAS5V is capable of sustaining a total mismatch at the antenna interface without any damage, even when transmitting at maximum RF power.
Cinterion® ALAS5V Hardware Interface Description Page 44 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 2.2.1 Antenna Interface Specifications Table 13: RF Antenna interface GSM/UMTS/LTE (at operating temperature range1) Parameter Conditions LTE connectivity Band 1, 2, 3, 4, 5, 7, 8, 12, 18, 19, 20, 26, 28, 38, 39, 40, 41, 66 Receiver Input Sensitivity @ LTE 2100 Band 1 ARP (ch.
Cinterion® ALAS5V Hardware Interface Description Page 45 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 Table 13: RF Antenna interface GSM/UMTS/LTE (at operating temperature range1) Parameter Conditions Min. Typical Max.
Cinterion® ALAS5V Hardware Interface Description Page 46 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 Table 13: RF Antenna interface GSM/UMTS/LTE (at operating temperature range1) Parameter RF Power @ ARP with 50 Load (ROPR=4, i.e., no reduction) Conditions GPRS, 1 TX EDGE, 1 TX GPRS, 2 TX EDGE, 2 TX GPRS, 3 TX EDGE, 3 TX GPRS, 4 TX EDGE, 4 TX RF Power @ ARP with 50 Load (ROPR=5) GPRS, 1 TX EDGE, 1 TX GPRS, 2 TX EDGE, 2 TX GPRS, 3 TX EDGE, 3 TX GPRS, 4 TX EDGE, 4 TX Min.
Cinterion® ALAS5V Hardware Interface Description Page 47 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 Table 13: RF Antenna interface GSM/UMTS/LTE (at operating temperature range1) Parameter RF Power @ ARP with 50 Load (ROPR=6) Conditions GPRS, 1 TX EDGE, 1 TX GPRS, 2 TX EDGE, 2 TX GPRS, 3 TX EDGE, 3 TX GPRS, 4 TX EDGE, 4 TX RF Power @ ARP with 50 Load (ROPR=7) GPRS, 1 TX EDGE, 1 TX GPRS, 2 TX EDGE, 2 TX GPRS, 3 TX EDGE, 3 TX GPRS, 4 TX EDGE, 4 TX Min. Typical Max.
Cinterion® ALAS5V Hardware Interface Description Page 48 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 Table 13: RF Antenna interface GSM/UMTS/LTE (at operating temperature range1) Parameter RF Power @ ARP with 50 Load (ROPR=8, i.e., max. reduction) Conditions GPRS, 1 TX EDGE, 1 TX GPRS, 2 TX EDGE, 2 TX GPRS, 3 TX EDGE, 3 TX GPRS, 4 TX EDGE, 4 TX Min. Typical Max.
Cinterion® ALAS5V Hardware Interface Description Page 49 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 2.2.2 Antenna Installation The antennas are connected by soldering the antenna pads (ANT_MAIN, ANT_DRX_MIMO, ANT_GNSS) and their neighboring ground pads directly to the application’s PCB.
Cinterion® ALAS5V Hardware Interface Description Page 50 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 2.2.3 2.2.3.1 RF Line Routing Design Line Arrangement Instructions Several dedicated tools are available to calculate line arrangements for specific applications and PCB materials - for example from http://www.polarinstruments.com/ (commercial software) or from http://web.awrcorp.com/Usa/Products/Optional-Products/TX-Line/ (free software).
Cinterion® ALAS5V Hardware Interface Description Page 51 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 Micro-Stripline This section gives two line arrangement examples for micro-stripline. Figure 18: Micro-Stripline line arrangement samples ALAS5V_HID_v00.
Cinterion® ALAS5V Hardware Interface Description Page 52 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 2.2.3.2 Routing Examples Interface to RF Connector Figure 19 shows a sample connection of a module‘s antenna pad at the bottom layer of the module PCB with an application PCB‘s coaxial antenna connector. Line impedance depends on line width, but also on other PCB characteristics like dielectric, height and layer gap. The sample stripline width of 0.
Cinterion® ALAS5V Hardware Interface Description Page 53 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 2.2.4 RF Antenna Diagnostic RF antenna (GSM/UMTS/LTE) diagnosis requires the implementation of an external antenna detection circuit. An example for such a circuit is illustrated in Figure 21. It allows to check the presence and the connection status of RF antennas. To properly detect the antenna and verify its connection status the antenna feed point must have a DC resistance RANT of 9k (±3k).
Cinterion® ALAS5V Hardware Interface Description Page 54 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 Figure 21 shows the basic principles of an antenna detection circuit that is able to detect antennas and verify their connection status. The GPIO pads can be employed to enable the antenna detection, the ADCx_IN pads can be used to measure the voltage of external devices connected to these ADC input pads - thus determining RANT values.
Cinterion® ALAS5V Hardware Interface Description Page 55 of 124 2.2 GSM/UMTS/LTE Antenna Interface 67 Table 15 lists assured antenna diagnostic states depending on the measured RANT values. Note that the RANT ranges not mentioned in the below table, i.e., 1k...6k and 12k...40k are tolerance ranges. Within these tolerance ranges a decision threshold for a diagnostic application may be located. For more details on the sample antenna detection circuit please refer to Section 2.3.1.
Cinterion® ALAS5V Hardware Interface Description Page 56 of 124 2.3 GNSS Antenna Interface 67 2.3 GNSS Antenna Interface In addition to the RF antenna interface ALAS5V also has a GNSS antenna interface. See Section 2.1.1 to find out where the GNSS antenna pad is located. The GNSS pad’s shape is the same as for the RF antenna interface (see Section 2.2.2). It is possible to connect active or passive GNSS antennas. In either case they must have 50 impedance.
Cinterion® ALAS5V Hardware Interface Description Page 57 of 124 2.3 GNSS Antenna Interface 67 Figure 23 shows a sample circuit realizing ESD protection for a passive GNSS antenna. Connecting the input ANT_GNSS_DC to GND prevents ESD from coupling into the module. Module SMT interface GNSS _EN 100nF Not used ANT_GNSS _DC Passive GNSS antenna (Optional) 0R ESD protection 10nH ANT_GNSS To GNSS receiver Figure 23: ESD protection for passive GNSS antenna 2.3.
Cinterion® ALAS5V Hardware Interface Description Page 58 of 124 2.4 Sample Application 67 2.4 Sample Application Figure 24 shows a typical example of how to integrate an ALAS5V module with an application. The PWR_IND line is an open collector that needs an external pull-up resistor which connects to the voltage supply VCC µC of the microcontroller. Low state of the open collector pulls the PWR_IND signal low and indicates that the ALAS5V module is active, high level notifies the Power Down mode.
Cinterion® ALAS5V Hardware Interface Description Page 59 of 124 2.4 Sample Application 67 Main antenna (GSM/UMTS/LTE) IGT GND ANT_MAIN 47k Diversity antenna (LTE) GND GND EMERG _OFF ANT_DRX_MIMO GND 47k 100k VCC µC 47µF Ultra low ESR PWR_IND BATT+ 2 Rechargeable Lithium battery BATT+_RF 2 + VDD (1.8V) VEXT (1.8V) NTC VCC µC Module OE V CCA 4 VCCB Level Controller PCM interface lines USB 2.0 HS Mode Or USB 3.0 SS Mode 4 2 4 4 x 47µF Ultra low ESR PCM2_...
Cinterion® ALAS5V Hardware Interface Description Page 60 of 124 2.4 Sample Application 67 2.4.1 Prevent Back Powering Because of the very low power consumption design, current flowing from any other source into the module circuit must be avoided in any case, for example reverse current from high state external control lines while the module is powered down. Therefore, the external application must be designed to prevent reverse current flow.
Cinterion® ALAS5V Hardware Interface Description Page 61 of 124 2.4 Sample Application 67 2.4.2 Sample Level Conversion Circuit Depending on the micro controller used by an external application ALAS5V‘s digital input and output lines (i.e., ASC0 lines) may require level conversion. The following Figure 25 shows sample circuits with recommended level shifters for an external application‘s micro controller (with VLOGIC between 3.0V...3.6V).
Cinterion® ALAS5V Hardware Interface Description Page 62 of 124 2.4 Sample Application 67 2.4.3 Sample Circuit for Antenna Detection The following figures explain how an RF antenna detection circuit may be implemented for ALAS5V to be able to detect connected antennas (for basic circuit and diagnostic principles including usage of GPIO and ADCx_IN pads - please refer to Section 2.2.4).
Cinterion® ALAS5V Hardware Interface Description Page 63 of 124 ANT2 ANT1 2.
Cinterion® ALAS5V Hardware Interface Description Page 64 of 124 2.4 Sample Application 67 Table 18: Antenna detection reference circuit - parts list Reference Part Value R1,2 Resistor 22R R3,4 Resistor 10k R5,6 Resistor 140k 1% R7,8 Resistor 100k 1% R9,10 Resistor 100k R11,12 Resistor 10k > 125mW R13,14 Resistor 4k4 1% (e.g.
Cinterion® ALAS5V Hardware Interface Description Page 65 of 124 3 GNSS Interface 67 3 GNSS Interface ALAS5V integrates a GNSS receiver that offers the full performance of GPS/GLONASS technology. The GNSS receiver is able to continuously track all satellites in view, thus providing accurate satellite position data. The integrated GNSS receiver supports the NMEA protocol via USB or ASC0 interface.
Cinterion® ALAS5V Hardware Interface Description Page 66 of 124 3.1 GNSS Interface Characteristics 67 3.1 GNSS Interface Characteristics The following tables list general characteristics of the GNSS interface. Table 19: GNSS properties Parameter Conditions Min. Typical Max. Unit Frequency GPS 1575 1575.42 1585 MHz 1597 1602 1607 -- -- -- 1597 1575.
Cinterion® ALAS5V Hardware Interface Description Page 67 of 124 3.1 GNSS Interface Characteristics 67 Through the external GNSS antenna DC feeding the module is able to supply an active GNSS antenna. The supply voltage level at the GNSS antenna interface depends on the GNSS configuration.
Cinterion® ALAS5V Hardware Interface Description Page 68 of 124 4 Operating Characteristics 96 4 Operating Characteristics 4.1 Operating Modes The table below briefly summarizes the various operating modes referred to throughout the document. Table 21: Overview of operating modes Mode Function Normal GSM / GPRS / operation UMTS / HSPA / LTE SLEEP Power saving set automatically when no call is in progress and the USB connection is detached and no active communication via ASC0.
Cinterion® ALAS5V Hardware Interface Description Page 69 of 124 4.2 Power Up/Power Down Scenarios 96 4.2 Power Up/Power Down Scenarios In general, be sure not to turn on ALAS5V while it is beyond the safety limits of voltage and temperature stated in Section 6.1. ALAS5V immediately switches off after having started and detected these inappropriate conditions. In extreme cases this can cause permanent damage to the module. 4.2.
Cinterion® ALAS5V Hardware Interface Description Page 70 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.2 Signal States after First Startup Table 22 describes the various states each interface signal passes through after startup and during operation. Signals are in an initial state while the module is initializing. Once the startup initialization has completed, i.e. when the software is running, all signals are in defined state.
Cinterion® ALAS5V Hardware Interface Description Page 71 of 124 4.2 Power Up/Power Down Scenarios 96 Table 22: Signal states Signal name Pad no.
Cinterion® ALAS5V Hardware Interface Description Page 72 of 124 4.2 Power Up/Power Down Scenarios 96 Table 22: Signal states Signal name Pad no.
Cinterion® ALAS5V Hardware Interface Description Page 73 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.3 Turn off or Restart ALAS5V To switch off or restart the module the following procedures may be used: • Software controlled shutdown procedure: Software controlledby sending an AT command over the serial application interface. See Section 4.2.3.1. • Software controlled restart procedure: Software controlled by sending an AT commandover the serial application interface. See Section 4.2.3.2.
Cinterion® ALAS5V Hardware Interface Description Page 74 of 124 4.2 Power Up/Power Down Scenarios 96 Start shutdown approx. 20s Deregister from network, system shut down PWR_IND Digital outputs VEXT Inputs driven by application BATT + driven by application Figure 29: Signal states during turn-off procedure Note 1: Note 2: 4.2.3.2 VEXT can be used in solutions to prevent back powering (see also Section 2.4.1). It should have a level lower than 0.3V after module shutdown.
Cinterion® ALAS5V Hardware Interface Description Page 75 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.3.3 Turn off ALAS5V Using IGT Line The IGT line can be configured for use in two different switching modes: You can set the IGT line to switch on the module only, or to switch it on and off. The switching mode is determined by the parameter "MEShutdown/OnIgnition" of the AT^SCFG command.
Cinterion® ALAS5V Hardware Interface Description Page 76 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.3.4 Turn off or Restart ALAS5V in Case of Emergency Caution: Use the EMERG_OFF line only when, due to serious problems, the software is not responding for more than 5 seconds. Pulling the EMERG_OFF line causes the loss of all information stored in the volatile memory. Therefore, this procedure is intended only for use in case of emergency, e.g.
Cinterion® ALAS5V Hardware Interface Description Page 77 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.3.5 Overall Shutdown Sequence In case the above described dedicated software or hardware controlled shutdown procedures fail or hang for some reason, it may become necessary to disconnect BATT+ in order to ultimately shut down the module. Figure 33 shows a flow chart that illustrates how an overall shutdown sequence might be implemented. Module switch off...
Cinterion® ALAS5V Hardware Interface Description Page 78 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.4 Automatic Shutdown Automatic shutdown takes effect if: • The ALAS5V board is exceeding the critical limits of overtemperature or undertemperature • Undervoltage or overvoltage is detected The automatic shutdown procedure is equivalent to the power down initiated with the AT^SMSO command, i.e. ALAS5V logs off from the network and the software enters a secure state avoiding loss of data.
Cinterion® ALAS5V Hardware Interface Description Page 79 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.4.1 Thermal Shutdown The board temperature is constantly monitored by an internal NTC resistor located on the PCB. The values detected by the NTC resistor are measured directly on the board and therefore, are not fully identical with the ambient temperature. Each time the board temperature goes out of range or back to normal, ALAS5V instantly displays an alert (if enabled).
Cinterion® ALAS5V Hardware Interface Description Page 80 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.4.2 Deferred Shutdown at Extreme Temperature Conditions In the following cases, automatic shutdown will be deferred if a critical temperature limit is exceeded: • While an emergency call is in progress. • During a two minute guard period after power-up. This guard period has been introduced in order to allow for the user to make an emergency call.
Cinterion® ALAS5V Hardware Interface Description Page 81 of 124 4.2 Power Up/Power Down Scenarios 96 4.2.4.3 Undervoltage Shutdown If the measured battery voltage is no more sufficient to set up a call the following URC will be presented: ^SBC: Undervoltage. The URC indicates that the module is close to the undervoltage threshold. If undervoltage persists the module keeps sending the URC several times before switching off automatically. This type of URC does not need to be activated by the user.
Cinterion® ALAS5V Hardware Interface Description Page 82 of 124 4.3 Power Saving 96 4.3 Power Saving ALAS5V is able to reduce its functionality to a minimum (during the so-called SLEEP mode) in order to minimize its current consumption. The following sections explain the module’s network dependent power saving behavior. The power saving behavior is further configurable by AT command: • AT^SCFG= "MEopMode/PwrSave": The power save mode is by default enabled.
Cinterion® ALAS5V Hardware Interface Description Page 83 of 124 4.3 Power Saving 96 Now, a paging timing cycle consists of the actual fixed length paging plus a variable length pause before the next paging. In the pauses between listening to paging messages, the module resumes power saving, as shown in Figure 34. Figure 34: Power saving and paging in GSM networks The varying pauses explain the different potential for power saving. The longer the pause the less power is consumed.
Cinterion® ALAS5V Hardware Interface Description Page 84 of 124 4.3 Power Saving 96 4.3.2 Power Saving while Attached to WCDMA Networks The power saving possibilities while attached to a WCDMA network depend on the paging timing cycle of the base station. During normal WCDMA operation, i.e., the module is connected to a WCDMA network, the duration of a paging timing cycle varies. It may be calculated using the following formula: t = 2DRX value * 10 ms (WCDMA frame duration).
Cinterion® ALAS5V Hardware Interface Description Page 85 of 124 4.3 Power Saving 96 4.3.3 Power Saving while Attached to LTE Networks The power saving possibilities while attached to an LTE network depend on the paging timing cycle of the base station. During normal LTE operation, i.e., the module is connected to an LTE network, the duration of a paging timing cycle varies.
Cinterion® ALAS5V Hardware Interface Description Page 86 of 124 4.4 Power Supply 96 4.4 Power Supply ALAS5V needs to be connected to a power supply at the SMT application interface - 4 lines BATT+, and GND. There are two separate voltage domains for BATT+: • BATT+_RF with 2 lines for the RF power amplifier supply • BATT+ with 2 lines for the general power management.
Cinterion® ALAS5V Hardware Interface Description Page 87 of 124 4.4 Power Supply 96 4.4.1 Power Supply Ratings Table 24 and Table 25 assemble various voltage supply and current consumption ratings for the supported modules. Possible ratings are preliminary and will have to be confirmed. Table 24: Voltage supply ratings Description BATT+ Supply voltage Conditions Directly measured at Module. 3.
Cinterion® ALAS5V Hardware Interface Description Page 88 of 124 4.4 Power Supply 96 Table 25: Current consumption ratings IBATT+ 1 Description Conditions OFF State supply current Power Down Typical rating RTC off USB disconnected 30 USB connected 60 USB disconnected 90 USB connected 120 SLEEP @ DRX=9 (no communication with the module) USB disconnected 1.7 USB suspend 13.2 SLEEP2 @ DRX=5 (no communication with the module) USB disconnected 1.9 USB suspend 13.
Cinterion® ALAS5V Hardware Interface Description Page 89 of 124 4.4 Power Supply 96 Table 25: Current consumption ratings IBATT+ 1 Description Conditions Average GSM supply current EDGE Data transfer GSM850/900; PCL=5; 1Tx/4Rx ROPR=8 (max. reduction) EDGE Data transfer GSM850/900; PCL=5; 2Tx/3Rx Peak current during GSM transmit burst IBATT+ 1 Average GSM supply current (GNSS on) Typical rating Unit 220 mA ROPR=8 (max.
Cinterion® ALAS5V Hardware Interface Description Page 90 of 124 4.4 Power Supply 96 Table 25: Current consumption ratings Description IBATT+ IBATT+ 1 1 Average UMTS supply current Conditions 2 Typical rating Unit mA SLEEP @ DRX=9 (no communication with the module) USB disconnected 1.6 USB suspend 13.1 SLEEP2 @ DRX=8 Voice calls and (no communication with Data transfers the module) measured 2 @ maximum Pout SLEEP @ DRX=6 (no communication with the module) USB disconnected 1.
Cinterion® ALAS5V Hardware Interface Description Page 91 of 124 4.4 Power Supply 96 Table 25: Current consumption ratings Description IBATT+ 1 Conditions 2 Average LTE sup- SLEEP @ "Paging ply current (FDD)5 Occasions" = 256 2 SLEEP @ "Paging Data transfers Occasions" = 128 measured @ maximum Pout SLEEP2 @ "Paging Occasions" = 64 2 SLEEP @ "Paging Occasions" = 32 Typical rating Unit USB disconnected 1.9 mA USB suspend 13.5 USB disconnected 2.3 USB suspend 13.9 USB disconnected 2.
Cinterion® ALAS5V Hardware Interface Description Page 92 of 124 4.4 Power Supply 96 Table 25: Current consumption ratings Description IBATT+ 1 Conditions 2 Average LTE sup- SLEEP @ "Paging ply current (TDD)5 Occasions" = 256 2 SLEEP @ "Paging Data transfers Occasions" = 128 measured @ maximum Pout SLEEP2 @ "Paging Occasions" = 64 2 SLEEP @ "Paging Occasions" = 32 Typical rating Unit USB disconnected 1.9 mA USB suspend 13.5 USB disconnected 2.3 USB suspend 13.9 USB disconnected 2.
Cinterion® ALAS5V Hardware Interface Description Page 93 of 124 4.4 Power Supply 96 Table 25: Current consumption ratings Description IBATT+ 1 Average TDSCDMA supply current (GNSS off) Conditions 2 Average TDSCDMA supply current (GNSS on) mA USB disconnected 1.6 USB suspend 13.1 SLEEP2 @ DRX=8 (no communication with the module) USB disconnected 1.8 USB suspend 13.3 USB disconnected 2.3 USB suspend 13.
Cinterion® ALAS5V Hardware Interface Description Page 94 of 124 4.4 Power Supply 96 4.4.2 Minimizing Power Losses When designing the power supply for your application please pay specific attention to power losses. Ensure that the input voltage VBATT+ never drops below 3.3V on the ALAS5V board, not even in a transmit burst where current consumption can rise to typical peaks of 2A. It should be noted that ALAS5V switches off when exceeding these limits.
Cinterion® ALAS5V Hardware Interface Description Page 95 of 124 4.5 Operating Temperatures 96 4.5 Operating Temperatures Table 26: Board temperature Parameter Min Typ Max Unit Operating temperature range -30 +25 +85 °C Restricted temperature range1 -40 +95 °C >+95 °C 2 Automatic shutdown Temperature measured on ALAS5V board <-40 --- 1. Restricted operation allows normal mode data transmissions for limited time until automatic thermal shutdown takes effect.
Cinterion® ALAS5V Hardware Interface Description Page 96 of 124 4.6 Electrostatic Discharge 96 4.6 Electrostatic Discharge The module is not protected against Electrostatic Discharge (ESD) in general. Consequently, it is subject to ESD handling precautions that typically apply to ESD sensitive components. Proper ESD handling and packaging procedures must be applied throughout the processing, handling and operation of any application that incorporates a ALAS5V module.
Cinterion® ALAS5V Hardware Interface Description Page 97 of 124 5 Mechanical Dimensions and Mounting 107 5 Mechanical Dimensions and Mounting 5.1 Mechanical Dimensions of ALAS5V Figure 40 shows a 3D view1 of ALAS5V and provides an overview of the board's mechanical dimensions2. For further details see Figure 41. Length: 40mm Width: 36mm Height: 3mm Top view Bottom view Figure 40: ALAS5V – top and bottom view 1. The coloring of the 3D view does not reflect the module’s real color. 2.
Cinterion® ALAS5V Hardware Interface Description Page 98 of 124 [ [ 5.1 Mechanical Dimensions of ALAS5V 107 5 3 1 0 / . 7 + [ [ * ) ( ' & % $ ERWWRP YLHZ WRS YLHZ QR VROGHU SDGV NHHS DUHD IUHH Figure 41: Dimensions of ALAS5V (all dimensions in mm) ALAS5V_HID_v00.
Cinterion® ALAS5V Hardware Interface Description Page 99 of 124 5.2 Mounting ALAS5V onto the Application Platform 107 5.2 Mounting ALAS5V onto the Application Platform This section describes how to mount ALAS5V onto the PCBs, including land pattern and stencil design, board-level characterization, soldering conditions, durability and mechanical handling. For more information on issues related to SMT module integration see also [3].
Cinterion® ALAS5V Hardware Interface Description Page 100 of 124 5.2 Mounting ALAS5V onto the Application Platform 107 The stencil design illustrated in Figure 43 is recommended by Gemalto M2M as a result of extensive tests with Gemalto M2M Daisy Chain modules.
Cinterion® ALAS5V Hardware Interface Description Page 101 of 124 5.2 Mounting ALAS5V onto the Application Platform 107 5.2.2 Moisture Sensitivity Level ALAS5V comprises components that are susceptible to damage induced by absorbed moisture. Gemalto M2M’s ALAS5V module complies with the latest revision of the IPC/JEDEC J-STD020 Standard for moisture sensitive surface mount devices and is classified as MSL 4. For additional moisture sensitivity level (MSL) related information see Section 5.2.4. 5.2.3 5.
Cinterion® ALAS5V Hardware Interface Description Page 102 of 124 5.2 Mounting ALAS5V onto the Application Platform 107 Table 28: Reflow temperature recommendations1 Profile Feature Pb-Free Assembly Preheat & Soak Temperature Minimum (TSmin) Temperature Maximum (TSmax) Time (tSmin to tSmax) (tS) 150°C 200°C 60-120 seconds Average ramp up rate (TL to TP) 3K/second max.
Cinterion® ALAS5V Hardware Interface Description Page 103 of 124 5.2 Mounting ALAS5V onto the Application Platform 107 5.2.4 Durability and Mechanical Handling 5.2.4.1 Storage Conditions ALAS5V modules, as delivered in tape and reel carriers, must be stored in sealed, moisture barrier anti-static bags. The conditions stated below are only valid for modules in their original packed state in weather protected, non-temperature-controlled storage locations.
Cinterion® ALAS5V Hardware Interface Description Page 104 of 124 5.2 Mounting ALAS5V onto the Application Platform 107 5.2.4.3 Baking Baking conditions are specified on the moisture sensitivity label attached to each MBB: • It is not necessary to bake ALAS5V, if the conditions specified in Section 5.2.4.1 and Section 5.2.4.2 were not exceeded. • It is necessary to bake ALAS5V, if any condition specified in Section 5.2.4.1 and Section 5.2.4.2 was exceeded.
Cinterion® ALAS5V Hardware Interface Description Page 105 of 124 5.3 Packaging 107 5.3 Packaging 5.3.1 Trays ALAS5V is shipped in 6x3 trays as illustrated in Figure 45. The figure also shows the proper module orientation in the trays: The small round hole marking pad A1 is furthest away from the beveled corner of the tray. Figure 45: Shipping tray dimensions 5.3.
Cinterion® ALAS5V Hardware Interface Description Page 106 of 124 5.3 Packaging 107 Figure 46: Moisture Sensitivity Label ALAS5V_HID_v00.
Cinterion® ALAS5V Hardware Interface Description Page 107 of 124 5.3 Packaging 107 MBBs contains two desiccant pouches to absorb moisture that may be in the bag. The humidity indicator card described below should be used to determine whether the enclosed components have absorbed an excessive amount of moisture. The desiccant pouches should not be baked or reused once removed from the MBB.
Cinterion® ALAS5V Hardware Interface Description Page 108 of 124 6 Regulatory and Type Approval Information 115 6 Regulatory and Type Approval Information 6.1 Directives and Standards ALAS5V has been designed to comply with the directives and standards listed below.
Cinterion® ALAS5V Hardware Interface Description Page 109 of 124 6.1 Directives and Standards 115 Table 32: Standards of European type approval 3GPP TS 51.010-1 Digital cellular telecommunications system (Release 7); Mobile Station (MS) conformance specification; ETSI EN 301 511 V12.5.1 Global System for Mobile communications (GSM); Mobile Stations (MS) equipment; Harmonized Standard covering the essential requirements of article 3.2 of Directive 2014/53/EU GCF-CC V3.
Cinterion® ALAS5V Hardware Interface Description Page 110 of 124 6.1 Directives and Standards 115 Table 34: Standards of the Ministry of Information Industry of the People’s Republic of China SJ/T 11363-2006 “Requirements for Concentration Limits for Certain Hazardous Substances in Electronic Information Products” (2006-06). SJ/T 11364-2006 “Marking for Control of Pollution Caused by Electronic Information Products” (2006-06).
Cinterion® ALAS5V Hardware Interface Description Page 111 of 124 6.2 SAR requirements specific to portable mobiles 115 6.2 SAR requirements specific to portable mobiles Mobile phones, PDAs or other portable transmitters and receivers incorporating a GSM module must be in accordance with the guidelines for human exposure to radio frequency energy.
Cinterion® ALAS5V Hardware Interface Description Page 112 of 124 6.3 Reference Equipment for Type Approval 115 6.3 Reference Equipment for Type Approval The Gemalto M2M general reference setup submitted to type approve ALAS5V is shown in the figure below: Figure 48 illustrates the setup for general tests and evaluation purposes. The evaluation module can be plugged directly onto the so-called “Audio(-Ethernet) Adapter”.
Cinterion® ALAS5V Hardware Interface Description Page 113 of 124 6.4 Compliance with FCC and ISED Rules and Regulations 115 6.4 Compliance with FCC and ISED Rules and Regulations The Equipment Authorization Certification for the Gemalto M2M modules reference application described in Section 6.
Cinterion® ALAS5V Hardware Interface Description Page 114 of 124 6.4 Compliance with FCC and ISED Rules and Regulations 115 Table 37: Antenna gain limits for FCC and ISED for ALAS5V-US (TBD.
Cinterion® ALAS5V Hardware Interface Description Page 115 of 124 6.4 Compliance with FCC and ISED Rules and Regulations 115 If Canadian approval is requested for devices incorporating ALAS5V modules the above note will have to be provided in the English and French language in the final user documentation. Manufacturers/OEM Integrators must ensure that the final user documentation does not contain any information on how to install or remove the module from the final product.
Cinterion® ALAS5V Hardware Interface Description Page 116 of 124 7 Document Information 121 7 Document Information 7.1 Revision History Preceding document: "Cinterion® ALAS5V Hardware Interface Description" v00.030 New document: "Cinterion® ALAS5V Hardware Interface Description" v00.030a Chapter What is new Throughout document Defined GPIO6 as interrupt enabled. 1.2 Added TD-SCDMA to Table 1, removed “Uplink CA” from Table 2. 1.3 Revised Figure 1. 2.1.
Cinterion® ALAS5V Hardware Interface Description Page 117 of 124 7.1 Revision History 121 Preceding document: "Cinterion® ALAS5V Hardware Interface Description" v00.014 New document: "Cinterion® ALAS5V Hardware Interface Description" v00.018 Chapter What is new Throughout document Added ASC2 (RXD2/TXD2 lines) serial interface as debug interface including test point recommendation. Removed support for LTE-TDD Band 41 (for ALAS5V-W). Removed support for second I2C interface (I2CDAT2, I2CCLK2). 2.1.
Cinterion® ALAS5V Hardware Interface Description Page 118 of 124 7.2 Related Documents 121 7.2 [1] [2] [3] [4] [5] Related Documents ALAS5V AT Command Set ALAS5V Release Note Application Note 48: SMT Module Integration Universal Serial Bus Specification Revision 3.0 Universal Serial Bus Specification Revision 2.0 7.
Cinterion® ALAS5V Hardware Interface Description Page 119 of 124 7.
Cinterion® ALAS5V Hardware Interface Description Page 120 of 124 7.
Cinterion® ALAS5V Hardware Interface Description Page 121 of 124 7.4 Safety Precaution Notes 121 7.4 Safety Precaution Notes The following safety precautions must be observed during all phases of the operation, usage, service or repair of any cellular terminal or mobile incorporating ALAS5V. Manufacturers of the cellular terminal are advised to convey the following safety information to users and operating personnel and to incorporate these guidelines into all manuals supplied with the product.
Cinterion® ALAS5V Hardware Interface Description Page 122 of 124 8 Appendix 123 8 Appendix 8.
Cinterion® ALAS5V Hardware Interface Description Page 123 of 124 8.1 List of Parts and Accessories 123 Table 39: Molex sales contacts (subject to change) Molex For further information please click: http://www.molex.com Molex Deutschland GmbH Otto-Hahn-Str. 1b 69190 Walldorf Germany Phone: +49-6227-3091-0 Fax: +49-6227-3091-8100 Email: mxgermany@molex.com American Headquarters Lisle, Illinois 60532 U.S.A.
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