evaluation kit user guide - janus rc

Terminus Plug-In Modules Evaluation Kit User Guide

Bulletin JA03-EKUMRevision P04Date 26 Aug 2013

Terminus Plug-In Modules Evaluation Kit User Guide Rev: P04 Date: 08/26/13© Copyright 2013 Janus Remote Communications Specifications subject to change without notice

All Rights Reserved See website for latest revision. Not intended for life support applications.

INTRODUCTION

The following document describes the functions of the evaluation board for the Terminus Plug-In series of cellular communication terminals. This guide, along with the Plug-In Modules Hardware User guide, allows all features of the terminal to be evaluated before your PCB goes into CAD.

Be advised that there is an evaluation kit for each of the Plug-In Modules available on the Janus website. These kits supply all the accessories required to evaluate the chosen terminal.

INTERFACES

Power Supply

The Evaluation Board requires 5VDC to power the evaluation PCB and Terminus module. The evaluation board has two power supply connection options: center positive barrel connector or terminal block direct wire connection.

The Evaluation Board is equipped with protection circuitry to prevent reverse voltage, as well as help with protection from transients. The board can withstand a reverse voltage of 60V and a peak voltage of 80V. The circuitry is set to clip any input greater than 6V to a safe level.

Any input above 6V will read for a set period, and if before 20 mS has not returned to safe level, the over-voltage protection will activate and turn off the output.

To re-enable the output, power must be cycled or the SWITCHER_EN pin (DIP pos. 7) must be pulled low at least 100 µS and then released.

Power supply requirement:

Voltage: 5Vdc ± 5%

Power: 10W peak

RS-232 Serial Ports

The Evaluation board for the Plug-In terminals has three RS-232 serial ports.

AT COMMAND PORT:

This port is available to send AT commands to GSM, CDMA, UMTS, EV-DO, and HSPA+ terminals. Please refer to the Terminus Plug-In User Guide for serial port details for the specific terminal you are evaluating.

Typical Port Settings:

Baud: 115200

Data bits: 8

Parity: None

Stop Bits: 1

Hardware Handshaking: CTS/RTS



TRACE PORT:

This port is used by the GSM865CF and HSPA910CF terminals and is used for debug and local firmware upgrades of the GSM modules radio firmware. This port is not needed for Python script upload, however, during development of Python scripts this port should be used to receive debug ‘print’ statements. Hardware handshaking is not available on this port.

Port Settings:

Baud: 115200

Data bits: 8

Parity: None

Stop Bits: 1

Hardware Handshaking: N/A

NAVSYNC MS20 GPS NMEA PORT:

This port is used exclusively by the GSM865CF terminal and is used to communicate with the MS20 GPS module. The MS20 GPS module is populated on the GSM865CF by option. Refer to Hardware User Guide for ordering information. Hardware handshaking is not available on this port.

Port Settings:

Baud: 9600

Data bits: 8

Parity: None

Stop Bits: 1


USB SERIAL PORTS:

The evaluation board for the Plug-In Terminus family allows access to virtual COM ports and modem ports via the USB. All of the Plug-In Terminus units support the USB interface except the GSM865CF. To use this interface during development you will need to download the USB drivers from the Janus website (www.janus-rc.com). Please note that in order for proper power on sequencing, the main power must be activated first. The USB VCC line must be disconnected until the device is on, otherwise it may not power up correctly or properly install the USB drivers.

CDMA864CF, EVDO910CF, CDMA910CF, UMTS864CF USB Ports

AUXILLARY PORT:

This port is available to send AT commands to GSM, CDMA and UMTS terminals. Please refer to the Plug-In User Guide for serial port details for the specific terminal you are evaluating.


Baud: 115200 Data bits: 8 Parity: None Stop Bits: 1 Hardware Handshaking: CTS/RTS

RS-232 SERIAL PORTS continued…



USB Serial Ports continued…

TRACE PORT:

This port is used for debug and local firmware upgrades of the cellular modules radio firmware. Hardware handshaking is not available on this port.

Port Settings:

Baud: 115200

Data bits: 8

Parity: None

Stop Bits: 1


TELIT GPS NMEA PORT:

This port is used to communicate with Telit’s integrated GPS hardware. Please refer to Telit AT command guide for available settings and features to implement this port in your hardware design. Hardware handshaking is not available on this port.

Port Settings:

Baud: 115200

Data bits: 8

Parity: None

Stop Bits: 1


HSPA910CF USB Ports

The HSPA910CF will show several virtual COM ports after the drivers are installed. These are USB0 through USB6, along with a modem for applications like Dial Up with Windows. This allows for applications like simultaneous AT commands, voice calls, and Python tracing.

These ports can be configured in various ways depending on the user’s application, but by default USB0 and USB3 are AT command ready after enumeration.


Baud: 115200 Data bits: 8 Parity: None Stop Bits: 1 Hardware Handshaking: N/A

You will want to reference HSPA910CF Ports Arrangements 4f.pdf for full details on using the AT#PORTCFG command.



EVALUATION KIT BOARD DETAILS

Telit Trace Port

AT Command Port

MS20 GPS NMEA Port

Dip Switches

General Purpose I/O Connections

Power IN (2.1mm barrel connector)

Power IN Terminal Block Connection

USB Port

MS20 Reset

Cellular Reset

Cellular ON-OFF

Handset Analog Audio

MCX Connector

SMA Connector

Plug-In Module Connector

J1 Jumper



GENERAL PURPOSE I/O:

The Evaluation board for the Plug-In series terminals expose the following I/O via terminal block wire connection.

CMOS GPIO 1 through 7

ADC 1 & 2

DAC 1

VAUX I/O Reference Voltage

Please refer to Hardware user guide before making connection to any of these I/Os. Each module has specific requirements for these I/O.

SWITCHES:

DIP SWITCHES:

The evaluation board has an 8 position DIP switch that allows selection of various modes of operation. Please refer to table below for definition of switch functions:

Name FunctionDescription ActivePositionMODE0 Disables the RS-232 Line Drivers. ON This allows for direct connection to CMOS UART I/O. Tri-States all Evaluation board I/Os directly connected to the Plug-In Terminus. This allows the module to be shutdown and not reverse bias the terminals I/O. MODE1 Cross connect of the TRACE and NAVSYNC_GPS signals for Null Modem configuration. ON This functionality is used specifically on the GSM865CF for the Python GPS Demo. MODE2 Not implemented N/AMODE3 Not implemented N/AMODE4 Not implemented N/ASERVICE For use with the GSM865CF N/A Enabling this switch allows local radio Firmware update via the Trace Serial Port.SWITCHER_EN Enable input of the Evaluation Board OFFENABLE Enable input of the Plug-In terminal OFF

All switches should be in the off position in order to turn-on Plug-In terminal and send AT commands via the RS-232 serial port.

PUSH BUTTON SWITCHES:

The evaluation board has three push buttons to control the state of the Plug-In terminal populated on the board.

GSM ON_OFF:

Used to toggle the on off state of the Plug-In terminal. On power up, the Evaluation PCB will toggle ON-OFF triggering the terminal to power up. To turn the terminal on or off, press the switch for two seconds and release.

GSM RESET:

Used to recover operation of Plug-In terminal in case of unexpected error resulting in the inability of the application to communicate with the terminal.

MS20 GPS RESET:

This switch is used exclusively by the GSM865CF terminal and is used to reset the GPS module in case of unexpected error resulting in the inability of the application to communicate with the GPS receiver.



RF CONNECTORS

The evaluation board comes equipped with RF connectors to interface Plug-In terminal with Cellular and GPS antennas. The Plug-In terminals have their RF connections exposed via Murata GSC connectors. The evaluation kits come with the terminals Cellular and GPS interfaces connected via a GSC-to-GSC RF patch cable to the Evaluation board.

SMA TO MURATA GSC CONNECTOR:

The SMA connector allows for a standard cellular antenna to be attached directly to the evaluation board.

MCX TO MURATA GSC CONNECTOR:

The MCX connector allows for a standard active GPS antenna to be attached directly to the evaluation board.

EVALUATION BOARD POWER JUMPER SELECTION

The power supply that supplies power to the evaluation boards active components can be selected from two different sources.

For ease of connection, the evaluation boards active components can be powered from the main power supply input. In this configuration it is not possible to evaluate the current consumption of the Plug-In Module without also including the active components of the evaluation board.

In order to evaluate the power consumption of the Plug-In modules without the added consumption of the evaluation boards active components, the evaluation board must be powered via the USB terminal.

J1 Jumper Selection:

ShuntLocation EvaluationBoardPowerSupplySourcePin1 <-> Pin 2 Evaluation Boards active components powered from main supply connector.Pin3 <-> Pin 2 Evaluation Boards active components powered from USB connector.

Note:

If the USB configuration is used, please note that only the evaluation board and a majority of it’s components will be powered by the USB. The attached CF module and evaluation board protection circuitry will not be and will still need to draw it’s power from the main “Power In” screw terminals or barrel jack. The protection circuitry will add a draw of roughly 1.5mA.

Also note that in order for proper power up operation, the USB power should be attached after the main supply is already attached and powered.

In order to take full advantage of the Pin 2-3 positioning for USB enabled Plug-In Terminus modems on the v3.xx evaluation boards, some minor hardware modifications need to be made. Please contact Janus for additional information.



GSM865CF GETTING STARTEDThis will take you through the initial steps required that will allow AT Commands to be sent to the GSM865CF Plug-In module.

Step 1Please confirm that you have these items, and that your Evaluation Board is correctly set:

Power supply with 2.1mm barrel connector termination 6’ RS232 cable USB to Serial adapter cable Jumper Shunt Cellular Antenna GSC to GSC patch cable(s)

Make sure that the DIP switches on the Evaluation Board are all set to OFF.

Step 2If not done already, plug the GSM865CF Plug-In Module into the connectors at the center of the Evaluation Board, being sure to align the pins properly. Take note that to make the alignment easier, the two connectors are of different lengths.

Step 3Cellular: Use one of the included GSC to GSC patch cables and attach one end to P5 on the GSM865CF and the other end to P15 of the evaluation board. Then attach the cellular antenna to the SMA edge mount connector of the evaluation board.

GPS (if applicable): Use one of the included GSC to GSC patch cables and attach one end to P4 on the GSM865CF and the other end to P15 on the evaluation board. Then attach the GPS antenna to the MCX edge mount connector of the evaluation board.

Step 4Connect the RS232 cable to the AT COMMAND port, labeled P8. Connect the other end to an available serial port on your PC, or an available USB port by use of the serial to USB adapter.

Step 5Place jumper shunt across Pin 1 and Pin 2 of Jumper J1.

Step 6Plug in your power supply to the 2.1mm barrel connector on the board, labeled P1. After roughly 2 seconds you should see the STATUS LED, labeled D7, start blinking. This lets you know that the Plug-In Module is powered and functioning.

Step 7Open HyperTerminal and start a new session. Use the drop down box to select the COM port that your serial cable is plugged into.



GSM865CF GETTING STARTED continued

Step 7 continuedThen select “Configure,” and select these settings:

Bits per second: 115200

Data bits: 8

Parity: None

Stop bits: 1

Flow control: Hardware

Then press “OK.”

Step 7Click on the “Call” button in HyperTerminal to make the connection. In the window you should now be able to send AT commands. To make sure you have a proper connection, type “AT” into the window, and press Enter. You should receive a response of “OK”.

If you do not receive that response, go back and check to make sure you’ve selected the correct COM port, as well as the settings.

If you receive an OK, your connection is successful and you are now able to communicate with the module. Please refer to http://www.janus-rc.com/terminuscf.html for a link to the proper Telit documentation.

The “Telit Module Software User Guide” will give step by step instructions on setting up voice and data calls, SMS messages, and socket connections.

The “Telit AT Reference Guide” is a full list of supported AT commands and their functions.



CDMA864CF GETTING STARTEDThis will take you through the initial steps required that will allow AT Commands to be sent to the CDMA864CF Plug-In module. This example uses the USB interface, but alternatively a serial connection to the AT Command DB9 for this may be faster and more suitable for you.


Power supply with 2.1mm barrel connector termination 3’ USB cable Jumper Shunt Cellular Antenna GSC to GSC patch cable


Step 2If not done already, plug the CDMA864CF Plug-In module into the connectors at the center of the Evaluation Board, being sure to align the pins properly. Take note that to make the alignment easier, the two connectors are of different lengths.

Step 3Cellular: The CDMA864CF has a short cable with a SMA end; simply attach the cellular antenna to the end of that cable.

GPS (if applicable): Use one of the included GSC to GSC patch cables and attach one end to the top GSC connector on the CC864-D module, and the other end to P15 on the evaluation board. Then attach the GPS antenna to the MCX edge mount connector of the evaluation board.


Step 5Plug in your power supply to the 2.1mm barrel connector on the board, labeled P1. After roughly 2 seconds you should see the STATUS LED, labeled D7, start blinking. This lets you know that the Plug-In module is powered and functioning.

Step 6Connect the USB cable to the USB port on the Evaluation Board. Connect the other end to an available USB port on your PC.



Step 7 You should see the following ports in the Windows™ Device Manager:

Telit Auxiliary Port Telit Diagnostics Interface Telit NMEA Port

If these do not become available, or you see an error message, this means you need to install the USB drivers for the CDMA864CF. Please refer to http://www.janus-rc.com/terminuscf.html for the proper drivers before continuing.

Step 8Open HyperTerminal or a similar terminal emulator and start a new session. Use the drop down box to select the COM port that corresponds to the Telit Auxiliary Port.

Then select “Configure,” and select these settings:

Bits per second: 115200Data bits: 8

Parity: None

Stop bits: 1








CDMA864CF GETTING STARTED continued



UMTS864CF GETTING STARTEDThis will take you through the initial steps required that will allow AT Commands to be sent to the UMTS864CF Plug-In module. This example uses the USB interface, but alternatively a serial connection to the AT Command DB9 for this may be faster and more suitable for you.


Power supply with 2.1mm barrel connector termination 3’ USB cable Jumper Shunt Cellular Antenna GSC to GSC patch cable(s)


Step 2If not done already, plug the UMTS864CF Plug-In module into the connectors at the center of the Evaluation Board, being sure to align the pins properly. Take note that to make the alignment easier, the two connectors are of different lengths.

Step 3Cellular: The UMTS864CF has a short cable with a SMA end; simply attach the cellular antenna to the end of that cable.

GPS (if applicable): Use one of the included GSC to GSC patch cables and attach one end to the top GSC connector on the UC864-G module, and the other end to P15 on the evaluation board. Then attach the GPS antenna to the MCX edge mount connector of the evaluation board.






UMTS864CF GETTING STARTED continued



If these do not become available, or you see an error message, this means you need to install the USB drivers for the UMTS864CF. Please refer to http://www.janus-rc.com/terminuscf.html for the proper drivers before continuing.




Data bits: 8

Parity: None

Stop bits: 1










HSPA910CF GETTING STARTEDThis will take you through the initial steps required that will allow AT Commands to be sent to the HSPA910CF Plug-In module. This example uses the USB interface, but alternatively a serial connection to the AT Command DB9 for this may be faster and more suitable for you.




Step 2If not done already, plug the HSPA910CF Plug-In module into the connectors at the center of the Evaluation Board, being sure to align the pins properly. Take note that to make the alignment easier, the two connectors are of different lengths.

Step 3Cellular: Use one of the included GSC to GSC patch cables and attach one end to P5 on the HSPA910CF and the other end to P14 of the evaluation board. Then attach the cellular antenna to the SMA edge mount connector of the evaluation board.

GPS: Use one of the included GSC to GSC patch cables and attach one end to P6 on the HSPA910CF and the other end to P14 on the evaluation board. Then attach the GPS antenna to the MCX edge mount connector of the evaluation board.






HSPA9104CF GETTING STARTED continued


USB1 USB2 USB3 USB4 USB5 USB6

If these do not become available, or you see an error message, this means you need to install the USB drivers for the HSPA910CF. Please refer to http://www.janus-rc.com/terminuscf.html for the proper drivers before continuing.

Step 8Open HyperTerminal or a similar terminal emulator and start a new session. Use the drop down box to select the COM port that corresponds to the USB3.



Data bits: 8

Parity: None

Stop bits: 1










EVDO910CF GETTING STARTEDThis will take you through the initial steps required that will allow AT Commands to be sent to the EVDO910CF Plug-In Module. This example uses the USB interface, but alternatively a serial connection to the AT Command DB9 for this may be faster and more suitable for you.




Step 2If not done already, plug the EVDO910CF Plug-In Module into the connectors at the center of the Evaluation Board, being sure to align the pins properly. Take note that to make the alignment easier, the two connectors are of different lengths.

Step 3Cellular: Use one of the included GSC to GSC patch cables and attach one end to P5 on the EVDO910CF and the other end to P15 of the evaluation board. Then attach the cellular antenna to the SMA edge mount connector of the evaluation board.

GPS: Use one of the included GSC to GSC patch cables and attach one end to P6 on the EVDO910CF and the other end to P15 on the evaluation board. Then attach the GPS antenna to the MCX edge mount connector of the evaluation board. .






EVDO910CF GETTING STARTED continued



If these do not become available, or you see an error message, this means you need to install the USB drivers for the EVDO910CF. Please refer to http://www.janus-rc.com/terminuscf.html for the proper drivers before continuing.




Data bits: 8

Parity: None

Stop bits: 1










APPENDIX

SCHEMATICS:

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APPENDIX — SCHEMATICS continued:

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_RX

EN

AB

LE

GP

S_T

XG

PS

_RX

MO

DE

1M

OD

E2

MO

DE

3M

OD

E4

SW

ITC

HE

R_E

NA

BLE

MO

DE

0M

OD

E1

MO

DE

2M

OD

E3

MO

DE

4

GS

M_R

XG

SM

_DS

RG

SM

_CT

SG

SM

_RIN

GG

SM

_DC

DG

SM

_TX

GS

M_D

TR

GS

M_R

TS

MO

DE

0

SE

RV

ICE

_IN

VR

TC

GP

S_T

XG

PS

_RX

US

B_V

BU

S

I2C

_S

CL

I2C

_S

DA

US

B_D

+

AD

C1

AD

C2

DA

CG

PIO

1

GP

S_R

ES

ET

GP

IO2

GP

IO3

VA

UX

GP

IO4

GP

IO5

US

B_D

-

GP

IO6

GP

IO7

US

B_I

D

EA

R+

EA

R-

MIC

-

GP

S_L

ED

PW

RM

ON

MIC

+G

SM

_RE

SE

T

SE

RV

ICE

ON

_OF

F

GS

M_L

ED

GS

M_R

XG

SM

_DS

RG

SM

_CT

SG

SM

_RIN

GG

SM

_DC

D

EN

AB

LE

GS

M_T

XG

SM

_DT

RG

SM

_RT

S

TR

AC

E_T

XT

RA

CE

_RX

TR

AC

E_T

XT

RA

CE

_RX

DA

CD

AC

_F

ILT

ER

ED

DA

C_

FIL

TE

RE

D

VR

TC

GP

S_T

XG

PS

_RX

US

B_V

BU

S

I2C

_SC

LI2

C_S

DA

US

B_D

+

AD

C1

AD

C2

DA

CG

PIO

1

GP

S_R

ES

ET

GP

IO2

GP

IO3

VA

UX

GP

IO4

GP

IO5

US

B_D

-

GP

IO6

GP

IO7

US

B_I

D

EA

R+

EA

R-

MIC

-

GP

S_L

ED

PW

RM

ON

MIC

+G

SM

_RE

SE

T

SE

RV

ICE

ON

_OF

F

GS

M_L

ED

GS

M_R

XG

SM

_DS

RG

SM

_CT

SG

SM

_RIN

GG

SM

_DC

D

EN

AB

LE

GS

M_T

XG

SM

_DT

RG

SM

_RT

S

TR

AC

E_T

XT

RA

CE

_RX

EN

AB

LE

GP

S_L

ED

PW

RM

ON

GS

M_R

ES

ET

SE

RV

ICE

_IN

ON

_OF

F

GS

M_L

ED

MO

DE

0

GP

IO1

GP

IO2

GP

IO3

GP

IO4

GP

S_R

ES

ET

GP

IO5

GP

IO6

GP

IO7

VR

TC

VAUX

SE

RV

ICE

_IN

SE

RV

ICE

VC

C_

IN

VC

C_

IN

5V_I

N

VC

C_I

N

VC

C_I

N

VC

C1.

8

VC

C3.

3

VC

C3.

3 VC

C3.

3

5V_

IN

5V_

IN

VB

AN

K1

VA

UX

MIC

+

PW

RM

ON

US

B_D

-U

SB

_D+

US

B_V

BU

SU

SB

_ID

EA

R-

EA

R+

MIC

-

nFO

RC

EO

FF

_LD

0F

OR

CE

ON

_LD

0nF

OR

CE

OF

F_

LD1

FO

RC

EO

N_L

D1

TR

AC

E_L

D_T

XG

PS

_LD

_TX

TR

AC

E_L

D_R

XG

PS

_LD

_RX

GS

M_L

D_R

TS

GS

M_L

D_D

TR

GS

M_L

D_T

XG

SM

_LD

_DC

DG

SM

_LD

_RIN

GG

SM

_LD

_CT

SG

SM

_LD

_DS

RG

SM

_LD

_RX

SW

ITC

HE

R_E

NA

BLE

MO

DE

0

PW

RM

ON

SE

RV

ICE

_IN

GS

M_R

ES

ET

ON

_OF

F

EN

AB

LE

GP

S_R

ES

ET

GS

M_L

ED

GP

IO1

GP

S_L

ED

GP

IO3

GP

IO2

GP

IO5

GP

IO4

GP

IO7

GP

IO6

On power-up or assertion of MR,

RESET will be pulled low for

approximately 2 seconds.

U6 Notes:

Allows direct solder connection of GSM865CF, CDMA864CF & UMTS864CF

Samtec Headers SLW-125-01-G-S &

SLW-124-01-G-S can be soldered in to allow removable module functionality.

SWITCH DEFINITION:

POS1 -> MODE0

POS2 -> MODE1

POS3 -> MODE2

POS4 -> MODE3

POS5 -> MODE4

POS6 -> SERVICE ACTIVE

POS7 -> DISABLE DEV. PCB POWER SUPPLY

POS8 -> DISABLE TERMINUS

Silk Screen Name:

Silk Screen Name:

Silk Screen Name:

ON_OFF

GPS RESET

CELLULAR RESET

AUTOMATION CONNECTIONS

Added 4/09/10

SERVICE_IN controls SERVICE

Header Notes:

SIP Headers can be populated in place of the ZIF sockets to

allow for an extra plug in option. Silk screen addition in

the P18 and P19 footprint should be added to show where

these SIPs will go. The silk screen should look how P3 and

P4 do.

R18

680

R-6

45-G

P19

1x24

ZIF

Soc

ket,

0.1"

(3M

: 224

-580

9-00

-060

2)O

MIT

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24

P6

1x25

HE

AD

ER

, 0.

1" x

0.1

" (S

LW-1

25-0

1-G

-S)

XT

-431

-G

C20

0.33

uF

C-6

67-G

10V

C53

0.1

uFC

-561

-G16

V

C21

0.01

uF

C-5

22-G

50V

R17

680

R-6

45-G

R38

13

.7k,

1%

OM

IT

R37

0 oh

mR

-606

-G

P3

1x25

HE

AD

ER

(0.

1" x

0.1

")O

MIT

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25

ON

2 3 4 5 6 7 81

SW

18

posi

tion

DIP

sw

itch,

SP

ST

, G

old

Fin

ish

(CT

2068

)X

T-43

0

R26

12.

1KR

-391

P14

RF

- G

SC

Con

nect

or (

MM

9329

-270

0RA

1)X

T-3

93-G

1

2

D5

SP

0505

BA

JTS

-273

5

6

1

3

2

4

C2

50.

01 u

FC

-522

-G50

V

C2

40.

01 u

FC

-522

-G50

V

D6

GR

EE

NS

-213 1

2

C54

0.1

uFC

-561

-G16

V

D4

SP

0505

BA

JTS

-273

5

6

1

3

2

4

C22

1 u

FC

-562

-G6

.3V

JTAG

U7D

XC

2C64

A-7

QF

G48

IK

-605

-M3-

G

TC

K23

TD

I21

TD

O40

TM

S22

P15

RF

- G

SC

Con

nect

or (

MM

9329

-270

0RA

1)X

T-3

93-G

1

2

I/O BANK2

U7B

XC

2C64

A-7

QF

G48

IK

-605

-M3-

G GP

IO_2

05

GP

IO_2

14

(GT

S1)

GP

IO_2

22

(GT

S0)

GP

IO_2

31

(GT

S3)

GP

IO_2

448

(GT

S2)

GP

IO_2

547

(GS

R)G

PIO

_26

46

GP

IO_2

745

GP

IO_2

844

GP

IO_2

943

GP

IO_3

039

GP

IO_3

138

GP

IO_3

237

GP

IO_3

336

GP

IO_3

435

GP

IO_3

534

GP

IO_3

633

GP

IO_3

732

Vcc

io2

42

P7

1x2

4 H

EA

DE

R,

0.1"

x 0

.1"

(SLW

-124

-01-

G-S

)X

T-4

32-G

SW

3G

SR

6.34

F13

0QP

S-5

80-G

3

4

21

P21

CO

N3

(171

6030

000)

XT

-454

-G1 2 3

C55

0.1

uFC

-561

-G16

V

C27

1 u

FC

-562

-G6

.3V

10k

47k

47k

10k

Q4

PE

MH

15S

-560

-G1 2 3

6 5 4

P18

1x32

ZIF

Soc

ket,

0.1"

(3M

: 232

-260

1-00

-060

2)O

MIT

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32

R15

100

K,

1%R

-675

-G

P.S.

U7C

XC

2C64

A-7

QF

G48

IK

-605

-M3-

G

Vcc

29

Vcc

aux

3

GN

D16

GN

D31

GN

D41

U6

Janu

s C

omm

on F

ootp

rint

Ter

min

alO

MIT

VC

C1

VC

C2

EN

AB

LE3

RX

D4

DS

R5

CT

S6

RIN

G7

DC

D8

TX

D9

DT

R10

RT

S11

GN

D12

TR

AC

E_T

X13

TR

AC

E_R

X14

GP

S_L

ED

15

GS

M_L

ED

16

SE

RV

ICE

17

PW

RM

ON

18

ON

_OF

F19

RE

SE

T20

MIC

+21

EA

R+

23

EA

R-

24

MIC

-22

GN

D49

VA

UX

48

VR

TC

47

AD

C1

46

AD

C2

45

DA

C44

GP

IO1

43

GP

IO2

42

GP

IO3

41

GP

IO4

40

GN

D39

GP

IO5

38

GP

IO6

37

GP

IO7

36

GP

S_R

ES

ET

35

GP

S_T

X34

GP

S_R

X33

I2C

_SC

L32

I2C

_SD

A31

US

B_I

D30

US

B_V

BU

S29

US

B_D

+28

US

B_D

-27

GN

D26

GN

D25

P16

RF

- S

MA

Con

nect

or (

SM

A-J

-P-H

-ST

-EM

1)X

T-4

36-G

1

2

C26

1 u

FC

-562

-G6.

3V

U8

Sup

ervi

sor

(TP

S38

08G

01)

K-5

83-M

1-G

RE

SE

T1

GN

D2

MR

3

CT

4S

EN

SE

5V

DD

6

R24

12.

1KR

-391

C23

1 u

FC

-562

-G6

.3V

P2

CO

N12

YT

-346

1 2 3 4 5 6 7 8 9 10 11 12

D7

YE

LL

OW

S-2

14

12

C18

1 u

FC

-562

-G6.

3V

SW

4G

SR

6.34

F13

0QP

S-5

80-G

3

4

21

C1

90.

01 u

FC

-522

-G50

V

R16

13

.7k,

1%

R-6

86

D3

SP

0505

BA

JTS

-273

5

6

1

3

2

4

P17

RF

- M

CX

Con

nect

or (

MC

X-J

-P-H

-ST

-EM

1)X

T-4

37-G

1

2

I/O BANK1

U7A

XC

2C64

A-7

QF

G48

IK

-605

-M3-

G

Vcc

io1

19

GP

IO_0

16

GP

IO_0

27

GP

IO_0

38

GP

IO_0

49

GP

IO_0

510

(GC

K0)

GP

IO_0

611

(GC

K1)

GP

IO_0

712

(GC

K2)

GP

IO_0

813

GP

IO_0

914

GP

IO_1

015

GP

IO_1

117

GP

IO_1

218

GP

IO_1

320

GP

IO_1

424

GP

IO_1

525

GP

IO_1

626

GP

IO_1

727

GP

IO_1

828

GP

IO_1

930

P5

1x6

HE

AD

ER

(0.

1" x

0.1

")X

T-2

45-G

Vcc

1

GN

D2

TC

K3

TD

O4

TD

I5

TM

S6

SW

2G

SR

6.34

F13

0QP

S-5

80-G

3

4

21

P4

1x24

HE

AD

ER

(0.1

" x

0.1"

)O

MIT

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24

R25

12.1

KR

-391




Figure 3: RS-232

DB

9_R

X0

DB

9_T

X0

DB

9_R

I0

DB

9_D

SR

0D

B9_

CT

S0

DB

9_C

D0

DB

9_R

TS

0D

B9_

DT

R0

DB

9_R

X1

DB

9_T

X1

DB

9_R

X2

DB

9_T

X2

DB

9_R

TS

0

DB

9_C

TS

0

DB

9_R

X0

DB

9_T

X0

DB

9_D

SR

0

DB

9_R

I0

DB

9_C

D0

DB

9_D

TR

0

DB

9_R

X1

DB

9_T

X1

DB

9_R

X2

DB

9_T

X2

VC

C3.

3

VC

C3.

3

GS

M_L

D_T

XG

SM

_LD

_DT

RG

SM

_LD

_RT

S

TR

AC

E_L

D_R

XG

PS

_LD

_RX

GS

M_L

D_R

XG

SM

_LD

_DS

RG

SM

_LD

_CT

SG

SM

_LD

_RIN

GG

SM

_LD

_DC

D

nFO

RC

EO

FF

_LD

0F

OR

CE

ON

_LD

0

TR

AC

E_L

D_T

XG

PS

_LD

_TX

nFO

RC

EO

FF

_LD

1F

OR

CE

ON

_LD

1

AT COMMAND PORT

GSM TRACE PORT

GPS NMEA PORT

C37

1 uF

C-5

62-G

6.3V

C34

1 uF

C-5

62-G

6.3V

P9

DB

9-S

MT

XT

-337

-G

59

48

37

26

1

10 11

P8

DB

9-S

MT

XT

-337

-G

59

48

37

26

1

10 11

C31

1 uF

C-5

62-G

6.3V

C33

0.2

2 uF

C-5

59-G

16V

CMOS

RS-232

U9A

MA

X32

38K

-460

-G

DIN

124

DIN

223

DIN

322

DIN

419

DIN

517

RO

UT

121

RO

UT

220

RO

UT

318

FO

RC

EO

FF

14

FO

RC

EO

N13

INV

ALI

D15

DO

UT

15

DO

UT

26

DO

UT

37

DO

UT

410

DO

UT

512

RIN

18

RIN

29

RIN

311

RO

UT

116

C32

1 uF

C-5

62-G

6.3V

U9B

MA

X32

38K

-460

-G

VC

C26

V+

27

V-

4

GN

D2

C1+

28

C1-

25

C2+

1

C2-

3

C35

1 uF

C-5

62-G

6.3

V

C29

1 uF

C-5

62-G

6.3V

C28

0.2

2 uF

C-5

59-G

16V

C36

1 uF

C-5

62-G

6.3V

U10

BM

AX

3238

K-4

60-G

VC

C26

V+

27

V-

4

GN

D2

C1+

28

C1-

25

C2+

1

C2-

3

CMOS

RS-232

U10

AM

AX

3238

K-4

60-G

DIN

124

DIN

223

DIN

322

DIN

419

DIN

517

RO

UT

121

RO

UT

220

RO

UT

318

FO

RC

EO

FF

14

FO

RC

EO

N13

INV

ALI

D15

DO

UT

15

DO

UT

26

DO

UT

37

DO

UT

410

DO

UT

512

RIN

18

RIN

29

RIN

311

RO

UT

116

P10

DB

9-S

MT

XT

-337

-G

59

48

37

26

1

10 11

C30

1 uF

C-5

62-G

6.3

V




Figure 4: Handset Analog Audio

*EA

R+

*MIC

+

*MIC

-

*EA

R-

VM

IC

EA

R-

EA

R+

MIC

-

MIC

+

R20

22K

, 5%

R-6

61G

C48

1nF

C-6

96

C51

1nF

C-6

96

C46

0.1

uF

C-6

68-G

16V

C42

1nF

C-6

96

C40

2.2

uFC

-686

6.3

V

C45

1nF

C-6

96

C47

39pF

C-6

5650

V

C50

39pF

C-6

5650

V

C39

0.1

uF

C-6

68-G

16V

C41

39pF

C-6

5650

V

R21

1k, 5

%R

-615

-GC44

39pF

C-6

5650

V

P11

4P4C

_RA

_JA

CK

XT-

464-

G

1234

C43

0.1

uF

C-6

68-G

16V

L4 39uH

L-27

5-G

R19

1k, 5

%R

-615

-G

L2 39uH

L-27

5-G

L3 39uH

L-27

5-G

C49

0.1

uF

C-6

68-G

16V

L1 39uH

L-27

5-G

Q5

MM

BT

3904

S-2

57-G




Figure 5: USB Port

US

B_

D-

US

B_D

+

US

B_V

BU

S

US

B_I

D

U11

ES

D A

RR

AY

(R

CLA

MP

0504

F.T

CT

)S

-574

-G1

2

6

5

4 3

C52

10uF

, 20

%C

-726

-G25

V

P12

US

B-T

YP

E B

SO

CK

ET

(U

SB

-B-S

-F-B

-TH

)X

T-42

1-G

1 2 3 456

P13

1x5

HE

AD

ER

(0.

1" x

0.1

")O

MIT1

2345

R22

27,

5%R

-658

-G

R23

27,

5%R

-658

-G

t

RT

1P

TC

200

mA

(08

05L0

20Y

R)

S-2

97-G

12




Figure 6: Factory Automation (not populated)

PA

5P

A3

PA

1P

A0

PA

2P

A4

PB

0P

B2

PB

1

PC

0P

C2

PC

4P

C5

PC

3P

C1

PC

6

PC

2P

C1

PC

4P

C3

PA

2P

A3

PA

4P

A5

PC

6P

C5

PB

1P

B0

PC

0P

B2

PA

0P

A1

VC

C_5

PC

VA

UX

VC

C_5

PC

VA

UX

VC

C_5

PC

VA

UX

VA

UX

VC

C_5

PC

VA

UX

VC

C_5

PC

VC

C_5

PC

VC

C_5

PC

VC

C_5

PC

VC

C_5

PC

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Revision RevisionDate NoteA00 05/15/10 Preliminary ReleaseA01 06/28/10 Updates to Eval Board Descriptions & SpecsP00 01/17/12 Updated Power Supply Interfaces, Schematic, DIP Switches. Moved to Preliminary StatusP01 04/05/12 Added HSPA910CF Description and SpecsP02 11/15/12 Added EVDO910CF Description and SpecsP03 07/10/13 New Board Photo UpdateP04 08/26/13 Updated Page 14 information - P15 should be P14 & Legal Statement

Terminus Plug-In Modules Evaluation Kit User Guide

JanusRemoteCommunicationsEuropeBay 143

Shannon Industrial Estate Shannon, Co. Clare, Ireland

Phone: +353 61 475 666

Division of The Connor-Winfield Corporation2111 Comprehensive Drive • Aurora, Illinois 60505

630.499.2121 • Fax: 630.851.5040

www.janus-rc.com

evaluation kit user guide - janus rc

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