Telit Communications S p A GM862L Quad-Band GSM/GPRS module User Manual GM862 QUAD PY Hardware User Guide

Telit Communications S.p.A. Quad-Band GSM/GPRS module GM862 QUAD PY Hardware User Guide

Users Manual

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GM862-QUAD / PY Hardware User
Guide
GM862-QUAD-PY, GM862-QUAD HW User Guide
1vv0300748 Rev. 1 - 24/10/06
GM862-QUAD / PY Hardware User Guide
1vv0300748 Rev. 1 - 24/10/06
Contents
Overview ...........................................................................................................................6
Interface connectors on GM862-QUAD / PY ..................................................................7
2.1
Description..............................................................................................................................7
2.2
Connectors Position ..............................................................................................................7
2.3
Board to Board Connector ....................................................................................................8
2.3.1
Molex 52991-0508 (male) GM862 Connector PIN-OUT ..................................................................9
2.3.2
Antenna Connector........................................................................................................................ 11
2.4
Dimensions ...........................................................................................................................12
2.5
Mounting the GM862 Modules on your Board ...................................................................13
2.5.1
2.5.2
Hardware Commands ....................................................................................................16
3.1
Turning ON the GM862-QUAD / PY .....................................................................................16
3.2
Turning OFF the GM862-QUAD / PY ...................................................................................18
3.2.1
3.2.2
Antenna Coaxial Cable Fixing ....................................................................................................... 13
Precautions .................................................................................................................................... 15
Hardware Shutdown ...................................................................................................................... 18
Hardware Unconditional Restart.................................................................................................... 19
Power Supply .................................................................................................................21
4.1
Power Supply Requirements ...............................................................................................21
4.2
General Design Rules ..........................................................................................................22
4.2.1
Electrical Design Guidelines .......................................................................................................... 22
4.2.1.1 + 5V input Source Power Supply Design Guidelines ................................................................ 22
4.2.1.2 + 12V input Source Power Supply Design Guidelines .............................................................. 24
4.2.1.3 Battery Source Power Supply Design Guidelines ..................................................................... 26
4.2.1.4 Battery Charge control Circuitry Design Guidelines .................................................................. 26
4.2.2
Thermal Design Guidelines ........................................................................................................... 29
4.2.3
Power Supply PCB layout Guidelines ........................................................................................... 30
Serial Ports .....................................................................................................................31
5.1
Level translation ...................................................................................................................33
5.2
5V UART level translation....................................................................................................35
Audio Section Overview ................................................................................................37
6.1
Microphone Paths Characteristic and Requirements .......................................................39
6.2
General Design Rules ..........................................................................................................42
6.3
Other Considerations...........................................................................................................42
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6.4
Microphone Biasing .............................................................................................................43
6.4.1
6.4.2
6.5
Microphone Buffering ..........................................................................................................46
6.5.1
6.5.2
Buffered Balanced Mic................................................................................................................... 46
Buffered Unbalanced (Single Ended) Microphone . ...................................................................... 48
OUTPUT LINES (Speaker)..............................................................................................51
7.1
Short Description. ................................................................................................................51
7.2
Output Lines Characteristics ..............................................................................................52
7.3
General Design Rules ..........................................................................................................53
7.3.1
Balanced Microphone Biasing ....................................................................................................... 43
Unbalanced Microphone Biasing................................................................................................... 44
Noise Filtering ................................................................................................................................ 53
7.4
Handset Earphone Design ...................................................................................................54
7.5
Hands-Free Earphone (Low Power) Design .......................................................................55
7.6
Car Kit Speakerphone Design .............................................................................................56
General Purpose I/O.......................................................................................................57
8.1
Logic level specifications ....................................................................................................57
8.2
Using a GPIO pin as INPUT .................................................................................................59
8.3
Using a GPIO pin as OUTPUT .............................................................................................59
8.4
Using the RFTXMON Output GPIO5....................................................................................59
8.5
Using the Alarm Output GPIO6 ...........................................................................................59
8.6
Using the Buzzer Output GPIO7..........................................................................................60
ADC section....................................................................................................................61
9.1
ADC converter ......................................................................................................................61
9.1.1
9.1.2
Description ..................................................................................................................................... 61
Using ADC Converter .................................................................................................................... 61
10 Camera ............................................................................................................................62
10.1
10.1.1
10.1.2
10.1.3
10.1.4
10.1.5
10.1.6
Camera Transchip.............................................................................................................62
Camera Interface Connectors........................................................................................................ 62
EVB for Camera Support ............................................................................................................... 63
EVB for Transchip camera support ............................................................................................... 65
Block Diagram for supported camera ............................................................................................ 66
Schematic Diagrams for supported cameras ................................................................................ 67
Example usage script for camera .................................................................................................. 68
11 Conformity Assessment Issues ....................................................................................69
12 Document Change Log ..................................................................................................70
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GM862-QUAD / PY Hardware User Guide
1vv0300748 Rev. 1 - 24/10/06
This document is relating to the following products:
GM862-QUAD
3 990 250 659
GM862-QUAD-PY 3 990 250 658
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GM862-QUAD / PY Hardware User Guide
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DISCLAIMER
The information contained in this document is proprietary information of Telit Communications S.p.A.
Telit Communications S.p.A. makes every effort to ensure the quality of the information it makes
available. Notwithstanding the foregoing, Telit Communications S.p.A. does not make any warranty as
to the information contained herein, and does not accept any liability for any injury, loss or damage of
any kind incurred by use of or reliance upon the information.
Telit Communications S.p.A. disclaims any and all responsibility for the application of the devices
characterized in this document, and notes that the application of the device must comply with the
safety standards of the applicable country, and where applicable, with the relevant wiring rules.
Telit Communications S.p.A. reserves the right to make modifications, additions and deletions to this
document at any time and without notice.
© 2006 Telit Communications S.p.A.
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GM862-QUAD / PY Hardware User Guide
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1 Overview
The aim of this document is the description of some hardware solutions useful for developing a product with the
Telit GM862-QUAD / PY 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 shall be considered as mandatory, while the
suggested hardware configurations shall not be considered mandatory, instead the information given shall be
used as a guide and a starting point for properly developing your product with the Telit GM862-QUAD / PY module.
For further hardware details that may not be explained in this document refer to the Telit GM862-QUAD / PY
Product Description document where all the hardware information is reported.
NOTICE
(EN) The integration of the GSM/GPRS GM862-QUAD / PY cellular module within user application shall
be done according to the design rules described in this manual.
(IT) L’integrazione del modulo cellulare GSM/GPRS GM862-QUAD / PY all’interno dell’applicazione
dell’utente dovrà rispettare le indicazioni progettuali descritte in questo manuale.
(DE) Die integration des GM862-QUAD / PY GSM/GPRS Mobilfunk-Moduls in ein Gerät muß gemäß der in
diesem Dokument beschriebenen Kunstruktionsregeln erfolgen
(SL) Integracija GSM/GPRS GM862-QUAD / PY modula v uporabniški aplikaciji bo morala upoštevati
projektna navodila, opisana v tem piročniku.
(SP) La utilización del modulo GSM/GPRS GM862-QUAD / PY debe ser conforme a los usos para los
cuales ha sido deseñado descritos en este manual del usuario.
(FR) L’intégration du module cellulaire GSM/GPRS GM862-QUAD / PY dans l’application de l’utilisateur
sera faite selon les règles de conception décrites dans ce manuel.
GM862-QUAD / PY
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, nor any infringement of patents or other rights of third parties
which may result from its use. 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.
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GM862-QUAD / PY Hardware User Guide
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2 Interface connectors on GM862-QUAD
/ PY
2.1 Description
The Telit GM862-QUAD / PY is provided of the following interfaces:
•
•
•
GSM antenna connector
Board To Board Interface connector
SIM Card Reader
The Telit GM862-QUAD / PY board to board connector is a CSTP 50 pin vertical SMD Molex 52991–0508
(male).
2.2 Connectors Position
49
50
Board to Board
Connector
GSM Antenna
Connector
SIM Card Holder
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2.3 Board to Board Connector
Molex 52991-0508 (male) GM862 Connector LAY-OUT
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2.3.1 Molex 52991-0508 (male) GM862 Connector PIN-OUT
I/O Function
Internal
Pull up
Pin
Signal
VBATT
Main power supply
Power
GND
Ground
Power
VBATT
Main power supply
Power
GND
Ground
Power
VBATT
Main power supply
Power
A/D
A/D converter @ 11 bit (Input Impedance >100Kohm)
VBATT
Main power supply
Power
CHARGE
AI
Battery Charger Input
Power
EAR_HF+
AO Handsfree ear output, phase +
Audio
10
EAR_MT-
AO Handset earphone signal output, phase -
Audio
11
EAR_HF-
AO Handsfree ear output, phase -
Audio
12
EAR_MT+
AO Handset earphone signal output, phase +
Audio
13
MIC_HF-
AI
Handsfree microphone input; phase -
Audio
14
MIC_MT+
AI
Handset microphone signal input; phase+
Audio
15
MIC_HF+
AI
Handsfree microphone input; phase +
Audio
16
MIC_MT-
AI
Handset microphone signal input; phase-
Audio
17
ON_OFF
Input command for switching power ON or OFF (toggle command).
47KΩ
Pull Up to
VBATT
18
AXE
Handsfree switching
100KΩ
CMOS 2.8V
19
SIMIO
20
C103/TXD
Serial data input (TXD) from DTE
21
PWRMON
Module Status ON indication (Signal output for power on/off control of external
devices
22
SIMVCC
External SIM signal – Power (3)
23
RESET
Reset input
24
SIMRST
External SIM signal – Reset
25
CAM_CLK
26
SIMCLK
27
SIMIN
28
GPO2 / JDR
29
C106/CTS
Output for Clear to send signal (CTS) to DTE
CMOS 2.8V
30
C125/RING
Output for Ring indicator signal (RI) to DTE
CMOS 2.8V
31
GPI1
General purpose input
32
GPIO8/CAM_O
Max 2V input
I/O External SIM signal - Data I/O
3V ONLY
CMOS 2.8V
1KΩ
CMOS 2.8V
3V ONLY
3V ONLY
I/O Camera Interface (4)
CMOS 2.8V
External SIM signal – Clock
I/O External SIM signal – Presence (active low)
General purpose output (Open Collector) / Jammer Detect Report
I/O Configurable general purpose I/O pin / Camera Interface (4)
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Type
3V ONLY
47KΩ
CMOS 2.8V
Open Collector
transistor base
CMOS 2.8V
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Pin
33
34
Signal
C107/DSR
Internal
Pull up
I/O Function
Output for Data set ready signal (DSR) to DTE
GPIO9/CAM_RS
I/O Configurable general purpose I/O pin / Camera Interface (4)
Type
CMOS 2.8V
CMOS 2.8V
35
TX_TRACE
RESERVED on GM862-QUAD, Python Debug on GM862-QUAD-PY (TX data)
CMOS 2.8V
36
C109/DCD
Output for Data carrier detect signal (DCD) to DTE
CMOS 2.8V
37
C104/RXD
Serial data output to DTE
CMOS 2.8V
38
GPIO10
39
STAT_LED
40
GPIO11
41
RX_TRACE
42
GPIO12
43
C108/DTR
44
GPIO13
45
C105/RTS
49
GPIO3 / CAM_
SCL
GPIO4 /
CAM_SDA
GPIO5 /
RFTXMON
GPIO6
/ ALARM
50
GPIO7
/ BUZZER
46
47
48
I/O Configurable general purpose I/O
Status indicator led
Open Collector
I/O Configurable general purpose I/O pin
RESERVED on GM862-QUAD, Python Debug on GM862-QUAD-PY (RX data)
I/O Configurable general purpose I/O pin
Input for Data terminal ready signal (DTR) from DTE (4)
I/O Configurable general purpose I/O pin
CMOS 2.8V
Input for Request to send signal (RTS) from DTE
Configurable general purpose I/O pin /
I/O
IIC Camera Interface (4)
Configurable general purpose I/O pin /
I/O
IIC Camera Interface (4)
I/O Configurable general purpose I/O pin / Transmitter ON Monitor
CMOS 2.8V
CMOS 2.8V
CMOS 2.8V
CMOS 2.8V
CMOS 2.8V
CMOS 2.8V
CMOS 2.8V
CMOS 2.8V
CMOS 2.8V
I/O
Configurable general purpose I/O pin /
ALARM
CMOS 2.8V
I/O
Configurable general purpose I/O pin /
BUZZER
CMOS 2.8V
(1) For the exclusive use of the Technical Support Service
(2) An earphone with a 150 ohm impedance can be directly connected to EAR+ and EAR–
(3) On this pin a maximum of 10nF bypass capacitor is allowed.
(4) When activating the Easy camera these pins will not be available for other use
Note: If not used, almost all pins should be left disconnected. The only exceptions are the following
pins:
pin
1,3,5,7
2,4,6,8
17
20
23
37
45
signal
VBATT
GND
ON/OFF*
TXD
RESET*
RXD
RTS 1
RTS should be connected to the GND (on the module side) if flow control is not used
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GM862-QUAD / PY Hardware User Guide
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2.3.2 Antenna Connector
The Telit GM862-QUAD / PY includes one 50 Ohm MMCX coaxial female RF connector. On the user
application side the following connector must be used:
a)
Telegärtner
crimp - Order n. J01340A0121
MMCX angle plug
NOTE: be very careful when connecting the Telit GM862 Family modules RF connector. The RF
connector can be damaged if not connected with the proper antenna RF connector. The minimum
number of insertion cycles are recommended.
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2.4 Dimensions
The Telit GM862-QUAD / PY module overall dimension are:
•
•
•
•
Length:
Width:
Thickness:
Volume:
43.9 mm
43.9 mm
6.9 mm
≅ 13 cm3
The layout is shown in the following figure:
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GM862-QUAD / PY Hardware User Guide
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2.5 Mounting the GM862 Modules on your Board
In order to electrically connect your board to the Telit GM862 Family modules, use a CSTP 2x25 pin
vertical SMD SCH–SCH Molex 53748 - 0504 (female, low profile) as a counterpart to the CSTP 50
pin vertical SMD Molex 52991–0508 (male) of your Telit GM862 Family modules.
When mounting the Telit GM862 Family modules on your board, take care of soldering the GM862
shielding reeds on a ground plane or signal.
NOTE: be very careful when connecting the Telit GM862 module RF connector. The Telit GM862
module RF connector can be damaged if not connected with the proper antenna RF connector. The
minimum number of insertion cycles is recommended.
2.5.1 Antenna Coaxial Cable Fixing
The following constraints must be respected in the Telit GM862 Family modules antenna cable
connection:
•
The fixing point of the coaxial cable must not be placed too close to the antenna connector of the
GM862 module, leaving at least 30mm of flexible cable between the fixed point and the plug end.
•
The fixing point must be at the same height of the GM862 module antenna connector, eventually
using a wedge between the PCB and the cable if it is directly fixed to the PCB.
•
The flexible cable must never be bent with a radius lower than 25mm (RG174 cable).
•
The cable must be a RG174 type or more flexible ones.
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GM862-QUAD / PY Hardware User Guide
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The following pictures explain these constraints:
- Angle connector fixing example -
- Angle connector fixing example 2 NOTE: in the examples the cable is always bent, this is not a constrain. If the installation does not
require it, then the cable can be kept straight, ensuring that the fixing is without sliding.
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2.5.2 Precautions
•
•
•
•
The plug should be inserted in the connector only after the installation of the Telit GM862
Family modules in the board. This is to prevent accidental breaking of the antenna
connection during the transport.
The coaxial cable must be fixed at least in one point, without sliding possibilities.
The plug insertion/removal must be done axially with the female connector of the GM862,
keeping lateral strains to a minimum.
The insertion/crimping pull out force must be less than 15N.
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GM862-QUAD / PY Hardware User Guide
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3 Hardware Commands
3.1 Turning ON the GM862-QUAD / PY
To turn on the GM862-QUAD / PY the pin ON# must be tied low for at least 1 second and then
released.
The maximum current that can be drained from the ON# pin is 0,1 mA.
A simple circuit to do it is:
ON#
R1
Q1
Power ON impulse
R2
GND
NOTE: don't use any pull up resistor on the ON# line, it is internally pulled up. Using pull up resistor may bring to
latch up problems on the GM862-QUAD / PY power regulator and improper power on/off of the module. The line ON#
must be connected only in open collector configuration.
NOTE: In this document all the lines that are inverted, hence have active low signals are labelled with a name that
ends with a "#" or with a bar over the name.
TIP: To check if power has raised it is possible to monitor the PWRMON line, when this line goes high the module is
powered on, but before it remains on the device needs other 900 ms for software startup. Hence check the
PWRMON line and 900 ms after its transition to high it is possible to release the ON# pin.
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For example:
1- Let's assume you need to drive the ON# pin with a totem pole output of a +3/5 V microcontroller
(uP_OUT1):
2- Let's assume you need to drive the ON# pin directly with an ON/OFF button:
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3.2 Turning OFF the GM862-QUAD / PY
The turning off of the device can be done in two ways:
• by software command (see GM862-QUAD / PY Software User Guide)
• by hardware shutdown
• by hardware unconditional shutdown
When the device is shut down by software command or by hardware shutdown, it issues to the
network a detach request that informs the network that the device will not be reachable any more.
The hardware unconditional shutdown does not issue this request and shuts down immediately the
device.
3.2.1 Hardware Shutdown
To turn OFF the GM862-QUAD / PY the pin ON# must be tied low for at least 1 second and then
released.
The same circuitry and timing for the power on shall be used.
The device shuts down after the release of the ON# pin.
TIP: To check if the device has powered off, the hardware line PWRMON should be monitored. When PWRMON goes
low, the device has powered off.
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3.2.2 Hardware Unconditional Restart
To unconditionally Shutdown the GM862-QUAD / PY the pin RESET# must be tied low for at least 200
milliseconds and then released.
The maximum current that can be drained from the RESET# pin is 0,15 mA.
A simple circuit to do it is:
RESET#
Unconditional Restart
impulse
GND
NOTE: don't use any pull up resistor on the RESET# line nor any totem pole digital output. Using pull up resistor
may bring to latch up problems on the GM862-QUAD / PY power regulator and improper functioning of the module.
The line RESET# must be connected only in open collector configuration.
TIP: The unconditional hardware Restart should be always implemented on the boards and software should use it
as an emergency exit procedure.
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For example:
1- Let's assume you need to drive the RESET# pin with a totem pole output of a +3/5 V microcontroller
(uP_OUT2):
Unconditional Restart
impulse
The hardware unconditional restart 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 stacked waiting for some network or SIM responses.
If device does not respond to a command in the timeout window, retry issuing the command and if still
no response is received a hardware reset shall be issued.
Reset Signal Operating levels:
Signal
RESET Input high
RESET Input low
Min
2.0V*
0V
Max
2.2V
0.2V
* this signal is internally pulled up so the pin can be left floating if not used.
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4 Power Supply
The power supply circuitry and board layout are the most important part in the full product design and
they strongly reflect on the product overall performances, hence read carefully the requirements and
the guidelines that will follow for a proper design.
4.1 Power Supply Requirements
The GM862-QUAD / PY power requirements are:
• Nominal Supply Voltage:
• Max Supply Voltage:
• Supply voltage range:
• Max Peak current consumption (impulsive):
• Max Average current consumption during GPRS transmission :
• Max Average current consumption during VOICE/CSD transmission :
• Average current during Power Saving:
• Average current during idle (Power Saving disabled)
3.8 V
4.2 V
3.4 V - 4.2 V
1.9 A
500 mA
270 mA
≈ 4 mA
≈ 19 mA
The GSM system is made in a way that the RF transmission is not continuous, else it is packed into
bursts at a base frequency of about 216 Hz, the relative current peaks can be as high as about 2A.
Therefore the power supply has to be designed in order to withstand with 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 and the
supply; this will reflect on all the audio paths producing an audible annoying noise at 216 Hz; if the
voltage drop during the peak current absorption is too much, then the device may even shutdown as a
consequence of the supply voltage drop.
TIP: The electrical design for the Power supply should be made ensuring it will be capable of a peak current output
of at least 2 A.
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4.2 General Design Rules
The principal guidelines for the Power Supply Design embrace three different design steps:
- the electrical design
- the thermal design.
- the PCB layout.
4.2.1 Electrical Design Guidelines
The electrical design of the power supply depends strongly from 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
4.2.1.1 + 5V input Source Power Supply Design Guidelines
•
•
•
•
•
The desired output for the power supply is 3.8V, hence there's not a big difference between the
input source and the desired output and a linear regulator can be used. A switching power supply
will not be suited because of the low drop out requirements.
When using a linear regulator, a proper heat sink shall 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 GM862-QUAD / PY, 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 should be inserted close to the power input, in order to save the GM862-QUAD
/ PY from power polarity inversion.
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An example of linear regulator with 5V input is:
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4.2.1.2 + 12V input Source Power Supply Design Guidelines
•
•
•
•
•
•
•
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 shall not be used. A switching
power supply will be preferable because of its better efficiency especially with the 2A peak current
load represented by the GM862-QUAD / PY.
When using a switching regulator, a 500Khz 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.
For car PB battery the input voltage can rise up to 15,8V and this should 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.
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 should be inserted close to the power input, in order
to clean the supply from spikes.
A protection diode should be inserted close to the power input, in order to save the GM862-QUAD
/ PY from power polarity inversion. This can be the same diode as for spike protection.
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An example of switching regulator with 12V input is in the below schematic (it is split in 2 parts):
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4.2.1.3 Battery Source Power Supply Design Guidelines
•
The desired nominal output for the power supply is 3.8V and the maximum voltage allowed is
4.2V, hence a single 3.7V Li-Ion cell battery type is suited for supplying the power to the Telit
GM862-QUAD / PY module.
The three cells Ni/Cd or Ni/MH 3,6 V Nom. battery types or 4V PB types MUST NOT BE USED
since their maximum voltage can rise over the absolute maximum voltage for the GM862-QUAD /
PY and damage it.
NOTE: DON'T USE any Ni-Cd, Ni-MH, and Pb battery types. Their use can lead to overvoltage on the GM862-QUAD /
PY and damage it. USE ONLY Rechargeable 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 should be inserted close to the power input, in order to save the GM862-QUAD
/ PY from power polarity inversion. Otherwise the battery connector should 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.
4.2.1.4 Battery Charge control Circuitry Design Guidelines
The charging process for Li-Ion Batteries can be divided into 4 phases:
• Qualification and trickle charging
• Fast charge 1 - constant current
• Final charge - constant voltage or pulsed charging
• Maintenance charge
The qualification process consists in a battery voltage measure, indicating roughly its charge status. If
the battery is deeply discharged, that means its voltage is lower than the trickle charging threshold,
then the charge must start slowly possibly with a current limited pre-charging process where the
current is kept very low with respect to the fast charge value: the trickle charging.
During the trickle charging the voltage across the battery terminals rises; when it reaches the fast
charge threshold level the charging process goes into fast charge phase.
During the fast charge phase the process proceeds with a current limited charging; this current limit
depends on the required time for the complete charge and from the battery pack capacity. During this
phase the voltage across the battery terminals still raises but at a lower rate.
Once the battery voltage reaches its maximum voltage then the process goes into its third state: Final
charging. The voltage measure to change the process status into final charge is very important. It
must be ensured that the maximum battery voltage is never exceeded, otherwise the battery may be
damaged and even explode. Moreover for the constant voltage final chargers, the constant voltage
phase (final charge) must not start before the battery voltage has reached its maximum value,
otherwise the battery capacity will be highly reduced.
The final charge can be of two different types: constant voltage or pulsed.
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The constant voltage charge proceeds with a fixed voltage regulator (very accurately set to the
maximum battery voltage) and hence the current will decrease while the battery is becoming charged.
When the charging current falls below a certain fraction of the fast charge current value, then the
battery is considered fully charged, the final charge stops and eventually starts the maintenance.
The pulsed charge process has no voltage regulation, instead the charge continues with pulses.
Usually the pulse charge works in the following manner: the charge is stopped for some time, let's say
few hundreds of ms, then the battery voltage will be measured and when it drops below its maximum
value a fixed time length charging pulse is issued. As the battery approaches its full charge the off
time will become longer, hence the duty-cycle of the pulses will decrease. The battery is considered
fully charged when the pulse duty-cycle is less than a threshold value, typically 10%, the pulse charge
stops and eventually the maintenance starts.
The last phase is not properly a charging phase, since the battery at this point is fully charged and the
process may stop after the final charge. The maintenance charge provides an additional charging
process to compensate for the charge leak typical of a Li-Ion battery. It is done by issuing pulses with
a fixed time length, again few hundreds of ms, and a duty-cycle around 5% or less.
This last phase is not implemented in the GM862-QUAD / PY internal charging algorithm, so that the
battery once charged is left discharging down to a certain threshold so that it is cycled from full charge
to slight discharge even if the battery charger is always inserted. This guarantees that anyway the
remaining charge in the battery is a good percentage and that the battery is not damaged by keeping it
always fully charged (Li-Ion rechargeable battery usually deteriorate when kept fully charged).
Last but not least, in some applications it is highly desired that the charging process restarts when the
battery is discharged and its voltage drops below a certain threshold, GM862-QUAD / PY internal
charger does it.
As you can see, the charging process is not a trivial task to be done; moreover all these operations
should start only if battery temperature is inside a charging range, usually 5°C - 45°C.
The GM862-QUAD / PY measures the temperature of its internal component, in order to satisfy this
last requirement, it's not exactly the same as the battery temperature but in common application the
two temperature should not differ too much and the charging temperature range should be
guaranteed.
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An example of battery charger can be:
NOTE: In this particular application the battery charger input current must be limited to less than 1A. Using a
current limited wall adapter as the power source can do this.
For your convenience in the EVK there's also a current unlimited input, where the input source is not limited in
current and the drawn current is limited to about 0,5A by a MOSFET in the EVK.
The external battery charger is suggested in applications where the total consumption is higher than the current
provided by the GM862-QUAD / PY module.
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4.2.2 Thermal Design Guidelines
The thermal design for the power supply heat sink should be done with the following specifications:
•
•
•
•
Average current consumption during transmission @PWR level max:
Average current consumption during transmission @ PWR level min:
Average current during Power Saving:
Average current during idle (Power Saving disabled)
500mA
100mA
4mA
19mA
NOTE: The average consumption during transmissions depends on the power level at which the device is requested
to transmit by the network. The average current consumption hence varies significantly.
TIP: The thermal design for the Power supply should be made keeping a average consumption at the max
transmitting level during calls of 500mA.
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 into transmission for short periods of time (let's say few minutes)
and then remains for a quite long time in idle (let's 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 one for
500mA maximum current, or even could be the simple chip package (no heat sink).
Moreover in the 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 the 500mA, being usually
around 150mA.
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.
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4.2.3 Power Supply PCB layout Guidelines
As seen on the electrical design guidelines the power supply shall 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 GM862-QUAD / PY power input
pins or in the case the power supply is a switching type it can be placed close to the inductor to cut
the ripple provided the PCB trace from the capacitor to the GM862-QUAD / PY is wide enough to
ensure a dropless 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 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,
introducing the noise floor at the burst base frequency. For this reason while a voltage drop of 300400 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 doesn't have audio interface but only
uses the data feature of the Telit GM862-QUAD / PY, then this noise is not so disturbing and
power supply layout design can be more forgiving.
The PCB traces to the GM862-QUAD / PY and the Bypass capacitor must be wide enough to
ensure no voltage drops occur when the 2A current peaks are absorbed. This is for the same
reason as previous point. 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 (100-500 kHz usually).
The use of a good common ground plane is suggested.
The placement of the power supply on the board should be done in such 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 should be kept separate from noise sensitive lines such as
microphone/earphone cables.
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5 Serial Ports
The serial port on the Telit GM862-QUAD / PY is the core of the interface between the module and
OEM hardware.
2 serial ports are available on the module:
• MODEM SERIAL PORT
• TRACE (Usable only on GM862-QUAD-PY for Python Debug)
Several configurations can be designed for the serial port on the OEM hardware, but the most
common are:
- RS232 PC com port
- microcontroller UART @ 2.8V - 3V (Universal Asynchronous Receive Transmit)
- microcontroller UART@ 5V or other voltages different from 2.8V
Depending from the type of serial port on the OEM hardware a level translator circuit may be needed
to make the system work. The only configuration that doesn't need a level translation is the 2.8V
UART.
The TRACE Serial Port is a 3 wire (RX, TX GND) +2.8V UART.
The MODEM serial port on the GM862-QUAD / PY is a +2.8V UART with all the 7 RS232 signals. It
differs from the PC-RS232 in the signal polarity (RS232 is reversed) and levels. The levels for the
GM862-QUAD / PY UART are the CMOS levels:
Absolute Maximum Ratings -Not Functional
Parameter
Min
Max
Input level on any
-0.3V
digital pin when on
Input voltage on
-0.3V
analog pins when on
+3.75V
+3.0 V
Operating Range - Interface levels (2.8V CMOS)
Level
Min
Max
Input high level
VIH
2.1V
Input low level VIL 0V
Output high level VOH 2.2V
Output low level VOL 0V
3.3V
0.5V
3.0V
0.35V
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The signals of the GM862-QUAD / PY MODEM serial port are:
RS232
Pin
Number
Signal
DCD dcd_uart
RXD tx_uart
TXD rx_uart
DTR dtr_uart
GND
DSR dsr_uart
RTS rts_uart
CTS cts_uart
RI ri_uart
GM862QUAD /
PY Pin
Number
36
Name
Usage
Data Carrier Detect
37
Transmit line *see Note
20
Receive line *see Note
43
Data Terminal Ready
2-4
33
Ground
Data Set Ready
45
Request to Send
29
Clear to Send
30
Ring Indicator
Output from the GM862-QUAD / PY that
indicates the carrier presence
Output transmit line of GM862-QUAD / PY
UART
Input receive of the GM862-QUAD / PY
UART
Input to the GM862-QUAD / PY that controls
the DTE READY condition
Ground
Output from the GM862-QUAD / PY that
indicates the module is ready
Input to the GM862-QUAD / PY that controls
the Hardware flow control
Output from the GM862-QUAD / PY that
controls the Hardware flow control
Output from the GM862-QUAD / PY that
indicates the incoming call condition
NOTE: According to V.24, RX/TX signal names are referred to the application side, therefore on the GM862-QUAD /
PY side these signal are on the opposite direction: TXD on the application side will be connected to the receive line
(here named TXD/ rx_uart ) of the GM862-QUAD / PY serial port and vice versa for RX.
TIP: For a minimum implementation, only the TXD and RXD lines can be connected, the other lines can be left open
provided a software flow control is implemented.
The signals of the TRACE serial port are:
Signal
RX_TRACE
GM862QUAD /
PY Pin
Number
41
TX_TRACE
35
GND
2-4
Name
Usage
Python Debug Receive
line
Python Debug Transmit
line
Ground
Input line of Python Debug serial Port
Output line of Python Debug serial Port
Ground
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5.1 Level translation
In order to interface the Telit GM862-QUAD / PY 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 0/3V to +15/-15V
Actually, the RS232 UART 16450, 16550, 16650 & 16750 chipsets accept signals with lower levels on
the RS232 side (EIA/TIA-562) , allowing for 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 driver and receiver 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 0-3V UART level to the RS232 level, while the
receiver is the translator from RS232 level to 0-3V UART.
In order to translate the whole set of control lines of the UART you will need:
- 5 driver
- 3 receiver
NOTE: The digital input lines working at 2.8VCMOS have an absolute maximum input voltage of 3,75V; therefore the
level translator IC shall not be powered by the +3.8V supply of the module. Instead it shall be powered from a +2.8V /
+3.0V (dedicated) power supply.
This is because in this way the level translator IC outputs on the module side (i.e. GM862-QUAD / PY inputs) will
work at +3.8V interface levels, stressing the module inputs at its maximum input voltage.
This can be acceptable for evaluation purposes, but not on production devices.
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An example of level translation circuitry of this kind is:
the RS232 serial port lines are usually connected to a DB9 connector with the following layout:
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5.2 5V UART level translation
If the OEM application uses a microcontroller with a serial port (UART) that works at a voltage different
from 2.8 - 3V, then a circuitry has to be provided to adapt the different levels of the two set of signals.
As for the RS232 translation there are a multitude of single chip translators. For example a possible
translator circuit for a 5V TRANSMITTER/RECEIVER can be:
TIP: This logic IC for the level translator and 2.8V pull-ups (not the 5V one) can be powered
directly from PWRMON line of the GM862-QUAD / PY. Note that the TC7SZ07AE has open
drain output, therefore the resistor R2 is mandatory.
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NOTE: The UART input line TXD (rx_uart) of the GM862-QUAD / PY is NOT internally pulled
up with a resistor, so there may be the need to place an external 47KΩ pull-up resistor,
either the DTR (dtr_uart) and RTS (rts_uart) input lines are not pulled up internally, so an
external pull-up resistor of 47KΩ may be required.
A power source of the internal interface voltage corresponding to the 2.8VCMOS high level is
available at the PWRMON pin on the connector, whose absolute maximum output current is 1mA.
A maximum of 9 resistors of 47 KΩ pull-up can be connected to the PWRMON pin, provided no other
devices are connected to it and the pulled-up lines are GM862-QUAD / PY input lines connected to
open collector outputs in order to avoid latch-up problems on the GM862-QUAD / PY.
Care must be taken to avoid latch-up on the GM862-QUAD / PY and the use of this output line to
power electronic devices shall be avoided, especially for devices that generate spikes and noise such
as switching level translators, micro controllers, failure in any of these condition can severely
compromise the GM862-QUAD / PY functionality.
NOTE: The input lines working at 2.8VCMOS can be pulled-up with 47KΩ resistors that can
be connected directly to the PWRMON line provided they are connected as in this example.
NO OTHER devices than those suggested should be powered with the PWRMON line;
otherwise the module functionality may be compromised.
It is important to consider that the added circuit must have consumption lower than 1mA.
In case of reprogramming of the module has to be considered the use of the RESET line to
start correctly the activity.
The preferable configuration is having an external supply for the buffer.
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6 Audio Section Overview
The Base Band Chip of the GM862-QUAD / PY Telit Module provides two different audio blocks; both
in transmit (Uplink) and in receive (Downlink) direction:
“MT lines” should be used for handset function,
“HF lines” is suited for hands -free function (car kit).
These two blocks can be active only one at a time, selectable by AXE hardware line or by AT
command.
The audio characteristics are equivalent in transmit blocks, but are different in the receive ones and
this should be kept in mind when designing.
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page 37 of 70
50cm
7cm
3,3mV rms
-45dBV/Pa
-45dBV/Pa
0,33mV rms
23mVrms
365mV rms
GM862-QUAD / PY
GE863-GPS
Audio Paths
Audio Paths
+10dB
+20dB
Ear_HF-
Ear_HF+
Mic_HF+
Mic_HF-
Ear_MT-
Mic_MT-
Ear_MT+
GM863-GPS/
GM862-QUAD
Mic_MT+
Single
ended
Balanced
Fully Differential
Power Buffers
Differential
Line-Out Drivers
16
-12dBFS
16
audio2.skd
GM862-QUAD / PY Hardware User Guide
1vv0300748 Rev. 1 - 24/10/06
EXTERNAL
AMPLIFIER
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6.1 Microphone Paths Characteristic and Requirements
TIP: being the microphone circuitry the more noise sensitive, its design and layout must be
done with particular care. Both microphone paths are balanced and the OEM circuitry should
be balanced designed to reduce the common mode noise typically generated on the ground
plane. However also an unbalanced circuitry can be used for particular OEM application needs.
TIP: due to the difference in the echo canceller type, the “Mic_MT” audio path is suited for
Handset applications, while the “Mic_HF”audio path is suited for hands-free function (car kit).
The Earphone applications should be made using the “Mic_HF” audio path but DISABLING the
echo canceller by software AT command. If the echo canceller is left active with the Earphone,
then some echo might be introduced by the echo cancel algorithm.
“Mic_MT” 1st differential microphone path
•
•
•
•
•
•
•
•
line coupling
line type
coupling capacitor
differential input resistance
differential input voltage
microphone nominal sensitivity
analog gain suggested
echo canceller type
AC
balanced
≥ 100nF
50kΩ
≤ 1,03Vpp (365mVrms)
-45 dBVrms/Pa
+ 20dB
handset
“Mic_HF” 2nd differential microphone path
•
•
•
•
•
•
line coupling
line type
coupling capacitor
differential input resistance
differential input voltage
microphone nominal sensitivity
AC
balanced
≥ 100nF
50kΩ
≤ 65mVpp (23mVrms)
-45 dBVrms/Pa
•
•
analog gain suggested
echo canceller type
+10dB
car kit hands-free
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TIP: definition of the nominal sensitivity of the microphone lines .
The nominal sensitivity of the microphone lines indicates the voltage level on the GM862-QUAD / PY
pins present during "normal spoken" conditions.
For a handset , the "normal spoken” conditions take place when the talker mouth is 7cm far from the
microphone ; under these conditions the voice will produce an acoustic pressure of -4,7dBPa @1kHz
on the microphone membrane .
TIP: electrical equivalent signal and operating voice levels .
At "normal spoken" conditions, a microphone having the suggested nominal sensitivity of 45dBVrms/Pa , will produce
the electrical equivalent signal :
MicLevel = ( -45) + (-4.7) = -49.7 dBVrms
that means :
MicVoltage = 10 ( -49.7 / 20 ) = 3.3* 10 -3 Vrms
During a call , this level varies according to the volume of the talker voice; usually the following rough
thumb rule for the dynamic range may be used :
1) the talker is screaming . This is the strongest voice level condition: the signal increases by
+20dB ;
2) the talker is whispering. This is the lowest voice level condition: the voice level decreases by –
50dB .
These changes must be considered for designing the external microphone amplifier.
TIP: example of external microphone amplifier calculation .
Let’s suppose to use the 1stdifferential microphone path .In this case the maximum differential input
voltage to “Mic_MT” lines is 365mVrms(1,03Vpp) corresponding to –8,76dBV.
Now we can calculate the maximum voltage gain of an external microphone amplifier GA:
[(MicLevel + 20dB ) + G A ] = −8,76dBV
[− 49,7 + 20 + G A ] = −8,76
− 40,9 + 20 = −G A
G A = 20,94dB
you can set GA= +20dB to use standard resistor values .
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TIP: environment consideration .
For hands-free/car kit microphone, you must take into account the voice attenuation, due to the
distance between the microphone itself and the talker, when designing the external microphone
amplifier.
Not only, you must consider that the microphone will pick up also ambient noise; to overcome this
problem it is preferable to set the gain of the microphone 10dB lower with respect to the calculated
value for a nominal sensitivity. The corresponding reduction in signal level will be compensated by an
increased voice volume of the talker which will speak louder because of the ambient noise.
For a car cabin usually the distance between the microphone itself and the talker is 40/50cm ; in these
conditions the attenuation can be considered as a thumb rule around 20dB .
For the earphone we shall distinguish two different types: the earphones having the microphone
sustained close to the mouth and the ones having the microphone on the earpiece cable.
The same considerations for the additional voice attenuation due to the distance from the microphone
and the noise pick up can be made for the earphone having the microphone on the earpiece cable,
while the other kind of earphone shall be threaten as an handset.
TIP: how to compensate the losses in car cabin hands-free condition.
The voice signal , that in the "normal spoken” conditions produces on the microphone membrane an
acoustic pressure of -4,7dBPa at 1kHz , will have a further attenuation of 20dB due the 50cm distance
Therefore a microphone having the suggested nominal sensitivity of -45dBVrms/Pa,will produce a lower
electrical
equivalent signal :
MicLevel = ( -45) + (-4.7)-20 = -69.7
that means :
MicVoltage = 10 ( -49.7 / 20 ) = 0,33* 10 -3
Setting the “microphone gain” at +10dB (3 times), the signal in the nominal conditions on the
“Mic_HF” inputs s of GM862-QUAD / PY Telit Module will be :
“Mic_HF” Level = 0,33* 10 -3 * 3=1* 10 -3
Hence in these conditions the signal level on the“Mic_HF” input pads of the GM862-QUAD / PY is 10
dB (3 times) lower than the nominal, as suggested.
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6.2 General Design Rules
There are several configurations for the audio paths, but the most effective difference is between
balanced and unbalanced microphone configuration.
It is highly recommended to keep the whole microphone path balanced even if this means having 2
wires connecting the microphone instead of one needed (plus ground) in the unbalanced case. The
balanced circuitry is more suited because of its good common mode noise rejection, reducing the 216
Hz burst noise produced during the GSM transmissions.
• Where possible use balanced microphone circuitry
• Keep the microphone traces on the PCB and wires as short as possible.
• If your application requires an unbalanced microphone, then keep the lines on the PCB balanced
and "unbalance" the path close to the microphone wire connector if possible.
• For the microphone biasing voltage use a dedicated voltage regulator and a capacitor multiply
circuit.
• Make sure that the microphone traces in the PCB don't cross or run parallel to noisy traces
(especially the power line)
• If possible put all around to the microphone lines a ground trace connected to the ground plane by
several vias. This is done in order to simulate a shielded trace on the PCB.
• The biasing circuit and eventually the buffer can be designed in the same manner for the internal
and external microphones.
6.3 Other Considerations
If your application is a hands-free/car kit scenario, but you need to put microphone and speaker inside
the same box:
• Try to have the maximum possible distance between them, at least 7cm;
• becauses the microphone type is very important, if you use an omni-directional one ( and this is
the typical applicaton ) please seal it on the rear side (no back cavity) in order not to collect
unwanted signals ;
• try to make divergent the main axes of the two devices .
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6.4 Microphone Biasing
The electret microphones usually need a biasing voltage to work properly. Refer to your microphone
provider for the characteristics required.
NOTE: The microphones have a hot wire were the positive biasing must be connected. Usually
it is indicated by a + symbol or a red point. If the polarity of the bias is reversed, then the
microphone will not work properly. For this reason be sure to respect the mic. biasing polarity.
6.4.1 Balanced Microphone Biasing
The balanced microphone bias voltage should be obtained from a dedicated voltage regulator, in order
to eliminate the noise present on the power lines. This regulator can be the same for all the audio
paths. The microphone should be supplied from a capacitor multiply circuit.
For example a circuit for the balanced microphone biasing can be:
NOTE: In the balanced application the resistors R2 and R3 must have the same value to keep
the circuit balanced.
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NOTE: The cable to the microphone should not be shielded; instead a twisted pair cable shall
be used.
NOTE: The microphone sensitivity changes with the value of R2 and R3. Usually the
microphones are characterized with 2kΩ biasing resistance, so try to keep the sum of R2 and
R3 around 2kΩ. Refer to your microphone manufacturer for the mic. characteristics.
6.4.2 Unbalanced Microphone Biasing
The unbalanced microphone biasing voltage should be obtained from a dedicated voltage regulator, in
order to eliminate the noise present on the power lines. This regulator can be the same for all the
audio paths. The microphone should be supplied from a capacitor multiply circuit.
For example a circuit for the unbalanced microphone biasing can be:
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NOTE: In the unbalanced application the capacitor C3 shall be > 200nF otherwise the frequency
response will be cut at low band frequencies (down to 300Hz). This capacitor can be placed
close to the MIC- pad (MIC_HF- or MIC_MT- depending on the audio path chosen) or if
possible it should be placed close to the shielded cable connector. If the ground return path is
well designed, then it is possible to eliminate the C3 capacitor, provided the buffer is close to
the mic. input.
NOTE: The cable to the microphone should be shielded.
NOTE: The microphone changes with the value of R2. Usually the microphone sensitivity is
characterized with 2kΩ biasing resistance, so try to keep the value of R2 around 2kΩ. For mic.
characteristics refer to the manufacturer.
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6.5 Microphone Buffering
As seen previously, a microphone shall be connected to the input pins of the GM862-QUAD / PY
through a buffer amplifier that boosts the signal level to the required value.
Again the buffered microphone circuitry can be balanced or unbalanced: where possible it is always
preferable a balanced solution. The buffering circuit shall be placed close to the microphone or close
to the microphone wire connector.
6.5.1 Buffered Balanced Mic.
A sample circuit can be:
+20 dB
15K
270pF
15K
270pF
This circuit has a gain of 10 times (+20 dB), and is therefore suited for the “Mic_MT “ input if you have
a microphone with a sensitivity close to the suggested one (-45 dBVrms/Pa). If your microphone has a
different sensitivity or if the buffer is connected to the “Mic_HF “ inputs , then a gain adjustment shall
be done by changing resistors R604 and R606 ( if the required value is not a standard one , you can
change R605 e R607 ) and as a consequence the capacitors C636 and C637 to maintain the
bandwidth 150-4000Hz (at -3dB).
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The buffer gain is given by the formula:
Gain =
R604 R606
R605 R607
The C636 and C637 capacitors are placed in order to cut off the gain at higher frequencies than the
transmitted GSM band, the cutoff frequency (-3dB) should be 3500Hz in order to have -1dB at 3kHz.
The cutoff frequency is given by the formula:
freq. =
[Hz]
2π * R604 * C 637 2π * R606 * C 636
TIP: example of calculation.
Let's assume you have a microphone with a sensitivity of -45 dBVrms/Pa and you want to use it in 1st
differential microphone path (“Mic_MT” inputs) in "normal spoken" conditions at acoustic pressure of
-4.7dBPa.
As reported at page 33 , the electrical level output from the microphone will be :
MicLevel = ( -45) + (-4.7) = -49.7 dBVrms
corresponding to:
MicVoltage = 10 ( -49.7 / 20 ) = 3.3* 10 -3 Vrms
When the talker is screaming , we will have a signal of 330 mVrms on the “Mic_MT “ inputs due to a
20dB higher Mic Level (see TIP 1) with a buffer gain GA :
GA =20 log (AmplifierOutput / MicVoltage) =20 log (330 * 10 -3 )/( 33 * 10 -3 ) = 20 log 10=20dB
The corresponding values for the resistors on the buffer could be ( if we keep the input resistance
10kΩ )
R604 = R606 = gain* R607= gain* R605 = 10* 15 = 150 kΩ
The commercial values of 150kΩ & 15kΩ are then chosen.
As a consequence the values of the capacitors C636 and C637 shall be:
C636=C637= 1/ (2π*4000*R606)= 265 *10 -12 F
A commercial value of 270pF gives a cutoff frequency of 3931Hz with an errorless than 1,8% .
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6.5.2 Buffered Unbalanced (Single Ended) Microphone .
2,7nF
6,8nF
The above schematic can be used for a single ended (buffered unbalanced) microphone ; the required
biasing circuitry is not included. Note also that the capacitor C3 is not needed .
The gains of the two amplifiers are given by the formulas :
Gain(not inverting buffer ) = 1 +
R 719
R 720
Gain(inverting buffer ) =
R711
R708
Assigning half of overall gain to each amplifier, you will obtain the requested gain because of doubling
the microphone signal path; in fact by the use of two amplifiers (the upper as “inverting” and the lower
as “not inverting”configuration ) we obtain an additional +6dB gain (2 times) .
Remember : the “not inverting “ amplifier section gain shall not be less than 1 .
Like for the balanced buffered microphone , the amplifier overall gain can be modify changing the
value of resistor R719/R720 and R711 and as a consequence the capacitors C726 and C727. It is
advisable to change R708 only if you have difficulty to find a commercial value for R711 ; in this case
change R708 as little as possible .
The -3dB bandwidth is given by the approximated formula (considering C725 >> C726):
freq. =
[Hz]
2π * R719 * C 726 2π * R711* C 727
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The buffer bandwidth at -3dB shall be 4KHz.
Note that the biasing of the operational amplifier is given for the inverting amplifier by the series divider
R714-R715. The 100nF capacitor C719 is needed to filter the noise that could be coupled to that
divider. For the not inverting operational amplifier the biasing is given by a different divider R715-R717
with the capacitor C720 and through a series resistor R718 of 470KΩ.
TIP: example of calculation.
Llet's assume you have a microphone with a sensitivity of -45dBVrms/Pa and you want to use it in 2nd
differential microphone path (“Mic_HF” inputs) in "normal spoken" conditions at acoustic pressure of 4.7dBPa.
As reported at page XX , the electrical level output from the microphone will be :
MicLevel = ( -45) + (-4.7) = -49.7 dBVrms
but we have to consider 20dB loss due to the higher distance from the mouth of the talker ( 50cm ) .
MicLevel = ( -49.7) + (-20) = -69.7 dBVrms
corresponding to
MicVoltage = 10 ( -69.7 / 20 ) = 0,33* 10 -3
In order to have a signal of 1 mVrms at the “Mic_HF” inputs , as suggested at TIP “environment
consideration “,
the buffer must have a gain
GA= “Mic_HF /MicVoltage = (1*10 -3)/(0,33*10
or +10 dB
Keeping in mind that “ balancing the line will double the signal”, to calculate the resistor values assign
half of required gain GA to each amplifier section . And therefore GS =1,5times (or +3,52dB) .
Choosing as 10kΩ as the input resistance , the corresponding values for the resistors on the buffer will
be :
R711 = GS * R708= 1.5*10 =15 kΩ
R719 = (GS -1) * R720 = (1.5 -1)*10 =5 kΩ
The commercial values of 15kΩ and 5.6kΩ be accepted .
As a consequence of the assigned values of the resistors, the nominal values of C726 and C727 are
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C726= 1/ (2π*4000*R719)= 7.10 *10 -9 F
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C727= 1/ (2π*4000*R711)= 2,65 *10 -9 F
modified in 6,8nF (fc1=4181Hz ) and 2,7nF (fc2=3931Hz) because of commercial values .
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OUTPUT LINES (Speaker)
7.1 Short Description.
The Telit GM862-QUAD / PY provides two audio paths in receive section. Only one of the two paths
can be active at a time, selectable by AXE hardware line or by AT command.
You must keep in mind the different audio characteristics of the receive blocks when designing:
Æ the “Ear_MT” lines EPN1 and EPP1 are the Differential Line-Out Drivers ; they can drive an
external amplifier or directly a 16 Ω earpiece at –12dBFS (*) ;
Æ the “Ear_HF” lines EPPA1_2 and EPPA2 are the Fully Differential Power Buffers ; they can directly
drive a 16Ω speaker in differential (balanced) or single ended (unbalanced) operation mode .
(*) FS : acronym of Full Scale. It is equal to 0dB, the maximum Hardware Analog Receive Gain of
BaseBand Chip.
The “Ear_MT” audio path should be used for handset function, while the “Ear_HF” audio path is suited
for hands-free function (car kit).
Both receiver outputs are B.T.L. type (Bridged Tie Load) and the OEM circuitry shall be designed
bridged to reduce the common mode noise typically generated on the ground plane and to get the
maximum power output from the device; however also a single ended circuitry can be designed for
particular OEM application needs.
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7.2 Output Lines Characteristics
“Ear_MT” Differential Line-out Drivers Path
• line coupling:
• line type:
• output load resistance :
• internal output resistance:
• signal bandwidth:
• max. differential output voltage
• differential output voltage
• SW volume level step
• number of SW volume steps
DC
bridged
≥ 14 Ω
4 Ω (typical)
150 - 4000 Hz @ -3 dB
1310 mVrms (typ, open circuit)
328mVrms /16 Ω @ -12dBFS
- 2 dB
10
“Ear_HF” Power Buffers path
• line coupling:
• line type:
• output load resistance :
• internal output resistance:
• signal bandwidth:
• max. differential output voltage
• max. single ended output voltage
• SW volume level step
• number of SW volume steps
DC
bridged
≥ 14 Ω
4 Ω ( >1,7 Ω )
150 - 4000 Hz @ -3 dB
1310 mVrms (typ, open circuit)
656 mVrms (typ, open circuit)
- 2 dB
10
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7.3 General Design Rules
There are several configurations for the audio output path, but the various design requirements can be
grouped into three different categories:
•
•
•
handset earphone (low power, typically a handset)
hands-free earphone (low power, typically a earphone)
car kit speakerphone (high power, typically a speaker)
The three groups have different power requirements, usually the first two applications need only few
mW of power, which can be directly drained from the GM862-QUAD / PY pads, provided a suited
speaker is used. This direct connect design is the cheaper and simpler solution and will be suited for
the most of the earphone design requirements. There's no need to decouple the output ear lines if a
suited earpiece is connected. For the last group, the speakerphone, a power amplifier is required to
raise the output power up to 5-10W required in a car cabin application.
All the designs shall comply with the following guidelines:
• Where possible use a bridged earphone circuitry, to achieve the maximum power output from the
device.
• Keep the earphone traces on the PCB and wires as short as possible.
• If your application requires a single ended earpiece and you want a direct connection, then leave
one of the two output lines open and use only the other referred to ground. Remember that in this
case the power output is 4 times lower than the bridged circuit and may not be enough to ensure
a good voice volume.
• Make sure that the earphone traces in the PCB don't cross or run parallel to noisy traces
(especially the power line)
• The cable to the speaker shall be a twisted pair with both the lines floating for the bridged output
type, shielded with the shield to ground for the single ended output type.
7.3.1 Noise Filtering
The I/O of the PCB should have a noise filter close to the connector, to filter the high frequency GSM
noise. The filter can be a Π formed by 2 capacitor and a inductance, with the one capacitor of 39pF 0603 case , and the other capacitor of 1nF - 0603; the inductance shall have a value of 39μH .
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7.4 Handset Earphone Design
As seen previously, a 16Ω earpiece can be directly connected to the output pads EAR_MT+ and
EAR_MT- of the GM862-QUAD / PY.
This solution is often the more cost effective, reducing the components count to a minimum. There are
several limitations to the use of this solution: speaker direct connect imposes the speaker
characteristics to be almost exactly the suggested ones, otherwise the power output may be reduced
(if speaker impedance is bigger than 16Ω) or the GM862-QUAD / PY ear port may be damaged (if
speaker impedance is less than 15Ω).
The other limitation of the speaker direct connection is the power output capability of the GM862QUAD / PY which is limited and for some particular applications may not be enough.
For these reasons, when the power output of the GM862-QUAD / PY is not enough or if the speaker
characteristics are different from the suggested, then it is preferable to use an amplifier to increase the
power and current output capabilities.
Again the output from the GM862-QUAD / PY is bridged and both lines should be used, where
possible, as inputs to the power amplifier. This ensures a higher common mode rejection ratio,
reducing the GSM current busts noise on the speaker output.
In this case the “EAR_MT” lines from the GM862-QUAD / PY should be AC coupled with a ceramic
capacitor of 100nF (or bigger ) .
It is always desirable to have a mute control on the amplifier, in order to turn it off while the device is
not sending signal to the output, in this manner the amplifier background noise which may be audible
during idle conditions is cut off.
A principle schematic may be:
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The resulting gain and high pass cut can be obtained with the formula:
Gain =
freq. =
R3
R2
[Hz]
2π * R3 * C 4
And an example of internal Ear amplifier could be :
+12dB
GM862-QUAD / PY
Some amplifier require a low impedance load at high frequency in order to avoid auto oscillation, this
can be made with a capacitor (100nF) in series with a resistor (15Ω).
When designing your application, remember to provide an adequate bypass capacitor to the amplifier
and place it close to the power input pin of the IC, keeping the traces as short as possible.
7.5 Hands-Free Earphone (Low Power) Design
The same design considerations made for the handset are valid for the hands-free earphone.
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7.6 Car Kit Speakerphone Design
For the car kit speaker phone function the power output requirement is usually at least 4W, therefore
an amplifier is needed to boost the GM862-QUAD / PY output.
The design of the amplifier shall comply with the following guidelines:
•
•
•
•
•
•
The input to the amplifier MUST be taken from the “Ear_HF” audio path of the GM862-QUAD / PY,
because of its echo canceller parameters suited to a car cabin use.
The amplifier shall have a gain of 30-40 times (29-32 dB) to provide the desired output power of 510W with the signal from the GM862-QUAD / PY “Ear_HF” audio output lines.
If the amplifier has a fixed gain then it can be adjusted to the desired value by reducing the input
signal with a resistor divider network.
The amplifier shall have a mute control to be used while not in conversation. This results in two
benefits: eliminating the background noise when not in conversation and saving power.
The power to the amplifier should be decoupled as much as possible from the GM862-QUAD / PY
power supply, by either keeping separate wires and placing bypass capacitors of adequate value
close to the amplifier power input pads.
The biasing voltage of the amplifier shall be stabilized with a low ESR (e.g. a tantalum) capacitor of
adequate value.
NOTE: The GM862-QUAD / PY audio path connected to the car kit hands-free amplifier MUST
be “Ear_HF” one, otherwise the echo cancellation will not be done due to the difference in the
echo canceller characteristics of the GM862-QUAD / PY internal audio path from the external
audio path.
Example of car kit amplifier schematic.
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8 General Purpose I/O
The general purpose I/O pins can be configured to act in three different ways:
- input
- output
- alternate function (internally controlled)
Input pins can only be read and report the digital value (high or low) present on the pin at the read
time; output pins can only be written or queried and set the value of the pin output; an alternate
function pin is internally controlled by the GM862-QUAD / PY firmware and acts depending on the
function implemented.
Not all GPIO pins support all these three modes:
- GPIO1 is an INPUT ONLY
- GPIO2 is an OUTPUT ONLY (open collector)
- GPIO3, GPIO4, GPIO8 to GPIO13 support both input or output mode but not Alternate function.
- GPIO5 supports all three modes and can be input, output, RFTXMON output (Alternate function)
- GPIO6 supports all three modes and can be input, output, ALARM output (Alternate function)
- GPIO7 supports all three modes and can be input, output, BUZZER output (Alternate function)
All GPIO pins except from GPIO1 and GPIO2 that are buffered with a transistor, are 2.8V CMOS
signals and their interface levels are the same specified in the paragraph 5 Serial Port.
8.1 Logic level specifications
Where not specifically stated, all the interface circuits work at 2.8V CMOS logic levels.
The following table shows the logic level specifications used in the GM862 interface circuits:
Absolute Maximum Ratings -Not Functional
Parameter
Min
Max
Input level on any -0.3V
digital pin when on
Input voltage on -0.3V
analog pins when on
+3.75V
+3.0 V
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Operating Range - Interface levels (2.8V CMOS)
Level
Min
Max
Input high level
2.1V
3.3V
Input low level
Output high level
Output low level
0V
2.2V
0V
0.5V
3.0V
0.35V
For 2,0V signals:
Operating Range - Interface levels (2.0V CMOS)
Level
Min
Max
Input high level
1.6V
3.3V
Input low level
Output high level
Output low level
0V
1,65V
0V
0.4V
2.2V
0.35V
Current characteristics
Level
Typical
Output Current
1mA
Input Current
1uA
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8.2 Using a GPIO pin as INPUT
The GPIO pins, 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 2.8V CMOS levels of the
GPIO.
If the digital output of the device to be connected with the GPIO input pin has interface levels different
from the 2.8V CMOS, then it can be connected to GPIO1 or can be buffered with an open collector
transistor, provided a 47KΩ pull-up resistor is connected as seen in the paragraph 5.2 5V UART level
translation.
8.3 Using a GPIO pin as OUTPUT
The GPIO pins, when used as outputs, can drive 2.8V CMOS digital devices or compatible hardware.
When set as outputs, the pins (except from GPIO2 which is Open Collector) have a push-pull output
and therefore the pull-up resistor may be omitted.
The GPIO2 pin, since it is an Open Collector output needs an external pull-up resistor.
8.4 Using the RFTXMON Output GPIO5
The GPIO5 pin, when configured as RFTXMON Output, is controlled by the GM862-QUAD / PY
module and will rise when the transmitter is active and fall after the transmitter activity is completed.
For example, if a call is started, the line will be HIGH during all the conversation and it will be again
LOW after hanged up.
8.5 Using the Alarm Output GPIO6
The GPIO6 pin, when configured as Alarm Output, is controlled by the GM862-QUAD / PY module
and will rise when the alarm starts and fall after the issue of a dedicated AT command.
This output can be used to power up the GM862-QUAD / PY controlling microcontroller or application
at the alarm time, giving you the possibility to program a timely system wake-up to achieve some
periodic actions and completely turn off either the application and the GM862-QUAD / PY during sleep
periods, drammatically reducing the sleep comsumption to few μA.
In battery powered devices this feature will greatly improve the autonomy of the device.
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8.6 Using the Buzzer Output GPIO7
The GPIO7 pin, when configured as Buzzer Output, is controlled by the GM862-QUAD / PY module
and will drive with appropriate square waves a Buzzer driver.
This permits to your application to easily implement Buzzer feature with ringing tones played at the call
incoming, on SMS incoming or simply playing a tone when needed by your application.
A sample interface scheme is included below to give you an idea of how to interface a Buzzer to the
GPIO7:
NOTE: To correctly drive a buzzer a driver must be provided, its characteristics depend on the Buzzer and for them
refer to your buzzer vendor.
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9 ADC section
9.1 ADC converter
9.1.1 Description
The GM862-QUAD / PY module provides a Analog to Digital Converter. The input line (named
ADC_IN1) is available on Pin #6 of the B2B connector of the module and on pin 19 of PL104
on EVK2 Board.
The on board A/D is 11-bit converter. It is able to read a voltage level in the range of 0÷2 volts
applied on the ADC pin input, store and convert it into 11 bit word.
Input Voltage range
AD conversion
Resolution
Min
Max
11
<1
Units
Volt
bits
mV
9.1.2 Using ADC Converter
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 to GM862-QUAD / PY AT commands specification for the full
description of this function.
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10 Camera
10.1 Camera Transchip
The GM862-QUAD / PY provides a direct support for Transchip digital cameras with the following
characteristics:
Type:
Technology:
Max picture size:
Output format:
Sensitivity:
10.1.1
TRANSCHIP TC5747
CMOS COLOR camera
VGA 480x640 pixels landscape
JPEG
4 Lux
Camera Interface Connectors
The 50-pins Molex connector of the module and a 24 pins ZIF connector for the CMOS camera
provide the interface connection between GM862 and Transchip camera.
Molex 52991-0508 GM862
TC5747MF24L
Pin
Signal
I/O
46
GPIO3
PD(6)
GND
2-4-6
50
34
25
2-4-6
GPIO7
CAM_PWR_ON
GPIO9
PD(1)
MON1
MON1_CAM
GND
Notes
Pin
Signal
I/O
I2C bus serial clock
SCLK
Ground
AGND
AVDD28
External 2.8V Regulator enable
controlled by CAM_PWR_ON pin
Camera Reset
RESET_N
Clock
CLK_IN**
Ground
DGND
n.c
DOUT_0
I/O
n.c
DOUT_1
I/O
n.c
DOUT_2
I/O
n.c
10
DOUT_3
I/O
n.c
11
DOUT_4
I/O
n.c
12
DOUT_5
I/O
n.c
13
DOUT_6
I/O
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50
47
2-4-6
32
2-4-6
n.c
14
DOUT_7
I/O
n.c
15
DOUT_8
I/O
n.c
16
VCLKOUT
n.c
17
VALIDH
n.c
18
VALIDV
GPIO7
CAM_PWR_ON
GPIO4
IICSDA_CAM
GND
GPIO8
PD(0)
GND
I/O
External 2.8V Regulator enable
controlled by CAM_PWR_ON pin
I2C bus serial data
19
DVDD28
20
SDIN
I/O
Ground
21
PS1
Camera power type selector
22
PS2
Ground
23
SHIELD
Flash Enable
24
LED_CTRL
Filter the AVDD28.
Use a Buffer between module clk out, MON1_CAM and camera clk in, CLK_IN.
***
Non-connected.
**
10.1.2
EVB for Camera Support
In order to interface the Telit GM862-QUAD / PY with a CMOS camera, Telit has developed an
evaluation board. The EVB is provided by:
• 10 pin Berg male connector (PL201) and RS232 level translator that allows a direct connection to
the PC. To switch on the level translator a jumper shall be set on PL203.
• 12 pin Berg male connector (PL202) to supply the GM862-QUAD / PY mounted on the EVB. The
input source power should be in the range 4,5V-12V. Charge line is also provided in case a Li-Ion
battery is connected to the VBATT pins. Charge input must fulfil charger line requests.
• 50 pin Molex male connector (PL103) to interface with the GM862-QUAD / PY directly.
• 30 pin Berg male connector (PL101) to interface with a PCB developed by the user or the EVK
board. On this connector is available the complete audio path, the serial port lines with full
handshaking, and the pins ON, AXE, RESET, GPIO1 and STAT_LED. Also the CHARGER_IN pin
can be available placing a 0 ohm resistor.
• 18 pin ZIF female connector (SO101) for CMOS camera.
• ON/OFF button (SW102) to power on and off the module.
• GPIO1 button (SW101) for future applications.
• Led (DL101) for device status indication.
NOTE: The Philips 74LVC1G08GW must be placed close to the GM862 connector; the length of the line between
CAMERA connector and MOLEX 50 PIN of GM862 must be max 5cm anyway.
NOTE: The CMOS cameras must be removed when the GPIO pins are used for I/O purpose.
Reproduction forbidden without Telit Communications S.p.A. written authorization - All Right reserved
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GM862-QUAD / PY Hardware User Guide
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Pic 1. Camera Physical Detail & Connector
Pic 2. Camera Socket Connector
Reproduction forbidden without Telit Communications S.p.A. written authorization - All Right reserved
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GM862-QUAD / PY Hardware User Guide
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10.1.3
EVB for Transchip camera support
In order to interface the Telit GM862 with a CMOS camera, Telit has developed an evaluation board.
The EVK allow connecting all Telit modules through 2 connectors of 40 pins each.
The I2CBUS DUAL CAMERA board is plugged in the 2 connectors of 30 pins each on the module
board.
CAMERA
BOARD
MODULE
BOARD
MAIN
BOARD
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GM862-QUAD / PY Hardware User Guide
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10.1.4
Block Diagram for supported camera
DVDD is an external power supply of 2.8V, controlled or gated by pin CAM_PWR_ON.
CAMERA TRANSCHIP
PD[6]
GND
AVDD
PD[1]
CAM_CLK
GND
DVDD
AVDD
GND
DVDD
IICSDA_CAM
GND
PD[0]
GND
MON1_CAM
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
CAM_CLK
Reproduction forbidden without Telit Communications S.p.A. written authorization - All Right reserved
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GM862-QUAD / PY Hardware User Guide
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10.1.5
Schematic Diagrams for supported cameras
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GM862-QUAD / PY Hardware User Guide
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10.1.6
Example usage script for camera
Camera setting: (shown here are the defaults ones)
>AT#CAMSEL=0
(camera selection: 0-auto, 1-agilent, 2-transchip)
OK
>AT#CMODE=0
(camera mode: 0-day, 1-night)
OK
>AT#CAMQUA=0
(camera quality: 0-low, 1-medieum, 2-high)
OK
>AT#CAMRES=0
(camera resolution: 0-VGA, 1-QVGA, 2-QQVGA)
OK
>AT#CAMCOL=0*
(camera color: 0-color, 1-grayscale)
OK
>AT#CAMZOOM=0
(camera zoom: 0-x1, 1-x2, 2-x4)
OK
>AT#CAMTXT=0*
(camera timestamp: 0-no, 1-time only, 2-data only, 3-time&data)
OK
Taking an reading a photo:
>AT#CAMEN=1
(camera ON)
OK
>AT#TPHOTO
(take photo)
OK
>AT+OBJL?
(see photo dimension)
#OBJL: Snapshot,38900
(where 38900 is the file dimension in bytes of the photo taken)
OK
>AT#RPHOTO
(download the photo)
…data…..
(where …data… Correspond to the photo data in binary)
OK
>AT#TPHOTO
OK
>AT#RPHOTO
Repeating photo capture and download n times
…data…..
OK
>AT#CAMEN=O
(camera OFF)
*only Transchip camera
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page 68 of 70
GM862-QUAD / PY Hardware User Guide
1vv0300748 Rev. 1 - 24/10/06
11 Conformity Assessment Issues
The GM862-QUAD & GM862-QUAD-PY module is assessed to be conforming to the R&TTE Directive
as stand-alone products so If the module is installed in conformance with Telit Communications
installation instructions require no further evaluation under Article 3.2 of the R&TTE Directive and do
not require further involvement of a R&TTE Directive Notified Body for the final product.
In all other cases, or if the manufacturer of the final product is in doubt then the equipment integrating
the radio module must be assessed against Article 3.2 of the R&TTE Directive.
In all cases assessment of the final product must be made against the Essential requirements of the
R&TTE Directive Articles 3.1(a) and (b), safety and EMC respectively, and any relevant Article 3.3
requirements.
The GM862-QUAD & GM862-QUAD-PY module is conform with the following European Union
Directives:
• R&TTE Directive 1999/5/EC (Radio Equipment & Telecommunications Terminal Equipments)
• Low Voltage Directive 73/23/EEC and product safety
• Directive 89/336/EEC for conformity for EMC
In order to satisfy the essential requisite of the R&TTE 99/5/EC directive, the GM862-QUAD &
GM862-QUAD-PY module is compliant with the following standards:
• GSM (Radio Spectrum). Standard: EN 301 511 and 3GPP 51.010-1
• EMC (Electromagnetic Compatibility). Standards: EN 301 489-1 and EN 301 489-7
• LVD (Low Voltage Directive) Standards: EN 60 950
In this document and the Hardware User Guide, Software User Guide all the information you may
need for developing a product meeting the R&TTE Directive is included. The GM862-QUAD &
GM862-QUAD-PY module is conform with the following US Directives:
• Use of RF Spectrum. Standards: FCC 47 Part 24 (GSM 1900)
• EMC (Electromagnetic Compatibility). Standards: FCC47 Part 15
To meet the FCC's RF exposure rules and regulations:
- The system antenna(s) used for this transmitter must be installed to provide a separation distance of
at least 20 cm from all the persons and must not be co-located or operating in conjunction with any
other antenna or transmitter.
- The system antenna(s) used for this module must not exceed 3 dBi for mobile and fixed or mobile
operating configurations.
- Users and installers must be provided with antenna installation instructions and transmitter operating
conditions for satisfying RF exposure compliance.
Manufacturers of mobile, fixed or portable devices incorporating this module are advised to clarify any
regulatory questions and to have their complete product tested and approved for FCC compliance.
Reproduction forbidden without Telit Communications S.p.A. written authorization - All Right reserved
page 69 of 70
GM862-QUAD / PY Hardware User Guide
1vv0300748 Rev. 1 - 24/10/06
12 Document Change Log
Revision
ISSUE#0
ISSUE#1
Date
16/10/06
24/10/06
Changes
Release First ISSUE# 0
Added chapter 11 (Conformity assessment Issues)
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