TI ERJ-3GEYJ301V

User's Guide
SBOU124 – March 2012
INA230EVM Evaluation Board and Software Tutorial
This user's guide describes the characteristics, operation, and use of the INA230EVM evaluation board. It
discusses how to set up and configure the software and hardware, and reviews various aspects of the
program operation. Throughout this document, the terms evaluation board, evaluation module, and EVM
are synonymous with the INA230EVM. 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.
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Contents
Overview ..................................................................................................................... 3
INA230EVM Hardware Setup ............................................................................................. 4
INA230EVM Hardware ..................................................................................................... 6
INA230EVM Software Setup ............................................................................................. 12
INA230EVM Software Overview ......................................................................................... 15
INA230EVM Documentation ............................................................................................. 23
List of Figures
1
Hardware Included with INA230EVM Kit................................................................................. 3
2
INA230EVM Hardware Setup ............................................................................................. 4
3
INA230EVM Test Board Block Diagram ................................................................................. 4
4
SM-USB-DIG Platform Block Diagram ................................................................................... 5
5
Typical Hardware Test Connections for the INA230EVM
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.............................................................
Connecting the USB Cable to the SM-USB-DIG Platform.............................................................
Confirmation of SM-USB-DIG Platform Driver Installation.............................................................
INA230EVM Default Jumper Settings ....................................................................................
Typical Filter Setup ........................................................................................................
INA230 Shunt Configurations ............................................................................................
INA230EVM Software Installation .......................................................................................
INA230EVM License Agreements .......................................................................................
INA230EVM Software Installation Progress ...........................................................................
INA230EVM Software Interface .........................................................................................
INA230EVM Software: Communication Error with the SM-USB-DIG Platform....................................
Setting the A1 Address ...................................................................................................
Configuring Operating Mode .............................................................................................
Configuring Conversion Times...........................................................................................
Setting the Configuration Register (Calibration Register) ............................................................
Setting the Configuration Register (Current LSB) .....................................................................
Configuring the Alert Pin..................................................................................................
INA230 Results Bar .......................................................................................................
Theory of Operation Flowchart on the Calculation Tab ..............................................................
Registers Tab ..............................................................................................................
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Microsoft, Windows are registered trademarks of Microsoft Corporation.
I2C is a trademark of NXP Semiconductors.
WinZIP is a registered trademark of WinZip International LLC.
All other trademarks are the property of their respective owners.
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25
Graphing the INA230 Data ............................................................................................... 22
26
Auto-Write, Power Button, and Voltage Control ....................................................................... 22
27
INA230EVM Schematic ................................................................................................... 23
28
INA230EVM PCB Top Layer (Component Side) ...................................................................... 24
List of Tables
2
1
INA230EVM Kit Contents .................................................................................................. 3
2
Related Documentation .................................................................................................... 4
3
Signal Definition of J1 on INA230EVM Board ........................................................................... 5
4
INA230EVM Test Board Jumper Functions ............................................................................. 9
5
INA230 I2C Address Configuration ...................................................................................... 16
6
Bill of Materials: INA230EVM
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Overview
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1
Overview
The INA230 is a high-side current sensor and power monitor with an I2C™ interface. The INA230 monitors
both current and supply voltage, with programmable conversion times and averaging modes. The
INA230EVM is a platform for evaluating the performance of the INA230 under various signal, shunt, and
supply conditions.
This document gives a general overview of the INA230EVM, and provides a general description of the
features and functions to be considered while using this evaluation module.
1.1
INA230EVM Kit Contents
Table 1 summarizes the contents of the INA230EVM kit. 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 also check the INA230 product folder on the TI web site at www.ti.com to
verify that you have the latest versions of the related software.
Table 1. INA230EVM Kit Contents
Item
Quantity
INA230EVM PCB Test Board
1
SM-USB-DIG Platform PCB
1
USB Extender Cable
1
SM-Dig Connector Ribbon Cable
1
User’s Guide CD-ROM
1
INA230EVM Board
USB SM-DIG
SM-DIG Connector Ribbon Cable
USB Extender Cable
Figure 1. Hardware Included with INA230EVM Kit
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INA230EVM Hardware Setup
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Related Documentation from Texas Instruments
The following documents provide information regarding Texas Instruments' integrated circuits used in the
assembly of the INA230EVM. This user's guide is available from the TI web site under literature number
SBOU124. 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 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 2. Related Documentation
Document
2
Literature Number
INA230 Product Data Sheet
SBOS601
SM-USB-DIG Platform User Guide
SBOU098
INA230EVM Hardware Setup
INA230EVM
USB SM-DIG
Shunt
PC
Figure 2 shows the overall system setup for the INA230EVM. The PC runs software that communicates
with the SM-USB-DIG Platform. The SM-USB-DIG Platform generates the analog and digital signals used
to communicate with the INA230 test board. Connectors on the INA230EVM test board allow the user to
connect to the system under test conditions to monitor the power, current, and voltage.
Figure 2. INA230EVM Hardware Setup
2.1
Theory of Operation for INA230 Hardware
A block diagram of the INA230 test board hardware setup is shown in Figure 3. The PCB provides
connections to the I2C interface and general-purpose inputs/outputs (GPIOs) on the SM-USB-DIG Platform
board. The PCB also provides connection points for external connections of the shunt voltage, bus
voltage, and ground.
Shunt
Terminals
10-Pin SM-DIG Connector
T3, T4
Vdut Supply
(DVDD)
4
J3, J4
A0
J1
INA230
2
I C Address Jumpers
A1
2
I C Interface
J5, J6
Figure 3. INA230EVM Test Board Block Diagram
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2.2
Signal Definitions of H1 (10-Pin Male Connector Socket)
Table 3 lists the pinout for the 10-pin connector socket used to communicate between the INA230EVM
and the SM-USB-DIG. It should be noted that the INA230EVM only uses the necessary I2C
communication lines (pins 1 and 3) and the VDUT and GND pins (pin 6 and pin 8) to issue commands to
the INA230 chip.
Table 3. Signal Definition of J1 on INA230EVM Board
(1)
2.2.1
Pin on J1
Signal
Description
1
I2C_SCL
I2C Clock Signal (SCL)
2
CTRL/MEAS4
GPIO: Control Output or Measure
Input
3
I2C_SDA1
I2C Data Signal (SDA)
4
CTRL/MEAS5
GPIO: Control Output or Measure
Input
5
SPI_DOUT1
SPI Data Output (MOSI)
6
VDUT
Switchable DUT Power Supply: +3.3
V, +5 V, Hi-Z (Disconnected) (1)
7
SPI_CLK
SPI Clock Signal (SCLK)
8
GND
Power Return (GND)
9
SPI_CS1
SPI Chip Select Signal (CS)
10
SPI_DIN1
SPI Data Input (MISO)
When VDUT is Hi-Z, all digital I/O are Hi-Z as well.
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 (available for download at www.ti.com). The
block diagram shown in Figure 4 gives a brief overview of the platform. The primary control device on the
SM-USB-DIG Platform is the TUSB3210. The TUSB3210 is an 8052 microcontroller that has an onboard
USB interface. The microcontroller receives information from the host computer that it interprets 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.
SM-USB-DIG
3.3-V
Regulator
USB
+5.0 V
To Computer
and Power Supplies
+3.3 V
TUSB32108052
Microcontroller
with USB Interface
and UART
USB Bus
from Computer
Power-On
Reset
2
Buffers and
Level
Translators
IC
SPI
Control Bits
Measure Bits
To Test Board
8-K ´ 8-Byte
EEPROM
USB +5.0 V
+3.3 V
Power
Switching
Vdut
(Hi-Z, 3.3V or 5V)
Switched Power
Figure 4. SM-USB-DIG Platform Block Diagram
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INA230EVM Hardware
Setting up the INA230EVM hardware involves connecting the two PCBs of the EVM together, applying
power, connecting the USB cable, and setting the jumpers. This section presents the details of this
procedure.
3.1
Electrostatic Discharge Warning
CAUTION
Many of the components on the INA230EVM 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 set up the INA230EVM and connect the two PCBs of the EVM together (that is, the INA230 Test Board
and SM-USB-DIG Platform board), 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.
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3.3
Connecting Power
After the EVM and SM-USB-DIG are conjoined, as Figure 5 illustrates, connect the desired VBUS and shunt
configuration intended to be measured. Typically, setup involves a high- or low-side load and a shunt
resistor across VIN+ and VIN–. The setup in Figure 5 represents a test scenario with a low-side shunt
attached. This source for VBUS is not included with the kit, and its voltage may differ depending on your
testing needs. The external power source is connected to the terminal strip T3.
NOTE: It is always necessary to connect the power to the SM-USB-DIG Platform board before
connecting the USB cable.
Figure 5. Typical Hardware Test Connections for the INA230EVM
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Connecting the USB Cable to the SM-USB-DIG Platform
Once power is connected, as shown in Figure 6, the computer typically responds with a Found New
Hardware, USB Device pop-up dialog. The pop-up window typically changes to Found New Hardware,
USB Human Interface Device. This pop-up indicates that the device is ready to be used. The SM-USBDIG Platform uses the human interface device drivers that are part of the Microsoft® Windows® operating
system.
Figure 6. Connecting the USB Cable to the SM-USB-DIG Platform
In some cases, the Windows Add Hardware Wizard may pop up. If this prompt appears, allow the system
device manager to install the human interface drivers by clicking Yes when requested to install drivers.
Windows then confirms installation of the drivers with the message shown in Figure 7.
Figure 7. Confirmation of SM-USB-DIG Platform Driver Installation
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3.5
INA230EVM Default Jumper Settings
Figure 8 shows the default jumper configuration for the INA230EVM. In general, the jumper settings of the
SM-USB-DIG Platform do not need to be changed. You may want to change some of the jumpers on the
INA230EVM board to match your specific configuration. For example, you may wish to set a specific I2C
address by configuring J3-J6.
Figure 8. INA230EVM Default Jumper Settings
Typically, jumper 2 on the INA230EVM is always set to the INT position. When set to the INT position, the
SM-USB-DIG Platform provides the supply for the INA230. When this jumper is set to the EXT position, an
external supply voltage can be connected to terminal strip T2 to provide the supply for the INA230.
Jumpers 3 through 6 control the I2C address pins for the INA230. These jumpers can set the address for
A0 and A1 to either supply, ground, SCL, or SDA. Make sure to only connect one jumper at a time for
each address control. Failure to properly connect jumpers can cause shorts or interruptions in the
communication lines. For more information on the INA230 addressing, refer to the INA230 product data
sheet.
Table 4 summarizes the function of the INA230 Test Board jumpers. For most applications, all jumpers
should be left in the respective default configurations.
Table 4. INA230EVM Test Board Jumper Functions
Jumper
Default
Purpose
J2
INT
This jumper selects whether the VS pin
on the INA230 is connected to the VDUT
signal generated from the SM-USB-DIG
Platform or whether the digital supply pin
is connected to terminal T2, allowing for
an external supply to power the device.
The default INT position connects the VS
pin to the VDUT control signal.
J3/J4
GND
This jumper selects the I2C A0 address
selection for A0.
J5/J6
GND
This jumper selects the I2C A1 address
selection for A1.
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INA230EVM Features
This section describes some of the hardware features present on the INA230EVM test board.
3.6.1
J2: I2C VS Control Setting
Jumper J2 selects what the INA230 supply pin is connected to. If J2 is set to the INT position, the VS pin 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. While J4 is set in the INT
position, the VS Power button in the INA230EVM software is able to control whether the VDUT supply
voltage is turned on or off.
When J2 is set in the EXT position, an external supply connected to terminal T2 can be used to provide
the supply voltage for the INA230.
3.6.2
J3 and J4: I2C Address Hardware Setting (A0)
Jumpers J3 and J4 are used to set the hardware setting for the A0 I2C address pin on the INA230. Using
J3, the A0 address can be set to either a logic '1' or a logic '0'. Using J4, the A0 address can be set to
either the SCL or SDA communication line. Make sure to only have either J3 or J4 connected individually;
failure to keep these lines separate can lead to board shorts and problems with the I2C communication
lines. See Section 5.2.1 on how to configure the INA230EVM software to match the J3/J4 hardware
setting.
3.6.3
J5 and J6: I2C Address Hardware Setting (A1)
Jumpers J5 and J6 are used to set the hardware setting for the A1 I2C address pin on the INA230. Using
J3, the A1 address can be set to either a logic '1' or a logic '0'. Using J4, the A1 address can be set to
either the SCL or SDA communication line. Make sure to only have either J5 or J6 connected individually;
failure to keep these lines separate can lead to board shorts and problems with the I2C communication
lines. See Section 5.2.1 on how to configure the INA230EVM software to match the J5/J6 hardware
setting.
3.6.4
External I2C Lines and Terminal Block T1
The I2C communication lines on the INA230EVM are tied to two sources: the internal I2C communication
lines from the SM-USB-DIG and the terminal block T1. If the user wants to add external signals separate
from the SM-USB-DIG, simply disconnect the SM-USB-DIG from the INA230EVM board and hook up the
necessary SDA, SCL, and GND lines. Also, remember to apply an external supply to the lines that is
compatible with the I2C communication device being used.
NOTE: Failure to disconnect the SM-USB-DIG while using external I2C communication can cause
damage to the SM-USB-DIG or any external communication devices that are connected.
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3.6.5
VIN+ and VIN– Input filter (R1, R2, and C1)
The INA230EVM has an optional input filter to remove high-frequency noise from the inputs VIN+ and
VIN–. This filter is typically unpopulated. The default values for R1 and R2 are 0-Ω resistors. Figure 9
shows the typical setup, which is recommended for basic INA230 evaluation.
0-W Resistors
Unpopulated C1
Figure 9. Typical Filter Setup
3.6.6
Shunt Monitor Configuration and Terminal Blocks T3 and T4
The INA230 is generally used in either a high-side or low-side shunt configuration, as shown in Figure 10.
Terminal block T3 represents VBUS and ground, while terminal block T4 represents VIN+ and VIN–.
Depending on the user’s needs, either of these configurations may be used without making any changes
to the INA230EVM board or software.
Figure 10. INA230 Shunt Configurations
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INA230EVM Software Setup
This section discusses how to install the INA230EVM software.
4.1
Operating Systems for the INA230EVM Software
The INA230EVM software has been tested on Microsoft® Windows® XP operating systems (OS) with
United States and European regional settings. The software should also function on other Windows OS
platforms.
4.2
Software Installation
The INA230EVM software is included on the CD that is shipped with the EVM kit. It is also available
through the INA230EVM product folder on www.ti.com. To install the software to a computer, insert the
disc into an available CD-ROM drive. Navigate to the drive contents and open theINA230EVM software
folder. Locate the compressed file (INA230EVM.zip) and open it using WinZIP® or a similar file
compression program; extract the INA230EVM files into a specific INA230EVM folder (for example,
C:\INA230EVM) on your hard drive.
Once the files are extracted, navigate to the INA230EVM folder you created on the hard drive. Locate the
setup.exe file and execute it to start the installation. The INA230 software installer file then begins the
installation process as shown in Figure 11.
Figure 11. INA230EVM Software Installation
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After the installation process initializes, the user is given the choice of selecting the directory in which to
install the program; the default location is C:\Program Files\INA230\ and C:\Program Files\National
Instruments\. Following this option, two license agreements are presented that must be accepted, as
shown in Figure 12. After accepting the Texas Instruments and National Instruments license agreements,
the progress bar opens and shows the installation of the software, as Figure 13 illustrates. Once the
installation process is completed, click Finish.
Figure 12. INA230EVM License Agreements
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Figure 13. INA230EVM Software Installation Progress
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5
INA230EVM Software Overview
This section discusses how to use the INA230EVM software. Software operation involves a two-step
process: configuration of the INA230 settings, and operation of the tool.
5.1
Starting the INA230EVM Software
The INA230 software can be operated through the Windows Start menu. From Start, select All Programs;
then select the INA230EVM program.
Figure 14 illustrates how the software should appear if the INA230EVM is functioning properly.
Figure 14. INA230EVM Software Interface
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Figure 15 shows an error that pops up if the computer cannot communicate with the EVM. If you receive
this error, first check to see that the USB cable is properly connected on both ends. This error can also
occur if you connect the USB cable before the SM-USB-DIG Platform power source. Another possible
source for this error is a problem with your PC USB Human Interface Device driver. Make sure that the
device is recognized when the USB cable is plugged in; recognition is indicated by a Windows-generated
confirmation sound.
Figure 15. INA230EVM Software: Communication Error with the SM-USB-DIG Platform
5.2
Configuring the INA230EVM Software
The INA230EVM software first requires a series of setup processes to configure the device and ensure
that it works properly. On the Configuration tab (see Figure 14), there are six steps noted:
Step 1. Set I2C Address
Step 2. Configure Operation
Step 3. Set Conversion Times
Step 4. Select Configuration Method
Step 5. Set Configuration Register
Step 6. Configure Alert Pin
This section explains how to configure the software and reviews some of the different setups that can be
done.
5.2.1
I2C Address Selection
The INA230 device has a flexible I2C address configuration that allows for multiple devices to be on the
same I2C lines. By moving the A0 and A1 addresses on jumpers J3-J6 to either GND, VS, SDA or SCL,
the INA230 can be changed to a total of 16 I2C addresses as shown in Table 5.
Table 5. INA230 I2C Address Configuration
16
A1
A0
Slave Address
GND
GND
1000000
GND
VS+
1000001
GND
SDA
1000010
GND
SCL
1000011
VS+
GND
1000100
VS+
VS+
1000101
VS+
SDA
1000110
VS+
SCL
1000111
SDA
GND
1001000
SDA
VS+
1001001
SDA
SDA
1001010
SDA
SCL
1001011
SCL
GND
1001100
SCL
VS+
1001101
SCL
SDA
1001110
SCL
SCL
1001111
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Figure 16 illustrates how to configure the I2C addresses. Click on either the A0 or A1 box and select how
the hardware is configured on the EVM. Failure to select the correct address prevents the INA230 device
from communicating with the software.
Figure 16. Setting the A1 Address
5.2.2
Configure Operating Mode
The second step of the INA230EVM configuration process allows the user to set the operating mode and
the averaging mode.
The Operating mode allows the user to restrict the amount of calculations done within the INA230 by
changing the conversion to be triggered or continuous, or shutting down the part altogether. When the
device is operating in triggered mode, it only performs conversions when the operating mode is set and
the Write All Reg button at the top of the screen is selected. After the mode changes and Write All Reg
has been selected, the Read All Reg button must also be selected in order for the changes on the device
to be reflected in the software.
When the INA230 is operating in continuous mode, conversions are performed directly after the previous
conversion is completed. When the INA230EVM software is in continuous mode, the software can be
updated at any time by pressing the Read All Reg button.
Power Down mode stops all conversions from taking place until the operating mode changes again. The
device remains attached to power but draws minimal current and does not perform any conversions.
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All three operating modes can also be limited to only measuring certain components of the device, as
shown in Figure 17. It is important to note that for complete functionality of the INA230, a configuration
must be chosen with Shunt and Bus configuration. Failure to choose Shunt and Bus configuration disables
a considerable portion of the unit functionality as discussed in the INA230 data sheet.
Figure 17. Configuring Operating Mode
The Configure Operation step also contains a drop down box for selecting the Averaging Mode. The
INA230 can be setup to take the average of several measurements before storing the value of the
measurements in the register table.
5.2.3
Set Conversion Times
Setting the conversion times allows the user to customize the amount of measurement time for
conversions. Typically, for the INA230EVM software, the user is not able to notice a visual difference
between the conversion times unless a high averaging mode and conversion time are chosen. The Shunt
and Bus conversion times can be set as shown in Figure 18.
Figure 18. Configuring Conversion Times
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5.2.4
Set Configuration Register
The Configuration Register must then be set correctly for the software to operate properly. There are two
methods used to set the Configuration Register: first, the user can manually calculate the desired value
and then input that value into the register table, as shown in Equation 1.Alternatively, the user can allow
the software to create a recommended window and choose an LSB for the current as shown in Figure 20.
Both methods accomplish the same goal by using Equation 1, but the method is selected by changing the
value in Step 4: Select Configuration Method (as Figure 19 and Figure 20 show).
0.00512
Calibration Register =
CurrentLSB ´ RSHUNT
(1)
The current LSB is calculated by a recommended range in the INA230 data sheet as shown in Equation 2.
It is important to note that with either of the methods used, the Current LSB and the Calibration Register
values are calculated based on the other variable and the RSHUNT value. See the section, Programming the
INA230 in the product data sheet for more information on setting the Calibration Register value.
Max Expected Current
Max Expected Current
£ CurrentLSB £
215
212
(2)
Figure 19. Setting the Configuration Register
(Calibration Register)
5.2.5
Figure 20. Setting the Configuration Register (Current
LSB)
Configuring the Alert Pin
The Alert Pin from the INA230 allows the user to set limits that monitor the registers and trigger a flag
when they are exceeded. The register that is being monitored can be changed by selecting the desired
alert configuration as shown in Figure 21. The value that is being considered is compared to the Alert
Limit box. This Alert Limit box modifies its functionality based on the selected configuration. It is important
to note that by default, the INA230 Alert pin is set to active low.
Figure 21. Configuring the Alert Pin
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In addition to the INA230EVM software alert configuration, the Alert Configuration box includes the
Conversion Ready button that allows for a special functionality on the Alert pin. When the INA230
completes the conversions for its current operation, it triggers the Alert pin and notifies the user that
another conversion can be performed. In most cases, the INA230 conversion ready flag is not visible
because of the speed of the INA230 conversion process.
5.3
Using the INA230EVM Software
After configuring the INA230EVM software, the rest of the tabs can be evaluated. This section describes
the basic operation of the device, and offers guidelines for interpreting the graphic user interface (GUI).
5.3.1
INA230 Bus Voltage, Shunt Voltage, Current, and Power Reading Bar
The bottom bar of the INA230 software, as shown in Figure 22, allows the user to constantly check the
status of the INA230 unit itself. These values are updated each time the Read All Reg button is pressed
at the top of the software. In addition to the register values stored in the part, the software also includes
flags for when the part is ready to trigger another conversion and when the Alert pin is triggered.
Figure 22. INA230 Results Bar
5.3.2
Calculation and Theory of Operation
The Calculation tab, as shown in Figure 23, allows the user to follow the software flow with basic
calculations performed from within the device. It is important to note that the calculations are performed
with the decimal values of the corresponding registers.
Figure 23. Theory of Operation Flowchart on the Calculation Tab
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5.3.3
Register Tab
The Register tab contains information on the individual operation of the INA230 registers. Each register
can be changed on a bit-by-bit basis to allow the user to have total control of the device beyond the
general functionality of the GUI alone. Most of this functionality is displayed in the Configuration register
tab, but by selecting the appropriate register and clicking on the Help With Reg button on the Register
tab, as shown in Figure 24, the user can diagnose the individual uses of each bit in each register.
Figure 24. Registers Tab
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INA230EVM Software Overview
5.3.4
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Graph Tab
The Graph tab contains a plot window that shows the progression of data over time on the INA230. All
four variables at the bottom of the EVM software (VBUS, VSHUNT, Current, and Power) can be plotted using
the drop-down box directly above the graph. After the desired plot has been selected, toggle the
Continuously Poll Data button above the plot to begin polling for data. If the user desires to save the
data from the plot, simply select the USB Controls drop-down at the top of the page, then select the Start
Graph Log option. Once the Start Graph Log has been selected, the user is prompted to select a location
for the data and to name the file.
Figure 25. Graphing the INA230 Data
5.3.5
Auto-Write and the Supply Voltage
The INA230EVM software allows users to customize the board level voltage, regulated by the SM-USBDIG. By selecting either 3.3 V or 5 V, the user can designate which voltage the device should operate at.
The software also includes an Auto-Write feature as shown in Figure 26, which is enabled by default. This
feature automatically updates the register table whenever a change is made. When this feature is
enabled, the Write All Registers button serves little purpose and is only used as an alternative to when
AutWrite is disabled.
Figure 26. Auto-Write, Power Button, and Voltage Control
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6
INA230EVM Documentation
This section contains the complete bill of materials, schematic diagram, and PCB layout for the
INA230EVM.
NOTE: The board layout is not to scale. This image is intended to show how the board is laid out; it
is not intended to be used for manufacturing INA230EVM PCBs.
6.1
Schematic
Figure 27 shows the schematic for the INA230EVM.
Figure 27. INA230EVM Schematic
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INA230EVM Documentation
6.2
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PCB Layout
Figure 28 shows the component layout for the INA230EVM PCB.
Figure 28. INA230EVM PCB Top Layer (Component Side)
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6.3
Bill of Materials
Table 6 lists the bill of materials for the INA230EVM.
Table 6. Bill of Materials: INA230EVM
Item No.
Ref Des
1
R5, R6
Resistor, 10 kΩ 1/10 W 5% 0603 SMD
Description
Stackpole Electronics
Vendor/Mfr
RMCF0603JT10K0
Part Number
2
R3, R4
Resistor, 300 Ω 1/10 W 5% 0603 SMD
Panasonic
ERJ-3GEYJ301V
3
R1, R2
Resistor, 0.0 Ω 1/10 W 0603 SMD
Stackpole Electronics
RMCF0603ZT0R00
4
C2
5
Capacitor, Tantalum 4.7 μF 35 V 10% SM AVX Corp.
TAJC475K035RNJ
C3, C4
Capacitor, Ceramic 0.10 μF 25 V X7R
10% 0603
TDK Corp.
C1608X7R1E104K
6
D1, D2
LED Green Wide Angle 0603 SMD
Panasonic
LNJ3W0C83RA
7
U1
INA230
Texas Instruments
8
Jumpers All
Connector, Header 50-Position .100" SGL Samtec
Gold
TSW-150-07-G-S
9
Jumpers All
Shunt LP w/Handle 2-Pos 30AU
Tyco Electronics
881545-2
10
Test Points All
PC Test Point Compact SMT
Keystone Electronics
5016
11
T1
3-Block Terminal 3.5 mm
On Shore Technology Inc
ED555/3DS
12
T2, T3, T4
2-Block Terminal 3.5 mm
On Shore Technology Inc
ED555/2DS
13
Bumpons
Bumpon Hemisphere 0.50 x 0.14 Clear
3M
SJ-5312 (CLEAR)
14
J1
Connector, Socket RT Angle 1-Position
0.050
Mill-Max Manufacturing
851-93-10-20-001000
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