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Texas Instruments TSC2017EVM and TSC2017EVM-PDK (Rev. A) User guides
User's Guide
SLAU305A – January 2010 – Revised June 2010
TSC2017EVM and TSC2017EVM-PDK
This user's guide describes the characteristics, operation, and use of the TSC2017EVM, both by itself and
as part of the TSC2017EVM-PDK. This evaluation module (EVM) is a four-wire resistive touch screen
controller EVM which also has auxiliary input and temperature-measuring capabilities. A complete circuit
description, schematic diagram, and bill of materials are included.
The following related documents are available through the Texas Instruments Web site at www.ti.com.
EVM-Compatible Device Data Sheets
1
2
3
4
5
6
7
8
Device
Literature Number
TSC2017
SBAS472
TAS1020B
SLES025
REG1117-5
SBVS001
TPS767D318
SLVS209
SN74LVC125A
SCAS290
SN74LVC1G125
SCES223
SN74LVC1G07
SCES296
Contents
EVM Overview ............................................................................................................... 2
1.1
Features ............................................................................................................. 2
1.2
Introduction ......................................................................................................... 2
Analog Interface ............................................................................................................. 3
Digital Interface .............................................................................................................. 3
Power Supplies .............................................................................................................. 4
4.1
TSC Power .......................................................................................................... 4
4.2
Standalone Operation ............................................................................................. 4
4.3
USB-MODEVM Interface Power ................................................................................. 4
EVM Operation .............................................................................................................. 5
5.1
Analog Input ........................................................................................................ 5
5.2
Digital Control ...................................................................................................... 5
5.3
Default Jumper Locations ......................................................................................... 5
EVM-PDK Operation ........................................................................................................ 5
6.1
TSC2017EVM-PDK Setup ........................................................................................ 5
6.2
Quick Start .......................................................................................................... 8
6.3
GUI and Operation Description .................................................................................. 9
6.4
Datalogging ........................................................................................................ 11
EVM Bill of Materials ...................................................................................................... 12
7.1
TSC2017 Top Silk Screen ....................................................................................... 14
Schematics ................................................................................................................. 14
8.1
TSC2017EVM Schematic ....................................................................................... 14
8.2
USB-MODEVM Schematic ...................................................................................... 14
List of Figures
Microsoft, Windows are registered trademarks of Microsoft Corporation.
I2C is a trademark of NXP Semiconductors.
NI Speedy-33 is a trademark of National Instruments Corporation.
All other trademarks are the property of their respective owners.
SLAU305A – January 2010 – Revised June 2010
TSC2017EVM and TSC2017EVM-PDK
Copyright © 2010, Texas Instruments Incorporated
1
EVM Overview
www.ti.com
1
TSC2017EVM-PDK Hardware Block Diagram and Connection ...................................................... 6
2
TSC2017EVM-PDK Software GUI Screen
3
Four Main Sections in TSC2017EVM-PDK GUI Screen ............................................................. 10
1
Analog Interface Pinout .................................................................................................... 3
2
Digital Interface Pinout ..................................................................................................... 3
3
Power Supply Pinout ....................................................................................................... 4
4
Power Selection Options: JP1 ............................................................................................. 4
5
List of Jumpers .............................................................................................................. 5
6
USB-MODEVM Switches and Jumpers Default Position .............................................................. 7
7
TSC2017EVM Bill of Materials
8
USB-MODEVM Bill of Materials
..............................................................................
8
List of Tables
1
EVM Overview
1.1
Features
•
•
..........................................................................................
........................................................................................
12
13
Full-featured evaluation board for the TSC2017 four-wire resistive touch screen controller (TSC).
Modular design for use with a variety of DSP and microcontroller interface boards.
The TSC2017EVM-PDK is a complete evaluation kit, which includes a USB-based motherboard and
evaluation software for use with a personal computer running Microsoft® Windows® operating systems.
1.2
Introduction
The TSC2017EVM is designed in the Texas Instruments modular EVM form factor, which allows direct
evaluation of the performance and operating characteristics of the TSC2017 and eases software
development and system prototyping. This EVM is compatible with the 5-6K Interface Board (SLAU104)
from Texas Instruments and additional third-party boards such as the NI Speedy-33™ from National
Instruments Corporation.
The TSC2017EVM-PDK is a complete evaluation/demonstration kit, which includes a USB-based
motherboard called the USB-MODEVM interface board and evaluation software for use with a personal
computer running Microsoft Windows operating systems. The TSC2017EVM-PDK is a package that
includes (1) a TSC2017EVM printed circuit board (PCB); (2) a USB-MODEVM PCB; and (3) a CD-ROM
with an evaluation software installer and related documentation.
2
TSC2017EVM and TSC2017EVM-PDK
SLAU305A – January 2010 – Revised June 2010
Copyright © 2010, Texas Instruments Incorporated
Analog Interface
www.ti.com
2
Analog Interface
For maximum flexibility, the TSC2017EVM is designed for easy interfacing to multiple analog sources.
Samtec part numbers SSW-110-22-F-D-VS-K and TSM-110-01-T-DV-P provide a convenient 10-pin,
dual-row header/socket combination at J1. This header/socket provides access to the analog input pins of
the TSC. Consult Samtec at www.samtec.com, or call 1-800-SAMTEC-9 for a variety of mating connector
options. Table 1 summarizes the pinouts for the analog interface pinout J1.
Table 1. Analog Interface Pinout
3
Pin Number
Signal
J1.2
X+
Touch screen X+ electrode
J1.4
X–
Touch screen X– electrode
J1.6
Y+
Touch screen Y+ electrode
J1.8
Y–
Touch screen Y– electrode
Auxiliary input, 0 V to VREF
J1.12
AUX
J1.10, J1.14-J1.20 (even)
Unused
J1.1-J1.7 (odd), J1.15
Unused
J1.9-J1-13 (odd) , J1.17, J1.19
AGND
Description
Analog ground
Digital Interface
The TSC2017EVM is designed to easily interface with multiple control platforms. Samtec part numbers
SSW-110-22-F-D-VS-K and TSM-110-01-T-DV-P provide a convenient 10-pin, dual-row header/socket
combination at J2. This header/socket provides access to the digital control and serial data pins of the
TSC. Consult Samtec at www.samtec.com or call 1-800-SAMTEC-9 for a variety of mating connector
options. Table 2 describes the digital interface pinout.
Table 2. Digital Interface Pinout
Pin Number
Signal
J2.12
RESET
Hardware reset, input to TSC, active low
J2.15
PENIRQ
PENIRQ Pen interrupt output from TSC,
active low
J2.16
SCL
I2C™ bus serial clock
J2.20
SDA
I2C bus serial data line
J2.4, J2.10, J2-18
DGND
J2.1-J2.13 (odd), J2.17, J2.19
Unused
J2.2, J2.6, J2.8, J2.14
Unused
SLAU305A – January 2010 – Revised June 2010
Description
Digital ground
TSC2017EVM and TSC2017EVM-PDK
Copyright © 2010, Texas Instruments Incorporated
3
Power Supplies
4
www.ti.com
Power Supplies
J3 provides connection to the common power bus for the TSC2017EVM. Power is supplied on the pins
listed in Table 3.
Table 3. Power Supply Pinout
Signal
Pin Number
Signal
Unused
1
2
Unused
Unused
3
4
Unused
DGND
5
6
AGND
+1.8VD
7
8
Unused
+3.3VD
9
10
Unused
When power is supplied to J3, JP1 allows for one of two different dc voltages to be selected as the power
source for the TSC. See the schematic and PCB silkscreen for details.
The TSC2017EVM-PDK motherboard (the USB-MODEVM interface board) supplies power to J3 of the
TSC2017EVM. Power for the motherboard is supplied either through its USB connection or via terminal
blocks on the board.
4.1
TSC Power
Power for the TSC2017 VDD can be supplied either from the +1.8-VD terminal or from the +3.3-VD
terminal.
JP1 selects the voltage that is routed to the TSC2017. When JP1 is in the default factory condition (shunt
on pins 1-2), power to the TSC comes from J3.9 (+3.3 VD). When the shunt is installed on JP1 pins 2-3,
power comes from J3.7 (+1.8 VD). Removing the shunt on JP1, the user can connect any dc power
supply between 1.6 VD and 3.6 VD to VCC by connecting the power to JP1 pin 2.
Table 4. Power Selection Options: JP1
4.2
Shunt on Pins
VDD
Voltage from J3 Pin
1-2
+3.3 VD
9
2-3
+1.8 VD
7
Removed
+1.6 VD to +3.6 VD
External
Standalone Operation
When used as a standalone EVM, power can be applied to TP1 (VCC), referenced to TP3 (AGND).
CAUTION
Verify that all power supplies are within the safe operating limits shown on the
TSC2017 data sheet (SBAS472) before applying power to the EVM.
4.3
USB-MODEVM Interface Power
The USB-MODEVM interface board can be powered from several different sources:
• USB
• 6-VDC to 10-VDC ac/dc external wall supply (not included)
• Laboratory power supply
When powered from the USB connection, JMP6 must have a shunt from pins 1-2 (this is the default
factory configuration). When powered from 6 VDC to 10 VDC, either through the J8 terminal block or J9
barrel jack, JMP6 must have a shunt installed on pins 2-3. If power is applied in any of these ways,
onboard regulators generate the required supply voltages, and no further power supplies are necessary.
4
TSC2017EVM and TSC2017EVM-PDK
SLAU305A – January 2010 – Revised June 2010
Copyright © 2010, Texas Instruments Incorporated
EVM Operation
www.ti.com
If laboratory supplies are used to provide the individual voltages required by the USB-MODEVM interface
board, JMP6 must have no shunt installed. Voltages then are applied to J2 (+5 VA), J3 (+5 VD), J4 (+1.8
VD), and J5 (+3.3 VD). The +1.8 VD and +3.3 VD also can be generated by the onboard regulators from
the +5-VD supply; to enable this supply, the switches on SW1 must be set to enable the regulators by
placing them in the ON position (lower position, looking at the board with text reading right side up). If +1.8
VD and +3.3 VD are supplied externally, disable the onboard regulators by placing SW1 switches in the
OFF position.
Each power supply voltage has an LED (D1-D7) that lights when the power supplies are active.
5
EVM Operation
This section provides information on the analog input, digital control, and general operating conditions of
the TSC2017EVM.
5.1
Analog Input
The analog input sources (touch screen and auxiliary input) can be applied directly to J1 (top or bottom
side) or through signal-conditioning modules available for the modular EVM system.
5.2
Digital Control
The digital control signals can be applied directly to J2 (top or bottom side). The modular TSC2017EVM
also can be connected directly to a DSP or microcontroller interface board, such as the USB-MODEVM
interface board if purchased as part of the TSC2017EVM-PDK. See the device product folder for the
TSC2017 for a current list of compatible interface and/or accessory boards.
5.3
Default Jumper Locations
Table 5 provides a list of jumpers found on the EVM and the resepctive factory default conditions.
Table 5. List of Jumpers
6
Jumper
Shunt Position
JP1
1-2
Jumper Description
JP2
Closed
EEPROM address select. When installed and used with the USB-MODEVM, firmware for the
motherboard is executed from the EEPROM on the TSC2017EVM. This is the default mode.
JP3
Closed
TSC2017 I2S slave address A0 bit (default is 1001000b)
Analog power select (default is +3.3 VD)
EVM-PDK Operation
This section provides information on operating the TSC2017EVM-PDK, including setup, program
installation, and the GUI and its operation description.
6.1
6.1.1
TSC2017EVM-PDK Setup
Hardware Setup
A TSC2017EVM-PDK includes three components: (1) the TSC2017EVM circuit board; (2) the
USB-MODEVM circuit board; and (3) a CDROM with TSC2017EVM-PDK installer and related
documentation.
SLAU305A – January 2010 – Revised June 2010
TSC2017EVM and TSC2017EVM-PDK
Copyright © 2010, Texas Instruments Incorporated
5
EVM-PDK Operation
www.ti.com
The hardware block diagram of the TSC2017EVM-PDK is shown in Figure 1, where two circuit boards,
TSC2017EVM and USB-MODEVM, are connected. The motherboard is designated as the USB-MODEVM
interface board; the daughtercard is the TSC2017EVM described previously in this document. The
TSC2017EVM board is plugged on top of the USB-MODEVM board.
TSC2017EVM
J1
J2
RESET
X+/X-/Y+/Y-
PENIRQ
TSC2017
SCL
AUX
SDA
J3
EEPROM
USB-MODEVM
USB J7
TAS1020B
J11
J12
Control Interface
J13
2
(SPI, I C)
J16
J17
J18
Figure 1. TSC2017EVM-PDK Hardware Block Diagram and Connection
The simple diagram in Figure 1 shows only the basic features of the USB-MODEVM interface board. The
board is built around a TAS1020B streaming audio USB controller with an 8051-based core. The board
features two positions for modular EVMs, or one double-wide serial modular EVM may be installed.
For use with the TSC2017, the TSC2017EVM is installed in the topmost EVM slot, which connects the
TSC2017 digital control interface to the I2C port, realized using the TAS1020B. Because the TSC2017 has
no audio features, the lower EVM slot, which is connected to the TAS1020B digital audio interface, is not
used.
6
TSC2017EVM and TSC2017EVM-PDK
SLAU305A – January 2010 – Revised June 2010
Copyright © 2010, Texas Instruments Incorporated
EVM-PDK Operation
www.ti.com
As configured at the factory (shown in Table 6), the board is ready to use with the TSC2017EVM.
Table 6. USB-MODEVM Switches and Jumpers Default Position
Switch or Jumper
Setting
SW1
SW1-1
SW1-2
ON
ON
SW2
SW2-1
SW2-2
SW2-3
SW2-4
SW2-5
SW2-6
SW2-7
SW2-8
ON
OFF
ON
ON
ON
ON
ON
OFF
SW3
SW3-1
SW3-2
SW3-3
SW3-4
SW3-5
SW3-6
SW3-7
SW3-8
ON
OFF
OFF
OFF
OFF
OFF
OFF
OFF
JMP1
Installed
JMP2
Installed
JMP3
Removed
JMP4
Removed
JMP5
Connect 2 to 3
JMP6
Connect 1 to 2 (USB)
JMP7
Connect 2 to 3
JMP8
Removed
All switches and jumpers on both the mother- and daughterboards must stay in the manufacturer default
position, as given in Table 5 and Table 6.
6.1.2
Software Installation and Setup
Place the CD-ROM into your PC CD-ROM drive. To install and set up the TSC2017EVM-PDK, execute
the following steps:
1. Go to the Installer directory on this CD-ROM; find and run setup.exe.
2. Accept the license agreement, and continue the installation.
3. Follow the instructions and prompts as they are given.
4. When the installation is completed, click Finish on the TSC2017EVM installer window.
5. Restart your computer. (This step may not be necessary, but is suggested.)
6. When your computer has finished restarting, connect the TSC2017EVM via a USB cable to the
computer. Microsoft Windows should recognize the new device, and start the Found New Hardware
wizard sequence.
7. Select Install from a list or specific location (Advanced), and click on Next>.
8. Select Don't Search. I will Choose the driver to install, and click on Next>.
9. If TSC2017EVM is in the list of Models, click on it to select it. You are done.
10. Otherwise, if it is not there, the Windows Add Hardware wizard provides a list of common hardware
types; find and click on NI-VISA USB Devices.
11. Click on Have Disk...
12. Select Browse ..., and find the file, TSC2017EVM.inf, which is included with the installer and, by
default, is in the directory:
C:\Program Files\Texas Instruments\TSC2017EVM \data\
13. Select the TSC2017EVM.inf file, and click on it.
14. Your PC then installs it.
15. Click on Finish to finish the installation.
SLAU305A – January 2010 – Revised June 2010
TSC2017EVM and TSC2017EVM-PDK
Copyright © 2010, Texas Instruments Incorporated
7
EVM-PDK Operation
www.ti.com
You are done and ready to run the TSC2017EVM software GUI.
6.2
Quick Start
In order to use the touch screen features, a four-wire resistive touch screen must be connected to J1 on
the TSC2017EVM. It is important to ensure that the connection between TSC2017 and the touch screen is
as short, simple, and secure as possible.
When both hardware and software installation/setup have completed successfully, attach a USB cable
from your PC to the USB-MODEVM Interface board (J7 on the motherboard). As configured at the factory,
the board is powered from the USB interface; no other external power supply is needed, and the power
indicator LEDs on the USB-MODEVM light up.
Also the yellow LED (D2, which is located next to the J7 USB plug) lights up to indicate that the processor
on the USB-MODEVM board works and runs the TSC firmware program properly.
Launch the TSC2017 evaluation software on your PC, which you just installed. The software automatically
finds the TSC2017EVM, and a screen similar to the one shown in Figure 2 appears.
Figure 2. TSC2017EVM-PDK Software GUI Screen
8
TSC2017EVM and TSC2017EVM-PDK
SLAU305A – January 2010 – Revised June 2010
Copyright © 2010, Texas Instruments Incorporated
EVM-PDK Operation
www.ti.com
Note that the I2C Bus Status shown in the lower right corner (just above the STOP button of the GUI in
Figure 2) is green if the driver in your PC has been properly set up, and the TSC slave address is
corresponding.
TSC2017 has an address pin A0 that can be set low or high to get the TSC2017 address for either
1001000b (if A0 = low) or 1001001b (if A0 = high). On the TSC2017EVM board, JP3 controls the A0
status. By default, A0 must be installed (refer to Table 5), and thus the default A0 is '0' in the Device
Address (A0) selection box. Change it to '1' if TSC2017EVM JP3 is removed (high).
At the startup of the GUI, the non-Touch Data Acquisition section (on the right side) functions and proper
temperature data is displayed, as shown in Figure 2.
To stop running the software, you click on the STOP button in the lower right corner of the screen.
6.3
GUI and Operation Description
After the TSC2017EVM-PDK hardware and software installation and setup (described in Section 6.1),
evaluation and development with the TSC2017 can begin.
By plugging into a USB port on your PC and starting the TSC2017EVM-PDK software on your PC, the
interface GUI is displayed as shown in Figure 2.
The GUI has four general sections (shown in Figure 3):
1. The yellow boxes contain Touchscreen Functions.
2. The blue box contains Data Acquisition Functions.
3. The pink box contains TSC2017 commands.
4. The purple box contains TSC2017 Setup commands.
SLAU305A – January 2010 – Revised June 2010
TSC2017EVM and TSC2017EVM-PDK
Copyright © 2010, Texas Instruments Incorporated
9
EVM-PDK Operation
www.ti.com
Figure 3. Four Main Sections in TSC2017EVM-PDK GUI Screen
6.3.1
Touchscreen Functions
The Touchscreen Functions section is updated when a touch is detected on the touch screen. As the
touch screen is drawn on, the motion on the touch screen is translated into pixels on this box. The
software takes X, Y, and Z readings, which are shown to the right of the touch screen box. As the touch
pressure is increased, the pixel size increases; a lighter touch results in smaller pixel sizes.
The Z-value displayed is not what is described in the TSC2017 data sheet; this difference is because in
the data sheet equation, it is assumed that the sheet resistance of the touch screen being used is known.
The value used in this program is calculated by Equation 2 of the TSC2017 data sheet, but without
multiplying it by the RX-plate resistance. This value ranges from 0 to 3 and larger, with larger numbers
representing a more forceful pressure on the screen. Using the Maximum Z Value to Display knob, you
can set a threshold so that the program does not display lightly pressed points. This threshold setting
helps to eliminate display of spurious points that may result from touch screen mechanical bouncing.
The display can be cleared by pressing the Clear Graph button on the screen.
10
TSC2017EVM and TSC2017EVM-PDK
SLAU305A – January 2010 – Revised June 2010
Copyright © 2010, Texas Instruments Incorporated
EVM-PDK Operation
www.ti.com
6.3.2
Data Acquisition Functions
The TSC2017 has provision for measuring one auxiliary input voltages (AUX) and temperature. This
section displays the measured values for these parameters. Measurements are updated only when the
touch screen is not being pressed and auto-reading mode is enabled (the AutoRead LED button is on).
Temperature is displayed using both methods described in the TSC2017 data sheet. Using the TEMP0
and TEMP1 measurements, a temperature reading with 2°C resolution and accuracy is achieved. Using
only the TEMP0 measurement, a reading with 0.3°C resolution is possible, but this option requires
knowing the TEMP0 value at 25°C; this normally is a calibration that the user performs. This program
assumes that TEMP0 = 580 mV at 25°C.
By default, AutoRead LED is on. That is, the software continuously reads nontouch data, AUX, TEMP1
and TEMP2, and automatically updates them in the Non-Touch Data Acquisition section. To stop the data
acquisition, click on the green LED AutoRead to turn it off.
Both AUX and temperature measurements require a reference voltage, which is provided to the TSC2017
VREF pin. The VREF (volts) controller box can be written with the corresponding VREF voltage. The factory
default VREF is 3.3 VDC.
6.3.3
TSC2017 Command
The TSC2017 can be configured to operate in 8-bit or 12-bit resolution modes. Control over the mode
used is selected in this section, which is sent to TSC2017 in the command byte.
The two power-down bits, PD1 and PD0, of the TSC2017 can be set from this panel as well. A brief
description of the mode selected is shown on the screen when setting these bits; see Table 2 (Command
Byte Definitions) of the TSC2017 data sheet (SBAS472) for details on what these bits do.
6.3.4
TSC2017 Setup Command
TSC2017 has several software programmable features that can be set up by TSC2017 in the setup mode,
a specific command called Setup.
Software reset can bring TSC2017 to its power-up default condition. When clicking on the LED and it
becomes green, the TSC2017 is software reset.
TSC2017 has a built-in MAV filter, which is enabled by default. The MAV filter can be disabled/enabled by
clicking on the MAV Filter button.
The PENIRQ signal from the TSC2017 can be used as an interrupt to the host, and it requires being
pulled up by a resistor. The TSC2017 has an internal pullup RIRQ, and thus no external pullup is needed.
The internal pullup RIRQ can be selected and programmed to be either 50 kΩ (default) or 90 kΩ. The
Internal PENIRQ Pullup button is used to select the RIRQ.
For more details on the programmable features and Setup mode of the TSC2017, see the product data
sheet (SBAS472), .
6.3.5
TSC2017 Hardware Reset
Clicking on the Hardware Reset LED in the lower right corner of the GUI turns the LED switch on or off.
When the LED is turned on or lit (in green), the hardware reset pin RESET is pulled low by a digital control
signal from the USB-MODEVM board, and the TSC2017 enters the hardware reset process. To bring
TSC2017 back to normal operational state, the LED must be turned off.
6.4
Datalogging
The software can record the data it takes from the TSC2017 to a tab-delimited file, suitable for importing
into spreadsheets. To do this, first go into the File menu, and select Log Data to File..., which opens a
file-select window and allows you to specify a file to which to write the data. At the same time, this enables
the Datalogging menu.
SLAU305A – January 2010 – Revised June 2010
TSC2017EVM and TSC2017EVM-PDK
Copyright © 2010, Texas Instruments Incorporated
11
EVM Bill of Materials
www.ti.com
When ready to begin recording data to a file, select Datalogging → Start Logging. Data are written to the
file until Datalogging → Stop Logging is selected. When the screen is not touched, the AUX and TEMP
values are written to the file, and the X, Y, Z1, and Z2 parameters are written to the file with values of
9999, to indicate that they are not updated. When the screen is touched, the X, Y, Z1, and Z2 parameters
are written while the AUX and TEMP values are written to the file as 9999. Because the program
constantly updates at a rate of approximately 400 readings per second, datalog files can quickly grow
large; therefore, log only that data which are necessary.
The format of the data file has the first column as the time in milliseconds (which is just a timer in the
program; it can arbitrarily start at any number), then X, Y, Z1, Z2, AUX, TEMP0, and TEMP1 columns.
Every new reading is a new row in the file.
7
EVM Bill of Materials
Table 7 and Table 8 contain a complete bill of materials for the modular TSC2017EVM evaluation board
and the USB-MODEVM interface board, respectively (included only in the TSC2017EVM-PDK).
Table 7. TSC2017EVM Bill of Materials
Count
Ref Des
Description
Manufacturer
Mfg Part No.
1
NA
Printed Wiring Board
TI
6513588
3
C1, C3, C8
CAP CER 0.1 µF 50V 10% X7R 0603
Murata
GRM188R71H104KA93D
1
C2
CAP CER 10 µF 6.3V X5R 20% 0603
TDK
C1608X5R0J106M
0
C4, C5, C6, C7
Not Installed
1
C9
CAP CER 10 µF 10V 10% X5R 0805
Murata
GRM219R61A106KE44D
2
J1, J2
10 Pin, Dual Row, SM Header (20 Pos.)
Samtec
TSM-110-01-T-DV-P
2
J1B, J2B
10 Pin, Dual Row, SM Header (20 Pos.)
Samtec
SSW-110-22-F-D-VS-K
1
J3
5 Pin, Dual Row, SM Header (10 Pos.)
Samtec
TSM-105-01-T-DV-P
1
J3B
5 Pin, Dual Row, SM Header (10 Pos.)
Samtec
SSW-105-22-F-D-VS-K
1
JP1
3 Position Header
Samtec
TSW-103-22-T-S
2
JP2, JP3
2 Position Header
Samtec
TSW-102-22-T-S
3
R1, R2, R6
RES 20.0 kΩ 1/10W 1% 0603 SMD
Yageo
RC0603FR-0720KL
1
R3
RES 100 Ω 1/10W 1% 0603 SMD
Yageo
RC0603FR-07100RL
2
R4, R5
RES 2.74 kΩ 1/10W 1% 0603 SMD
Yageo
RC0603FR-072K74L
10
TP1, TP4–TP12
TEST POINT PC MINI 0.040"D RED
Keystone
5000
2
TP2, TP3
TEST POINT PC MINI 0.040"D BLACK
Keystone
5001
1
U1
12-Bit Nanopower, four-wire Micro TOUCH SCREEN CONTROLLER TI
with I2C™ Interface
TSC2017IYZG
1
U2
IC EEPROM 256KBIT 400KHZ 8TSSOP
Microchip
24AA256-I/ST
0.100 Shunt – Black Shunts
Samtec
SNT-100-BK-T
Additional Components
3
NA
Notes: 1. J1B, J2B, J3B bottom side parts are not shown in the schematic diagram
J1B is installed on the bottom side of the PWB opposite J1.
J2B is installed on the bottom side of the PWB opposite J2.
J3B is installed on the bottom side of the PWB opposite J3.
2. Refer to the PCA assembly instruction (6513588_ASSY_A.PDF – Assembly Drawing).
3. Manufacturer and Part Numbers for items may be substituted with electrically equivalent items.
12
TSC2017EVM and TSC2017EVM-PDK
SLAU305A – January 2010 – Revised June 2010
Copyright © 2010, Texas Instruments Incorporated
EVM Bill of Materials
www.ti.com
Table 8. USB-MODEVM Bill of Materials
Reference Designator
Description
Manufacturer
Manufacturer's Part No.
R4
10Ω 1/10W 5% Chip Resistor
Panasonic
ERJ-3GEYJ100V
R10, R11
27.4Ω 1/16W 1% Chip Resistor
Panasonic
ERJ-3EKF27R4V
R20
75Ω 1/4W 1% Chip Resistor
Panasonic
ERJ-14NF75R0U
R19
220Ω 1/10W 5% Chip Resistor
Panasonic
ERJ-3GEYJ221V
R14, R21, R22
390Ω 1/10W 5% Chip Resistor
Panasonic
ERJ-3GEYJ391V
R13
649Ω 1/16W 1% Chip Resistor
Panasonic
ERJ-3EKF6490V
R9
1.5KΩ 1/10W 5% , Chip Resistor
Panasonic
ERJ-3GEYJ152V
R1–R3, R5–R8
2.7KΩ 1/10W 5% , Chip Resistor
Panasonic
ERJ-3GEYJ272V
R12
3.09KΩ 1/16W 1% , Chip Resistor
Panasonic
ERJ-3EKF3091V
R15, R16
10KΩ 1/10W 5%, Chip Resistor
Panasonic
ERJ-3GEYJ103V
R17, R18
100KΩ 1/10W 5%, Chip Resistor
Panasonic
ERJ-3GEYJ104V
RA1
10KΩ 1/8W Octal Isolated, Resistor Array
CTS Corporation
742C163103JTR
C18, C19
33pF 50V Ceramic, Chip Capacitor, ±5%, NPO
TDK
C1608C0G1H330J
C13, C14
47pF 50V Ceramic, Chip Capacitor, ±5%, NPO
TDK
C1608C0G1H470J
C20
100pF 50V Ceramic Chip Capacitor, ±5%, NPO
TDK
C1608C0G1H101J
C21
1000pF 50V Ceramic Chip Capacitor, ±5%, NPO
TDK
C1608C0G1H102J
C15
0.1mF 16V Ceramic Chip Capacitor, ±10%,X7R
TDK
C1608X7R1C104K
C16, C17
0.33mF 16V Ceramic Chip Capacitor, ±20%,Y5V
TDK
C1608X5R1C334K
C9–C12–C28
1µF 6.3V Ceramic Chip Capacitor, ±10%, X5R
TDK
C1608X5R0J105K
C1–C8
10mF 6.3V Ceramic Chip Capacitor, ±10%, X5R
TDK
C3216X5R0J106K
D1
50V, 1A, Diode MELF SMD
Micro Commercial
Components
DL4001
D2
Yellow Light Emitting Diode
Lumex
SML-LX0603YW-TR
D3, D4, D6, D7
Green Light Emitting Diode
Lumex
SML-LX0603GW-TR
D5
Red Light Emitting Diode
Lumex
SML-LX0603IW-TR
Q1, Q2
N-Channel MOSFET
Zetex
ZXMN6A07F
X1
6MHz Crystal SMD
Epson
MA-505 6.000M-C0
U8
USB Streaming Controller
Texas Instruments
TAS1020BPFB
U2
5V LDO Regulator
Texas Instruments
REG1117-5
U9
3.3V/1.8V Dual Output LDO Regulator
Texas Instruments
TPS767D318PWP
U3, U4
Quad, 3-State Buffers
Texas Instruments
SN74LVC125APW
U5–U7
Single IC Buffer Driver with Open Drain o/p
Texas Instruments
SN74LVC1G07DBVR
U10
Single 3-State Buffer
Texas Instruments
SN74LVC1G125DBVR
U1
64K 2-Wire Serial EEPROM I2C
Microchip
24LC64I/SN
USB-MODEVM PCB
Texas Instruments
6463995
TP1–TP6, TP9–TP11
Miniature test point terminal
Keystone Electronics
5000
TP7, TP8
Multipurpose test point terminal
Keystone Electronics
5011
J7
USB Type B Slave Connector Thru-Hole
Mill-Max
897-30-004-90-000000
J1–J5, J8
2-position terminal block
On Shore Technology
ED555/2DS
J9
2.5mm power connector
CUI Stack
PJ-102B
J10
BNC connector, female, PC mount
AMP/Tyco
414305-1
J11A, J12A, J21A, J22A
20-pin SMT plug
Samtec
TSM-110-01-L-DV-P
J11B, J12B, J21B, J22B
20-pin SMT socket
Samtec
SSW-110-22-F-D-VS-K
J13A, J23A
10-pin SMT plug
Samtec
TSM-105-01-L-DV-P
J13B, J23B
10-pin SMT socket
Samtec
SSW-105-22-F-D-VS-K
J6
4-pin double row header (2x2) 0.1"
Samtec
TSW-102-07-L-D
J14, J15
12-pin double row header (2x6) 0.1"
Samtec
TSW-106-07-L-D
JMP1–JMP4
2-position jumper, 0.1" spacing
Samtec
TSW-102-07-L-S
SLAU305A – January 2010 – Revised June 2010
TSC2017EVM and TSC2017EVM-PDK
Copyright © 2010, Texas Instruments Incorporated
13
Schematics
www.ti.com
Table 8. USB-MODEVM Bill of Materials (continued)
Reference Designator
Description
Manufacturer
Manufacturer's Part No.
JMP8–JMP14
2-position jumper, 0.1" spacing
Samtec
TSW-102-07-L-S
JMP5, JMP6
3-position jumper, 0.1" spacing
Samtec
TSW-103-07-L-S
JMP7
3-position dual row jumper, 0.1" spacing
Samtec
TSW-103-07-L-D
SW1
SMT, half-pitch 2-position switch
C&K Division, ITT
TDA02H0SK1
SW2
SMT, half-pitch 8-position switch
C&K Division, ITT
TDA08H0SK1
Jumper plug
Samtec
SNT-100-BK-T
7.1
TSC2017 Top Silk Screen
8
Schematics
8.1
TSC2017EVM Schematic
The schematic diagram is provided as a reference.
8.2
USB-MODEVM Schematic
The schematic diagram is provided as a reference.
14
TSC2017EVM and TSC2017EVM-PDK
SLAU305A – January 2010 – Revised June 2010
Copyright © 2010, Texas Instruments Incorporated
Revision History
www.ti.com
Revision History
Changes from Original (January, 2010) to A Revision ................................................................................................... Page
•
Corrected error in Figure 1
..............................................................................................................
6
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
SLAU305A – January 2010 – Revised June 2010
Revision History
Copyright © 2010, Texas Instruments Incorporated
15
1
2
3
4
5
6
Revision History
REV
ECN Number
Approved
D
D
Vcc
Vcc
Vcc
C2
10uF
R2
R1
C1
TP9
Y+
TP10
X-
TP11
X+
TP7
RESET
20K
JP3
A2
TP8
Y-
20K
0.1uF
U1
A3
X+
XY+
Y-
X+
B3
Y+
C3
AUX
D3
TP12
AUX
R3
A1
100
C3
0.1uF
C4
NI
C5
NI
C6
NI
Y-
SDA
C7
NI
J2
C2
RESET
SCL
AUX
B2
A0
X-
GND
Analog Interface
2
4
6
8
10
12
14
16
18
20
D2
C
A0(-)
A0(+)
A1(-)
A1(+)
A2(-)
A2(+)
A3(-)
A3(+)
AGND
A4
AGND
A5
AGND
A6
VCOM
A7
AGND REFAGND REF+
VDD/REF
J1
1
3
5
7
9
11
13
15
17
19
D1
C1
TP6
PENIRQ
B1
PENIRQ
1
3
5
7
9
11
13
15
17
19
CNTL
CLKX
CLKR
FSX
FSR
DX
DR
INT
TOUT
GPIO5
TSC2017IZZZ
2
4
6
8
10
12
14
16
18
20
GPIO0
DGND
GPIO1
GPIO2
DGND
GPIO3
GPIO4
SCL
DGND
SDA
Vcc
C
R4
R5
2.74K
2.74K
Digital Interface
TP5
SCL
TP4
SDA
C8
Vcc
0.1uF
U2
J3
1
3
5
7
9
B
+VA
-VA
+5VA
-5VA
DGND AGND
+1.8VD VD1
+3.3VD +5VD
2
4
6
8
10
R6
JP2
TP1
Vcc
20k
1
2
3
4
A0
A1
A2
GND
VCC
SCL
SDA
WP
8
6
5
7
B
24AA256-I/ST
Power Interface
Vcc
Vcc
JP1
C9
10uF
TP2
DGND
TP3
AGND
ti
A
A
12500 TI Blvd. Dallas, Texas 75243
Title:
Engineer:
Drawn By:
FILE:
1
2
3
4
5
Wendy Fang
Lisa Parker
TSC2017 Evaluation Module
SIZE:
DATE:
6-Jan-2010
REV:
SHEET: 1
6513588
6
A
OF: 1
1
2
3
4
6
5
REVISION HISTORY
REV
IOVDD
R5
2.7K
2
5
9
12
1
USB MCK
4
10
USB I2S
13
J6
Q2
ZXMN6A07F
EXTERNAL I2C
SDA
SCL
WP
8
A0
A1
A2
U1
VCC
C9
1uF
4
1
1
3
5
7
9
11
3
2
44
43
42
41
40
39
37
38
36
35
34
32
R12
3.09K
.001uF
R10
27.4
R11
C13
47pF
C14
47pF
R7
2.7K
JMP8
1
2
P1.2
P1.1
P1.0
+3.3VD
C11
1uF
C12
1uF
C
MOSI
SS
SCLK
RESET
14
VCC
J15
1
3
5
7
9
11
3
6
8
11
1Y
2Y
3Y
4Y
7
GND
2
4
6
8
10
12
EXTERNAL SPI
USB RST
USB SPI
P3.5
JMP13
1
2
D2
+3.3VD
YELLOW
C25
R8
2.7K
P3.4
JMP14
1
2
IOVDD
P3.3
B
U6
1uF
4
2
INT
3
J8
5
B
1A
2A
3A
4A
1OE
2OE
3OE
4OE
JMP12
1
2
SML-LX0603YW-TR
MISO
SN74LVC1G07DBV
SN74LVC125APW
MRESET
649
2
U4
2
5
9
12
1
4
10
13
USB ACTIVE
R13
4
1uF
JMP11
1
2
C10
1uF
EXTERNAL AUDIO DATA
C27 IOVDD
JMP10
1
2
C24
1uF
SW DIP-8
P1.3
JMP9
1
2
SN74LVC1G07DBV
ED555/2DS
+5VD
EXT PWR IN
+1.8VD
R14
390
U9
5
6
4
1
2
3
6VDC-10VDC IN
D3
SML-LX0603GW-TR
JMP6
PWR SELECT
GREEN
3
9
U2
REG1117-5
3
C15 DL4001
0.1uF
VIN
C16
0.33uF
VOUT
GND
D1
10
11
12
2
R15
10K
C6
10uF
1
J9
R16
10K
+5VD
A
+3.3VD
+1.8VD
IOVDD
JMP7
1
2
3
4
5
6
TP6
1IN
1IN
1EN
1GND
2GND
2EN
2IN
2IN
1RESET
1OUT
1OUT
2RESET
2OUT
2OUT
TPS767D318PWP
CUI-STACK PJ102-B
2.5 MM
SW1
1
2
4
3
24
23
22
18
17
R17
100K
C7
10uF
D5
SML-LX0603IW-TR
R18
100K
R4
10
+3.3VD
RED
R19
220
ti
C8
10uF
D4
SML-LX0603GW-TR
C17
0.33uF
1.8VD ENABLE
3.3VD ENABLE
28
GREEN
DATA ACQUISITION PRODUCTS
REGULATOR ENABLE
6730 SOUTH TUCSON BLVD., TUCSON, AZ 85706 USA
TITLE
ENGINEER RICK DOWNS
USB-MODEVM INTERFACE
DRAWN BY ROBERT BENJAMIN
DOCUMENT CONTROL NO. 6463996
SHEET 1
2
A
HIGH PERFORMANCE ANALOG DIVISION
SEMICONDUCTOR GROUP
IOVDD SELECT
1
SW2
1
2
3
4
5
6
7
8
PWR_DWN
U7
31
30
29
27
26
25
24
23
8
21
33
2
16
15
14
13
12
11
10
9
2
4
6
8
10
12
1uF
TP11
+3.3VD
IOVDD
C26
3
P1.7
P1.6
P1.5
P1.4
P1.3
P1.2
P1.1
P1.0
DVDD
DVDD
DVDD
AVDD
9
10
11
12
13
14
15
17
18
19
20
22
27.4
XTALO
XTALI
PLLFILI
PLLFILO
MCLKI
PUR
DP
DM
DVSS
DVSS
DVSS
AVSS
MRESET
TEST
EXTEN
RSTO
P3.0
P3.1
P3.2/XINT
P3.3
P3.4
P3.5
NC
NC
7
1
2
3
1.5K
+3.3VD
U8
TAS1020BPFB
SCL
SDA
VREN
RESET
MCLKO2
MCLKO1
CSCLK
CDATO
CDATI
CSYNC
CRESET
CSCHNE
46
47
48
1
3
5
6
7
4
16
28
45
100pF
C21
R9
J14
1uF
33pF
MA-505 6.000M-C0
6.00 MHZ
J7 USB SLAVE CONN
897-30-004-90-000000
I2SDOUT
C23
U5
C19
C20
4
3
2
1
BCLK
SN74LVC1G07DBV
33pF
24LC64I/SN
GND
D+
DVCC
X1
C18
A0
A1
A2
USB I2S
USB MCK
USB SPI
USB RST
EXT MCK
LRCLK
IOVDD
4
VSS
R20
75
MCLK
7
GND
R6
2.7K
RA1
10K
I2SDIN
6
5
+3.3VD
SCL
C
SN74LVC1G125DBV
3
6
8
11
1Y
2Y
3Y
4Y
D
2
SN74LVC125APW
+3.3VD
TP10
14
VCC
+3.3VD
5
1
3
1A
2A
3A
4A
1OE
2OE
3OE
4OE
5
2
4
4
1uF
U3
APPROVED
J10
EXT MCLK
U10
3
R3
2.7K
TP9
SDA
1uF
5
C22
Q1
ZXMN6A07F
D
C28 IOVDD
IOVDD
+3.3VD
ENGINEERING CHANGE NUMBER
3
4
5
OF
2
FILE
SIZE B
DATE 10-Jun-2004
REV A
G:\USB Motherboard - Modular Evm\Schematic\USB Motherboard - ModEvm.ddb - Docume
6
1
2
3
4
6
5
REVISION HISTORY
REV
ENGINEERING CHANGE NUMBER
APPROVED
D
1
2
3
D
J11
J12
A0(+)
A1(+)
A2(+)
A3(+)
A4
A5
A6
A7
REFREF+
2
4
6
8
10
12
14
16
18
20
+5VA
J13A (TOP) = SAM_TSM-105-01-L-DV-P
J13B (BOTTOM) = SAM_SSW-105-22-F-D-VS-K
DAUGHTER-ANALOG
J11A (TOP) = SAM_TSM-110-01-L-DV-P
J11B (BOTTOM) = SAM_SSW-110-22-F-D-VS-K
+5VA
+5VD
JMP1
1
2
+VA
+5VA
AGND
+1.8VD
+3.3VD
-VA
-5VA
DGND
VD1
+5VD
2
4
6
8
10
GPIO0
DGND
GPIO1
GPIO2
DGND
GPIO3
GPIO4
SCL
DGND
SDA
SCLK
SS
P3.3
J12A (TOP) = SAM_TSM-110-01-L-DV-P
J12B (BOTTOM) = SAM_SSW-110-22-F-D-VS-K
TP8
DGND
+5VA
TP2
10uF
C2
+5VD
TP3
10uF
C3
TP4
10uF
JMP3
PWR_DWN
INT
JMP4
MISO
+3.3VD
MOSI
R1
R21
390
J1
-5VA
R22
390
SCL
2.7K
J2
+5VA
D6
SML-LX0603GW-TR
D7
SML-LX0603GW-TR
GREEN
GREEN
J3
+5VD
TP5
+1.8VD
C
RESET
IOVDD
2
C1
P3.5
P1.0
1
-5VA
P3.4
+5VD
JMP2
1
2
TP1
JMP5
2
4
6
8
10
12
14
16
18
20
-5VA
DAUGHTER-POWER
TP7
AGND
JPR-2X1
C
CNTL
CLKX
CLKR
FSX
FSR
DX
DR
INT
TOUT
GPIO5
DAUGHTER-SERIAL
J13
1
3
5
7
9
1
3
5
7
9
11
13
15
17
19
2
A0(-)
A1(-)
A2(-)
A3(-)
AGND
AGND
AGND
VCOM
AGND
AGND
1
1
3
5
7
9
11
13
15
17
19
C4
C5
10uF
10uF
J4
+1.8VD
R2
SDA
2.7K
I2SDOUT
J5
+3.3VD
I2SDIN
LRCLK
BCLK
J21
1
3
5
7
9
11
13
15
17
19
B
A0(-)
A1(-)
A2(-)
A3(-)
AGND
AGND
AGND
VCOM
AGND
AGND
J22
A0(+)
A1(+)
A2(+)
A3(+)
A4
A5
A6
A7
REFREF+
2
4
6
8
10
12
14
16
18
20
1
3
5
7
9
11
13
15
17
19
+5VA
DAUGHTER-ANALOG
J21A (TOP) = SAM_TSM-110-01-L-DV-P
J21B (BOTTOM) = SAM_SSW-110-22-F-D-VS-K
+1.8VD
+VA
+5VA
AGND
+1.8VD
+3.3VD
GPIO0
DGND
GPIO1
GPIO2
DGND
GPIO3
GPIO4
SCL
DGND
SDA
2
4
6
8
10
12
14
16
18
20
P1.1
B
P1.2
P1.3
MCLK
DAUGHTER-SERIAL
J23
1
3
5
7
9
CNTL
CLKX
CLKR
FSX
FSR
DX
DR
INT
TOUT
GPIO5
-VA
-5VA
DGND
VD1
+5VD
2
4
6
8
10
-5VA
J22A (TOP) = SAM_TSM-110-01-L-DV-P
J22B (BOTTOM) = SAM_SSW-110-22-F-D-VS-K
DAUGHTER-POWER
+3.3VD
+5VD
J23A (TOP) = SAM_TSM-105-01-L-DV-P
J23B (BOTTOM) = SAM_SSW-105-22-F-D-VS-K
ti
A
DATA ACQUISITION PRODUCTS
A
HIGH-PERFORMANCE ANALOG DIVISION
SEMICONDUCTOR GROUP
6730 SOUTH TUCSON BLVD., TUCSON, AZ 85706 USA
TITLE
ENGINEER
RICK DOWNS
DRAWN BY
ROBERT BENJAMIN
USB-MODEVM INTERFACE
DOCUMENT CONTROL NO. 6463996
SHEET 2
1
2
3
4
5
OF
2
FILE
SIZE B
DATE 10-Jun-2004
REV A
G:\USB Motherboard - Modular Evm\Schematic\USB Motherboard - ModEvm.ddb - Docume
6
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Texas Instruments (TI) provides the enclosed product(s) under the following conditions:
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patents or services described herein.
Please read the User’s Guide and, specifically, the Warnings and Restrictions notice in the User’s Guide prior to handling the
product. This notice contains important safety information about temperatures and voltages. For additional information on TI’s
environmental and/or safety programs, please contact the TI application engineer or visit www.ti.com/esh.
No license is granted under any patent right or other intellectual property right of TI covering or relating to any machine, process, or
combination in which such TI products or services might be or are used.
FCC Warning
This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR EVALUATION
PURPOSES ONLY and is not considered by TI to be a finished end-product fit for general consumer use. It generates, uses, and
can radiate radio frequency energy and has not been tested for compliance with the limits of computing devices pursuant to part 15
of FCC rules, which are designed to provide reasonable protection against radio frequency interference. Operation of this
equipment in other environments may cause interference with radio communications, in which case the user at his own expense
will be required to take whatever measures may be required to correct this interference.
EVM Warnings and Restrictions
It is important to operate this EVM within the input voltage range of 0 V to 3.6 V and the output voltage range of 0 V to 3.6 V .
Exceeding the specified input range may cause unexpected operation and/or irreversible damage to the EVM. If there are
questions concerning the input range, please contact a TI field representative prior to connecting the input power.
Applying loads outside of the specified output range may result in unintended operation and/or possible permanent damage to the
EVM. Please consult the EVM User's Guide prior to connecting any load to the EVM output. If there is uncertainty as to the load
specification, please contact a TI field representative.
During normal operation, some circuit components may have case temperatures greater than 30° C. The EVM is designed to
operate properly with certain components above 85° C as long as the input and output ranges are maintained. These components
include but are not limited to linear regulators, switching transistors, pass transistors, and current sense resistors. These types of
devices can be identified using the EVM schematic located in the EVM User's Guide. When placing measurement probes near
these devices during operation, please be aware that these devices may be very warm to the touch.
Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265
Copyright © 2010, Texas Instruments Incorporated
IMPORTANT NOTICE
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TI assumes no liability for applications assistance or customer product design. Customers are responsible for their products and
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Applications
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amplifier.ti.com
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dataconverter.ti.com
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DLP® Products
www.dlp.com
Communications and
Telecom
www.ti.com/communications
DSP
dsp.ti.com
Computers and
Peripherals
www.ti.com/computers
Clocks and Timers
www.ti.com/clocks
Consumer Electronics
www.ti.com/consumer-apps
Interface
interface.ti.com
Energy
www.ti.com/energy
Logic
logic.ti.com
Industrial
www.ti.com/industrial
Power Mgmt
power.ti.com
Medical
www.ti.com/medical
Microcontrollers
microcontroller.ti.com
Security
www.ti.com/security
RFID
www.ti-rfid.com
Space, Avionics &
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www.ti.com/space-avionics-defense
RF/IF and ZigBee® Solutions www.ti.com/lprf
Video and Imaging
www.ti.com/video
Wireless
www.ti.com/wireless-apps
Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265
Copyright © 2010, Texas Instruments Incorporated
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