ERJ-3GEYJ301V_技术文档

User's Guide

SBOU125–June 2012

INA223EVM User’s Guide and Software Tutorial

INA223EVM

This user's guide describes the characteristics, operation, and use of the INA223EVM evaluation board. It

discusses how to set up and configure the software and hardware, and reviews various aspects of the

program operation. This user's guide also includes information regarding operating procedures and

input/output connections, an electrical schematic, printed circuit board (PCB) layout drawings, and a parts

list for the EVM.

Throughout this document, the terms evaluation board, evaluation module, and EVM are synonymous with

the INA223EVM.

Microsoft, Windows are registered trademarks of Microsoft Corporation.

SPI is a trademark of Motorola Inc,.

I²C is a trademark of NXP Semiconductors.

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INA223EVM (continued)

Contents

1

2

3

4

5

6

Overview ..................................................................................................................... 3

INA223EVM Hardware Setup ............................................................................................. 4

INA223EVM Hardware Overview ......................................................................................... 7

INA223EVM Software Setup ............................................................................................. 12

INA223EVM Software Overview ......................................................................................... 14

INA223EVM Documentation ............................................................................................. 22

List of Figures

1

Hardware Included with INA223EVM Kit.................................................................................

Hardware Setup.............................................................................................................

INA223 Test Board Block Diagram .......................................................................................

SM-USB-DIG Platform Block Diagram ...................................................................................

Typical Hardware Test Connections on the INA223EVM..............................................................

Connecting the USB Cable to the SM-USB-DIG Platform.............................................................

Confirmation of SM-USB-DIG Platform Driver Installation.............................................................

INA223EVM Default Jumpers .............................................................................................

3

4

5

6

7

8

9

2

3

4

5

6

7

8

9

Typical Filter Setup........................................................................................................ 11

INA223 Shunt Configurations............................................................................................ 11

Software Install Window .................................................................................................. 12

Software License Agreement ............................................................................................ 13

Software Install Progress................................................................................................. 13

INA223EVM Software Interface ......................................................................................... 14

Communication Error with SM-USB-DIG Platform .................................................................... 14

Setting the A0 Address ................................................................................................... 15

Configuring the Output Mode ............................................................................................ 16

Configuring the Bus Voltage Gain....................................................................................... 18

Configuring the Current Shunt Voltage Gain .......................................................................... 18

Register Table ............................................................................................................. 19

Auto-Write, Power, and Voltage Controls .............................................................................. 20

Example Hardware Calculator ........................................................................................... 21

INA223EVM Board Schematic........................................................................................... 23

INA223EVM PCB Component Layout .................................................................................. 24

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

List of Tables

1

2

3

4

5

6

Related Documentation ....................................................................................................

INA223EVM H1 Pin Connections.........................................................................................

INA223 Test Board Jumper Functions ...................................................................................

4

5

9

INA223 I²C Address Configuration ...................................................................................... 15

Power Gain Values........................................................................................................ 17

Bill of Materials ............................................................................................................ 22

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Overview

1

Overview

The INA223 is a voltage output device that monitors current, bus voltage, and power of a supply line by

sensing a voltage drop across a shunt. The INA223EVM is a platform for evaluating the performance of

the INA223 under various signal, shunt, and supply conditions. This document gives a general overview of

the INA223EVM, and provides a general description of the features and functions to be considered while

using this evaluation module.

1.1 INA223EVM Kit Contents

The INA223EVM kit includes the following items:

•

(1) INA223 PCB evaluation board

(1) SM-USB-DIG Platform PCB

(1) USB extender cable

(1) SM-USB-DIG connector ribbon cable

(1) User’s guide CD-ROM

Figure 1 shows all of the included hardware. Contact the Texas Instruments Product Information Center

nearest you if any component is missing. It is highly recommended that you check the TI web site at

http://www.ti.com to verify that you have the latest versions of the related software.

USB Extender Cable

SM-USB-DIG

Connector

Ribbon Cable

INA223EVM

Board

SM-USB-DIG

Figure 1. Hardware Included with INA223EVM Kit

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1.2 Related Documentation

The following document provides information regarding Texas Instruments integrated circuits used in the

assembly of the INA223EVM. This user's guide is available from the TI web site under literature number

SBOU125 . Any letter appended to the literature number corresponds to the document revision that is

current at the time of the writing of this document. Newer revisions may be available from the TI web site

at http://www.ti.com, or call the Texas Instruments Literature Response Center at (800) 477-8924 or the

Product Information Center at (972) 644-5580. When ordering, identify the document by both title and

literature number.

Table 1. Related Documentation

Document

Literature Number

SBOS528

INA223 Product Data Sheet

SM-USB-DIG Platform User’s Guide

SBOU098

2

INA223EVM Hardware Setup

This section discusses the overall system setup for the INA223EVM. A PC runs software that

communicates with the SM-USB-DIG Platform. This platform generates the analog and digital signals

used to communicate with the INA223 board. Connectors on the INA223 allow the user to connect to the

system under test conditions where the power, current, and voltage are monitored.

Analog Supply

Power Supply

USB SM-DIG

INA223EVM

Shunt

Load

GND

Figure 2. Hardware Setup

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2.1 Theory of Operation for INA223 Hardware

A block diagram of the INA223 test-board hardware setup is shown in Figure 3. The PCB provides

connections to the I²C™ and general-purpose inputs and outputs (GPIO) on the SM-USB-DIG Platform

board. It also provides connection points for external connections to the shunt voltage.

Shunt

Terminal

T2

Supply Voltage

2

A0

Vs

Vdut

H1

INA223

JMP1/JMP2

I2C Addr

Jumper

I2C Interface

Figure 3. INA223 Test Board Block Diagram

2.2 Signal Definitions of H1 (10-Pin Male Connector Socket)

Table 2 shows the pinout for the 10-pin connector socket used to communicate between the INA223EVM

and the SM-USB-DIG. It should be noted that to issue commands to the INA223 chip, the INA223EVM

only uses H1 connnector pins 1 and 3 (I²C communication lines), pin 6 (VDUT), and pin 8 (GND).

Table 2. INA223EVM H1 Pin Connections

Pin on H1

Signal

I2C_SCL

CTRL/MEAS4⁽¹⁾

Description

1

2

3

4

5

6

I²C clock signal (SCL)

GPIO—Control output or measure input

I²C data signal (SDA)

I2C_SDA1

CTRL/MEAS5⁽¹⁾

SPI_DOUT3⁽¹⁾

VDUT

GPIO—Control output or measure input

SPI™ data output (MOSI)

Switchable DUT power supply: +3.3V, +5V, Hi-Z

(disconnected).⁽²⁾

7

8

SPI_CLK⁽¹⁾

GND

SPI clock signal (SCLK)

Power return (GND)

9

SPI_CS1⁽¹⁾

SPI_DIN1⁽¹⁾

SPI chip select signal (CS)

SPI data input (MISO)

10

(1)

(2)

This signal is not used on the INA223EVM.

When VDUT is Hi-Z, all digital inputs and outputs (I/O) are Hi-Z as well.

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2.3 Theory of Operation for SM-USB-DIG Platform

Figure 4 shows the block diagram for the SM-USB-DIG Platform. This platform is a general-purpose data

acquisition system that is used on several different Texas Instruments evaluation modules. The details of

its operation are included in a separate document (SBOU098). The block diagram shown in Figure 4 is

given as a brief overview of the SM-USB-DIG Platform.

SM-USB-DIG

3.3-V

Regulator

USB

+5.0 V

+3.3 V

USB Bus

from

Computer

TUSB3210

8052 Microcontroller

w/USB Interface

and UART

I²C

SPI

Control Bits

Measure Bits

Buffer and

Level

Translators

Power-On

Reset

8K ´ 8 Byte

EEPROM

VDUT

(Hi-Z, 3.3 V, or 5 V)

Switched Power

Power

Switching

USB +5.0 V

+3.3 V

Figure 4. SM-USB-DIG Platform Block Diagram

The brain of the SM-USB-DIG Platform is the TUSB3210, an 8052 microcontroller that has a built-in USB

interface. The microcontroller receives information from the host computer that is interpreted into power,

I²C, SPI, and other digital I/O patterns. During the digital I/O transaction, the microcontroller reads the

response of any device connected to the I/O interface. The response from the device is sent back to the

PC where it is interpreted by the host computer.

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INA223EVM Hardware Overview

3

INA223EVM Hardware Overview

The INA223EVM hardware setup involves connecting the two EVM PCBs together, applying power,

connecting the USB cable, and setting the jumpers. This section describes the details of this procedure.

3.1 Electrostatic Discharge Warning

Many of the components on the INA223EVM are susceptible to damage by electrostatic discharge (ESD).

Customers are advised to observe proper ESD handling precautions when unpacking and handling the

EVM, including the use of a grounded wrist strap at an approved ESD workstation.

3.2 Connecting the Hardware

To connect the INA223 test board and the SM-USB-DIG Platform together, gently slide the male and

female ends of the 10-pin connectors together. Make sure that the two connectors are completely pushed

together; loose connections may cause intermittent operation.

3.3 Connecting Power

After the EVM and SM-USB-DIG are joined, as shown in Figure 5, connect the desired V_BUSand shunt

configuration to be measured. Typically, setup involves a high- or low-side load and a shunt resistor

across V_IN+and V_IN–. The example in Figure 5 represents a test scenario with a low-side shunt attached.

The power supply for V_BUSis not included with the kit and is supplied by the customer; the specific voltage

needed depends on your testing needs.

Figure 5. Typical Hardware Test Connections on the INA223EVM

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3.4 Connecting the USB Cable to the SM-USB-DIG Platform

Figure 6 shows the USB connection to the SM-USB-DIG Platform board. The first time you connect to the

PC, the computer typically responds with a Found New Hardware, USB Device pop-up window. The pop-

up window then likely changes to Found New Hardware, USB Human Interface Device. The SM-USB-DIG

®

Platform uses the human interface device drivers that are part of with Microsoft Windows operating

systems.

Figure 6. Connecting the USB Cable to the SM-USB-DIG Platform

In some cases, the Windows Add Hardware Wizard is shown. If this prompt appears, allow the system

device manager to install the human interface drivers by clicking Yes when requested to install drivers.

Windows confirms installation of the drivers with the message shown in Figure 7. This pop-up indicates

that the device is ready to be used.

Figure 7. Confirmation of SM-USB-DIG Platform Driver Installation

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3.5 INA223EVM Default Jumper Settings

Figure 8 shows the default jumper configuration for the INA223EVM. You may want to change some of the

jumpers on the INA223EVM to match your specific configuration. For example, you may wish to set a

specific I²C address by configuring jumper 1 (JMP1) and jumper 2 (JMP2).

Figure 8. INA223EVM Default Jumpers

Jumper 3 (JMP3) on the INA223EVM is typically set to the internal (INT) position. When set to the INT

position, the device supply voltage is generated and controlled from the SM-USB-DIG Platform. When this

jumper is set to the external (EXT) position, INA223 pin 4 (V_S) connects to terminal strip T1 and can be

powered from an external supply.

JMP1 and JMP2 control the I²C address pin for the INA223; these jumpers set the address for A0 to either

high, low, SCL, or SDA. Make sure to connect only one jumper at a time for the address control (for

example, if JMP1 is connected, do not connect JMP2, and vice versa). Failure to properly connect

jumpers can cause shorts or interruptions in the communication lines. For more information on the INA223

addressing, consult the INA223 data sheet (SBOS528).

Table 3 summarizes the function of the INA223 test board jumpers. For most applications, all the jumpers

should be left in their default configurations.

Table 3. INA223 Test Board Jumper Functions

Jumper

JMP1

Default

Open

GND

Description

These jumpers select the I²C AO address selection for A0. Four

separate I²C addresses can be selected,depending on whether JMP2

is set to high or low, or JMP1 is set to SDA or SCL.

JMP2

JMP3

INT

This jumper selects whether the V_Spin on the INA223 is connected to

the digital power-supply signal (VDUT) generated from the SM-USB-

DIG Platform (INT position), or whether the VDUT pin is connected to

terminal T1, thus allowing for an external supply to power the digital

circuitry (EXT position).

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3.6 INA223EVM Hardware

This section describes some of the hardware features present on the INA223EVM board.

3.6.1

JMP3: I²C versus Control Setting

The JMP3 setting determines if the INA223 is powered from the SM-USB-DIG platform or an external

power supply. If JMP3 is set to the INT position, the V_Spin is connected to the switchable VDUT signal

generated from the SM-USB-DIG Platform. This voltage can be set to either 3.3 V or 5 V, depending on

how it is configured in the software.

When JMP3 is set to the EXT position, an external supply connected to terminal T1 must be used to

provide the digital supply voltage for the INA223.

3.6.2

3.6.3

JMP1 and JMP2: I²C Address Hardware Setting (A0)

JMP1 and JMP2 are used to set the hardware setting for the A0 I²C address pin on the INA223. Using

JMP2, the A0 address can be set to either a logic '1' or a logic '0'. Using JMP1, the A0 address can be set

to either the SCL or SDA communication line. Make sure to only have a jumper installed on JMP1 or

JMP2. Failure to keep these lines separate can lead to board shorts and problems with the I²C

communication lines. See the I2C Address Selection section for how to configure the INA223EVM

software to match the JMP1 and JMP2 hardware settings.

External I²C lines and Terminal Block T3

The I²C communication lines on the INA223EVM are tied to two sources: The internal I²C communication

lines from the SM-USB-DIG Platform and terminal block T3. If external signals separate from the SM-USB-

DIG are to be used, simply disconnect the SM-USB-DIG from the INA223 board and connect to external

SDA, SCL, and GND lines. Also, remember to apply an external V_Sthat is compatible with the I²C

communication device being used.

CAUTION

Failure to disconnect the SM-USB-DIG Platform while using external I²C

communication can cause damage to the SM-USB-DIG or external

communication device.

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3.6.4

V_IN+and V_IN–Input Filter (R4, R3, and C3)

The INA223EVM has an optional input filter located between the terminal block T2 and the INA223 input

pins. This filter helps to remove high-frequency noise from the V_IN+and V_IN–inputs. The EVM ships with

this filter not used. C3 is typically unpopulated and R3 and R4 have 0-Ω resistors installed. If filtering is

desired, limit the value for R3 and R4 to 10-Ω or less. Figure 9 shows the typical setup that is

recommended for basic INA223 evaluation. See the INA223 data sheet (SBOS528) for more details.

0 W Resistors

Unpopulated C3

Figure 9. Typical Filter Setup

3.6.5

Shunt Monitor Configuration and Terminal Block T2

The INA223 is typically used in a high-side configuration, as shown in Figure 10. The T2 terminal block

includes the connections for V_IN+and V_IN–, which should be connected directly across the shunt resistor.

Depending on the user’s needs, either of these configurations may be used without any changes needed

to the INA223EVM board or software.

C_BYPASS

R_SHUNT

0.1mF

Power Supply

(0V to 26V)

Load

V_S(Supply Voltage)

Attenuator

R_PULLUP

4.7kW

V_IN-

V_OUT

SCL

SDA

A0

V_IN+

Two-Wire

Interface

INA223

GND

Figure 10. INA223 Shunt Configurations

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4

INA223EVM Software Setup

This section discusses how to install the INA223 software.

4.1 Operating Systems for INA223EVM Software

The INA223 software has been tested on the Microsoft Windows XP operating system (OS) with United

States and European regional settings. This software should also function on other Windows operating

systems.

4.2 INA223 Software Installation

The INA223EVM software is included on the CD that is shipped with the EVM kit. It is also available

through the INA223EVM product folder on the TI web site. To download the software to your system,

insert the disc into an available CD-ROM drive. Navigate to the drive contents and open the INA223EVM

software folder. Locate the compressed file (INA223EVM.zip) and open it. Extract the INA223EVM files

into a folder labeled INA223EVM (for example, C:\INA223EVM) on your hard drive.

After the files are extracted, navigate to the INA223EVM folder you created on your hard drive. Locate the

setup.exe file and run it to start the installation. The INA223 software installer file opens to begin the

installation process, as shown in Figure 11.

Figure 11. Software Install Window

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After the install begins, the user is given the choice of selecting the directory to install the program, usually

defaulting to C:\Program Files\INA223\ and C:\Program Files\National Instruments\. Following this option,

two license agreements are presented that must be accepted, as shown in Figure 12.

Figure 12. Software License Agreement

After accepting the Texas Instruments and National Instruments license agreements, the progress bar

opens and shows the installation of the software, as shown in Figure 13. After the installation process is

complete, click Finish.

Figure 13. Software Install Progress

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5

INA223EVM Software Overview

This section describes how to use the INA223EVM software. The software operation contains a two-step

process: configuration and operation.

5.1 Starting the INA223EVM Software

To start the INA223 software, go to the Windows Start menu, select All Programs, and then select the

INA223EVM program. Figure 14 illustrates how the software should appear if the INA223EVM is

functioning properly.

Figure 14. INA223EVM Software Interface

Figure 15 shows the error that appears if the computer cannot communicate with the EVM. In the event

you receive this error, first ensure that the USB cable is properly connected on both ends. This error can

also occur if you connect the USB cable to your PC before the SM-USB-DIG Platform is connected to the

EVM board. Another possible source for this error is a problem with the computer USB human interface

device driver. Make sure that the device is recognized when the USB cable is plugged in, indicated by a

Windows-generated confirmation sound.

Figure 15. Communication Error with SM-USB-DIG Platform

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5.2 Configuring the INA223 Software

The next steps of this user’s guide describes how to configure the software and hardware for different

configurations.

5.2.1

I²C Address Selection

The INA223 has a flexible I²C address configuration that allows for multiple devices to be on the same I²C

lines. By moving the A0 address on jumpers JMP1 and JMP2 to either GND, VS, SDA or SCL, the INA223

can be changed to four different I²C addresses, as shown in Table 4.

Table 4. INA223 I²C Address Configuration

A0

GND

VS

Address

1000000

1000001

1000010

1000011

SDA

SCL

Figure 16 shows how to configure the I²C addresses. Click on the I²C Address Select button (shown in the

red box) to select how the hardware is configured on the EVM. If the correct address is not selected, the

INA223 cannot communicate with the software.

Figure 16. Setting the A0 Address

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5.2.2

Output Mode

The output mode configuration allows the user to toggle between different output signals generated from

the INA223, and is shown in the red box of Figure 17. The four options available for output mode are:

Shunt Voltage, Bus Voltage, Supply Power, and Load Power.

Figure 17. Configuring the Output Mode

The two power output modes of the INA223EVM is used to select whether the signal representing the

power being supplied by the power supply or the power being consumed by the load is made available at

the output pin. When the Supply Power option is selected, the V_BUSmeasurement is taken internally at the

VIN+ pin of the INA223 and combined with the V_SHUNTmeasurement to calculate the power being supplied.

The Load Power option operates in a similar manner to the Supply Power option, except that the V_BUS

measurement is taken internally at the VIN– pin of the INA223. The power being consumeed by the load

is found by taking the V_BUSmeasurement from the VIN– pin. The Supply Power and Load Power results

are very similar with the exception being that the Load Power option removes the power being dissipated

across the shunt resistor from the result. At high current shunt gains, the differences between Load Power

and Supply Power are negligible. At low current shunt gains, the power dissipated across the sense

resistor can result in a noticeable difference between these two results.

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It is important to note that valid bus voltage and shunt voltage measurements must be within the linear

range of the device in order for the INA223 to correctly calculate power using Equation 1.

POWER = V_OUT/ Power_GAIN× R_SHUNT

(1)

(2)

Where V_OUTis calculated based on Equation 2:

V_OUT= V_CM× V_SENSE× Power_GAIN

and Power_GAINvaluse are shown in Table 5.

Table 5. Power Gain Values

Bus Voltage Gain

Shunt Voltage Gain

Power_GAIN

0.667

4.267

10

1/10

1/5

20

128

300

20

1.333

8.533

20

1/5

128

300

20

1/5

2/5

2.667

17.067

40

2/5

128

300

2/5

The remaining two configurations, Bus Voltage and Shunt Voltage, measure the bus voltages at the VIN-

pin and the shunt voltage developed directly across the shunt resistor, respectively. The actual output

voltage of either measurement is based on the input voltage multiplied by the corresponding gain settings,

as shown in sections Section 5.2.3 and Section 5.2.4.

NOTE: For maximum accuracy, select a gain that gives a full-scale voltage, just below the maximum

output voltage.

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5.2.3

Bus Voltage Gain

The Bus Voltage Gain field allows the user to select the gain that the bus voltage is multiplied by. It is

important to choose a value that places the output voltage within the linear output range of the device.

Failure to ensure that the outputs are within the linear range of the device can result in inaccurate results.

Figure 18. Configuring the Bus Voltage Gain

Current Shunt Voltage Gain

5.2.4

The Current Shunt Voltage Gain field is used to select the device shunt voltage gain setting. It is important

to choose a value that places the output voltage within the linear output range of the device. Failure to

ensure that the outputs are within the linear range of the device can result in inaccurate results.

Figure 19. Configuring the Current Shunt Voltage Gain

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5.3 Using the INA223 Software

5.3.1

Register Table

The register table (shown by the red box in Figure 20) contains information on the internal registers of the

INA223 registers. Each register can be changed on a bit-by-bit basis to allow the user to have total control

of the part, outside the general functionality of the graphical user interface (GUI). Most of this functionality

is displayed in the Configuration Register; however, by selecting the appropriate register and clicking on

the Help w Reg button (shown in Figure 20), the individual use of each bit in each register can be

diagnosed.

Figure 20. Register Table

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5.3.2

Auto-Write and DVDD Voltage

The INA223EVM software allows for customization of the board level voltage, regulated by the SM-USB-

DIG. Select either +3.3V or +5V for the operating voltage of the chip, as shown in the upper red box in

Figure 21.

Figure 21. Auto-Write, Power, and Voltage Controls

The software also includes an Auto-Write feature (as shown in the lower red box in Figure 21). Auto-Write

is enabled by default, and automatically updates the register table whenever a change is made. When this

feature is enabled, the Write all Reg button serves little purpose, and is only used as an alternative for

when this button is disabled.

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5.3.3

Example Hardware Calculator

The Example Hardware Calculator tab allows the user to simulate the analog results of the INA223EVM.

By adjusting the controls on this page, and entering inputs for Vin+ (V), Vin- (V), and Rshunt, the

approximate values for Vout (V) and Power (W) can be estimated. Note that the appropriate output mode

must be selected to ensure accurate results, and that no limitations of the device are violated in the Error

field.

This calculator is used to help ensure that the physical output and settings are operating correctly. The

EVM and device digital communication interface are only designed to configure the device settings. There

is no analog readback available with this EVM. This means that the output voltages shown on this

calculator tab in the software are calculated results based on the parameters entered and not

representative of the measurements of the actual device.

Figure 22. Example Hardware Calculator

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6

INA223EVM Documentation

This section contains the complete bill of materials, schematic diagram, and PCB layout for the

INA223EVM. Documentation information for the SM-USB-DIG Platform can be found in the SM-USB-DIG

Platform User’s Guide (SBOU058), available at the TI web site at http://www.ti.com.

6.1 Bill of Materials

Table 6 lists the bill of materials for the INA223 Test Board.

Table 6. Bill of Materials

Digikey

Part Number

Manufacturer

Part Number

Ref Des

R1, R2

R5

Description

Manufacturer

RES 10K OHM 1/10W 5% 0603 SMD

RES 300 OHM 1/10W 5% 0603 SMD

RES 0.0 OHM 1/10W 0603 SMD

CAP TANTALUM 4.7UF 35V 10% SM

CAP CER .10UF 25V X7R 10% 0603

LED GREEN WIDE ANGLE 0603 SMD

INA223

Stackpole Electronics

Panasonic

RMCF0603JT10K0CT-ND

P300GCT-ND

RMCF0603JT10K0

ERJ-3GEYJ301V

RMCF0603ZT0R00

TAJC475K035RNJ

C1608X7R1E104K

LNJ3W0C83RA

R3, R4

C2

Stackpole Electronics

AVX Corp

RMCF0603ZT0R00CT-ND

478-1717-1-ND

C3, C4

D1

TDK Corp

445-1316-1-ND

Panasonic

P14140CT-ND

U1

Texas Instruments

Samtec

Jumpers All

Test Points All

T3

CONN HEADER 50POS .100" SGL GOLD

PC TEST POINT COMPACT SMT

3Block Terminal 3.5mm

SAM1029-50-ND

5016KCT-ND

ED2636-ND

TSW-150-07-G-S

5016

Keystone Electronics

On Shore Technology Inc

3M

OSTTE030161

ED555/2DS

T1, T2

Bumpons

H1

2Block Terminal 3.5mm

ED1514-ND

BUMPON .50X.14 BLACK

SJ5012-0-ND

ED8850-ND

SJ-5012 (BLACK)

851-93-10-20-001000

CONN SOCKET RT ANG 1POS .050

Mill-Max Manufacturing

22

INA223EVM User’s Guide and Software Tutorial

SBOU125–June 2012

Submit Documentation Feedback

INA223EVM Documentation

www.ti.com

6.3 PCB Component Layout

Figure 24 shows the layout of the components for the INA223EVM PCB.

Figure 24. INA223EVM PCB Component Layout

24

INA223EVM User’s Guide and Software Tutorial

SBOU125–June 2012

Submit Documentation Feedback

Evaluation Board/Kit Important Notice

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This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR EVALUATION PURPOSES

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EVM Warnings and Restrictions

It is important to operate this EVM within the input voltage range of 0 V to 26 V and the output voltage range of 0 V to 5.5 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 +25°C. The EVM is designed to operate

properly with certain components above +25°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.

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型号：	ERJ-3GEYJ301V
厂家：	TEXAS INSTRUMENTS
描述：	INA223EVM Userâs Guide and Software Tutorial INA223EVM USERA ????指南和软件教程
文件：	总26页 (文件大小：1323K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

ERJ-3GEYJ301V [TI]

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