HPA00900AIDCNR_技术文档

INA219

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SBOS448F –AUGUST 2008–REVISED SEPTEMBER 2011

Zerø-Drift, Bi-Directional

CURRENT/POWER MONITOR with I²C™ Interface

Check for Samples: INA219

1

FEATURES

DESCRIPTION

The INA219 is a high-side current shunt and power

23

•

SENSES BUS VOLTAGES FROM 0V TO +26V

REPORTS CURRENT, VOLTAGE, AND POWER

16 PROGRAMMABLE ADDRESSES

monitor with an I²C interface. The INA219 monitors

both shunt drop and supply voltage, with

•

programmable conversion times and filtering.

A

programmable calibration value, combined with an

internal multiplier, enables direct readouts in

amperes. An additional multiplying register calculates

power in watts. The I²C interface features 16

programmable addresses.

HIGH ACCURACY: 0.5% (Max) OVER

TEMPERATURE (INA219B)

•

FILTERING OPTIONS

CALIBRATION REGISTERS

SOT23-8 AND SO-8 PACKAGES

The INA219 is available in two grades: A and B. The

B grade version has higher accuracy and higher

precision specifications.

APPLICATIONS

•

SERVERS

The INA219 senses across shunts on buses that can

vary from 0V to 26V. The device uses a single +3V to

+5.5V supply, drawing a maximum of 1mA of supply

current. The INA219 operates from –40°C to +125°C.

TELECOM EQUIPMENT

NOTEBOOK COMPUTERS

POWER MANAGEMENT

BATTERY CHARGERS

WELDING EQUIPMENT

POWER SUPPLIES

TEST EQUIPMENT

RELATED PRODUCTS

DESCRIPTION

DEVICE

Current/Power Monitor with Watchdog,

Peak-Hold, and Fast Comparator Functions

INA209

Zerø-Drift, Low-Cost, Analog Current Shunt

Monitor Series in Small Package

INA210, INA211, INA212,

INA213, INA214

V_S

V_IN+V_IN-

(Supply Voltage)

INA219

Power Register

´

Data

CLK

A0

I²C

Interface

Current Register

PGA

ADC

A1

Voltage Register

GND

1

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas

Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

2

3

I²C is a trademark of NXP Semiconductors.

All other trademarks are the property of their respective owners.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

INA219

SBOS448F –AUGUST 2008–REVISED SEPTEMBER 2011

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This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with

appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.

ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more

susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.

Table 1. PACKAGING INFORMATION⁽¹⁾

PRODUCT

PACKAGE-LEAD

SO-8

PACKAGE DESIGNATOR

PACKAGE MARKING

D

I219A

A219

I219B

B219

INA219A

SOT23-8

SO-8

DCN

D

INA219B

SOT23-8

DCN

(1) For the most current package and ordering information see the Package Option Addendum at the end of this document, or visit the

INA219 product folder at www.ti.com.

ABSOLUTE MAXIMUM RATINGS⁽¹⁾

Over operating free-air temperature range (unless otherwise noted).

INA219

UNIT

V

Supply Voltage, V_S

6

(2)

Differential (V_IN+) – (V_IN–

)

–26 to +26

V

Analog Inputs,

V_IN+, V_IN–

Common-Mode

-0.3 to +26

V

SDA

SCL

GND – 0.3 to +6

V

GND – 0.3 to V_S+ 0.3

V

Input Current Into Any Pin

Open-Drain Digital Output Current

Operating Temperature

Storage Temperature

5

10

mA

°C

V

–40 to +125

–65 to +150

+150

Junction Temperature

Human Body Model

4000

ESD Ratings

Charged-Device Model

Machine Model (MM)

750

V

200

V

(1) Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may

degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond

those specified is not implied.

(2) V_IN+and V_IN–may have a differential voltage of –26V to +26V; however, the voltage at these pins must not exceed the range –0.3V to

+26V.

2

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ELECTRICAL CHARACTERISTICS: V_S= +3.3V

Boldface limits apply over the specified temperature range, T_A= –25°C to +85°C.

At T_A= +25°C, V_IN+= 12V, V_SENSE= (V_IN+– V_IN–) = 32mV, PGA = ÷ 1, and BRNG⁽¹⁾= 1, unless otherwise noted.

INA219A

INA219B

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

MIN

TYP

MAX

UNIT

INPUT

Full-Scale Current Sense (Input) Voltage Range

PGA = ÷ 1

PGA = ÷ 2

PGA = ÷ 4

PGA = ÷ 8

BRNG = 1

BRNG = 0

V_IN+= 0V to 26V

PGA = ÷ 1

PGA = ÷ 2

PGA = ÷ 4

PGA = ÷ 8

0

±40

±80

±160

±320

32

0

±40

±80

±160

±320

32

mV

V

0

Bus Voltage (Input Voltage) Range⁽²⁾

0

16

0

16

V

Common-Mode Rejection

Offset Voltage, RTI⁽³⁾

CMRR

100

120

±10

±20

±30

±40

0.1

10

100

120

±10

±20

±30

±40

0.1

10

dB

V_OS

±100

±125

±150

±200

±50⁽⁴⁾

±75

μV

±75

μV

±100

μV

vs Temperature

vs Power Supply

Current Sense Gain Error

vs Temperature

Input Impedance

V_IN+Pin

μV/°C

μV/V

m%

m%/°C

PSRR

V_S= 3V to 5.5V

Active Mode

±40

1

±40

1

20

μA

V_IN–Pin

20 || 320

μA || kΩ

Input Leakage⁽⁵⁾

Power-Down Mode

V_IN+Pin

0.1

±0.5

0.1

±0.5

μA

V_IN–Pin

DC ACCURACY

ADC Basic Resolution

1 LSB Step Size

Shunt Voltage

12

Bits

10

4

10

4

μV

mV

%

Bus Voltage

Current Measurement Error

over Temperature

Bus Voltage Measurement Error

over Temperature

Differential Nonlinearity

ADC TIMING

±0.2

±0.5

±1

±0.2

±0.3

±0.5

±1

%

±0.2

±0.1

±0.5

±1

±0.2

±0.1

%

LSB

ADC Conversion Time

12-Bit

11-Bit

10-Bit

9-Bit

532

276

148

84

586

304

163

93

532

276

148

84

586

304

163

93

μs

Minimum Convert Input Low Time

4

(1) BRNG is bit 13 of the Configuration Register.

(2) This parameter only expresses the full-scale range of the ADC scaling. In no event should more than 26V be applied to this device.

(3) Referred-to-input (RTI).

(4) Shaded cells indicate improved specifications of the INA219B.

(5) Input leakage is positive (current flowing into the pin) for the conditions shown at the top of the table. Negative leakage currents can

occur under different input conditions.

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ELECTRICAL CHARACTERISTICS: V_S= +3.3V (continued)

Boldface limits apply over the specified temperature range, T_A= –25°C to +85°C.

At T_A= +25°C, V_IN+= 12V, V_SENSE= (V_IN+– V_IN–) = 32mV, PGA = ÷ 1, and BRNG⁽¹⁾= 1, unless otherwise noted.

INA219A

INA219B

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

MIN

TYP

MAX

UNIT

SMBus

SMBus Timeout⁽⁶⁾

28

35

28

35

ms

DIGITAL INPUTS

(SDA as Input, SCL, A0, A1)

Input Capacitance

3

pF

Leakage Input Current

Input Logic Levels:

0 ≤ V_IN≤ V_S

0.1

1

0.1

1

6

μA

V_IH

0.7 (V_S)

6

0.7 (V_S)

V

V_IL

–0.3

0.3 (V_S)

–0.3

0.3 (V_S)

V

Hysteresis

500

mV

OPEN-DRAIN DIGITAL OUTPUTS (SDA)

Logic '0' Output Level

High-Level Output Leakage Current

POWER SUPPLY

I_SINK= 3mA

V_OUT= V_S

0.15

0.1

0.4

1

0.15

0.1

0.4

1

V

μA

Operating Supply Range

Quiescent Current

+3

+5.5

1

+3

+5.5

1

V

mA

μA

V

0.7

6

0.7

6

Quiescent Current, Power-Down Mode

Power-On Reset Threshold

TEMPERATURE RANGE

Specified Temperature Range

Operating Temperature Range

Thermal Resistance⁽⁷⁾

SOT23-8

15

2

–25

–40

+85

–25

–40

+85

°C

+125

θ_JA

142

120

142

120

°C/W

SO-8

(6) SMBus timeout in the INA219 resets the interface any time SCL or SDA is low for over 28ms.

(7) θ_JAvalue is based on JEDEC low-K board.

4

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SBOS448F –AUGUST 2008–REVISED SEPTEMBER 2011

PIN CONFIGURATIONS

DCN PACKAGE

SOT23-8

(Top View)

D PACKAGE

SO-8

(Top View)

V_IN+

V_IN-

A1

1

2

3

4

8

7

6

5

A1

A0

1

2

3

4

8

7

6

5

V_IN+

V_IN-

GND

V_S

A0

GND

V_S

SDA

SCL

SDA

SCL

PIN DESCRIPTIONS: SOT23-8

SOT23-8

(DCN)

PIN NO

NAME

DESCRIPTION

Positive differential shunt voltage. Connect to positive side of shunt resistor.

1

V_IN+

Negative differential shunt voltage. Connect to negative side of shunt resistor. Bus voltage is measured

from this pin to ground.

2

V_IN–

3

4

5

6

7

8

GND

V_S

Ground.

Power supply, 3V to 5.5V.

SCL

SDA

A0

Serial bus clock line.

Serial bus data line.

Address pin. Table 2 shows pin settings and corresponding addresses.

A1

PIN DESCRIPTIONS: SO-8

SO-8

(D)

PIN NO

NAME

A1

DESCRIPTION

Address pin. Table 2 shows pin settings and corresponding addresses.

Serial bus data line.

1

2

3

4

5

6

A0

SDA

SCL

V_S

Serial bus clock line.

Power supply, 3V to 5.5V.

GND

Ground.

Negative differential shunt voltage. Connect to negative side of shunt resistor. Bus voltage is measured

from this pin to ground.

7

8

V_IN–

V_IN+

Positive differential shunt voltage. Connect to positive side of shunt resistor.

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TYPICAL CHARACTERISTICS

At T_A= +25°C, V_IN+= 12V, V_SENSE= (V_IN+– V_IN–) = 32mV, PGA = ÷ 1, and BRNG = 1, unless otherwise noted.

FREQUENCY RESPONSE

ADC SHUNT OFFSET vs TEMPERATURE

0

-10

-20

-30

-40

-50

-60

-70

-80

-90

-100

100

80

320mV Range

160mV Range

60

40

20

0

-20

-40

-60

-80

-100

80mV Range

40mV Range

100

1k

10k

100k

1M

125

-25

0

25

50

10

-40

75

100

125

Input Frequency (Hz)

Temperature (°C)

Figure 1.

Figure 2.

ADC SHUNT GAIN ERROR vs TEMPERATURE

ADC BUS VOLTAGE OFFSET vs TEMPERATURE

100

80

50

45

40

35

30

25

20

15

10

5

60

40

20

160mV Range

320mV Range

0

-20

-40

-60

-80

-100

16V Range

32V Range

40mV Range

80mV Range

0

25

50

-25

0

25

50

-40 -25

75

100

-40

75

100

125

Temperature (°C)

Figure 3.

Figure 4.

ADC BUS GAIN ERROR vs TEMPERATURE

INTEGRAL NONLINEARITY vs INPUT VOLTAGE

20

15

100

80

60

10

40

16V

32V

5

20

0

-20

-40

-60

-80

-100

-5

-10

-15

-20

-0.2 -0.1

0

-0.4 -0.3

0.1

0.2

0.3

0.4

0

25

50

-40 -25

75

100

Input Voltage (V)

Temperature (°C)

Figure 5.

Figure 6.

6

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TYPICAL CHARACTERISTICS (continued)

At T_A= +25°C, V_IN+= 12V, V_SENSE= (V_IN+– V_IN–) = 32mV, PGA = ÷ 1, and BRNG = 1, unless otherwise noted.

INPUT CURRENTS WITH LARGE DIFFERENTIAL

VOLTAGES

(V_IN+at 12V, Sweep of V_IN–

)

ACTIVE I_Qvs TEMPERATURE

2.0

1.5

1.2

1.0

0.8

0.6

0.4

0.2

0

V_S+= 5V

V_S= 5V

1.0

0.5

V_S+= 3V

0

V_S= 3V

-0.5

-1.0

-1.5

V_S+= 5V

0

5

10

15

20

25

30

0

25

50

-40 -25

75

100

125

V_IN-Voltage (V)

Temperature (°C)

Figure 7.

Figure 8.

SHUTDOWN I_Qvs TEMPERATURE

ACTIVE I_Qvs I²C CLOCK FREQUENCY

16

14

12

10

8

1.0

0.9

0.8

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0

V_S= 5V

V_S= 3V

6

4

2

0

25

50

75

100

125

-40 -25

1k

10k

100k

1M

10M

Temperature (°C)

SCL Frequency (Hz)

Figure 9.

Figure 10.

SHUTDOWN I_Qvs I²C CLOCK FREQUENCY

300

250

200

150

100

50

V_S= 5V

V_S= 3V

0

1k

10k

100k

1M

10M

SCL Frequency (Hz)

Figure 11.

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REGISTER BLOCK DIAGRAM

Power⁽¹⁾

Bus Voltage⁽¹⁾

´

Current⁽¹⁾

Shunt Voltage

Channel

ADC

Bus Voltage

Channel

Full-Scale Calibration⁽²⁾

Shunt Voltage⁽¹⁾

´

PGA

(In Configuration Register)

NOTES:

(1) Read-only

(2) Read/write

Data Registers

Figure 12. INA219 Register Block Diagram

8

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APPLICATION INFORMATION

The INA219 is a digital current-shunt monitor with an

I²C and SMBus-compatible interface. It provides

digital current, voltage, and power readings

The I²C interface is used throughout this data sheet

as the primary example, with SMBus protocol

specified only when a difference between the two

systems is being addressed. Two bidirectional lines,

SCL and SDA, connect the INA219 to the bus. Both

SCL and SDA are open-drain connections.

necessary

for

accurate

decision-making

in

precisely-controlled systems. Programmable registers

allow flexible configuration for measurement

resolution,

versus-triggered

information appears at the end of this data sheet,

beginning with Table 4. See the Register Block

Diagram for a block diagram of the INA219.

and

operation.

continuous-

Detailed register

The device that initiates the transfer is called a

master, and the devices controlled by the master are

slaves. The bus must be controlled by a master

device that generates the serial clock (SCL), controls

the bus access, and generates START and STOP

conditions.

INA219 TYPICAL APPLICATION

To address a specific device, the master initiates a

START condition by pulling the data signal line (SDA)

from a HIGH to a LOW logic level while SCL is HIGH.

All slaves on the bus shift in the slave address byte

on the rising edge of SCL, with the last bit indicating

whether a read or write operation is intended. During

the ninth clock pulse, the slave being addressed

responds to the master by generating an

Acknowledge and pulling SDA LOW.

Figure 13 shows a typical application circuit for the

INA219. Use

a

0.1μF ceramic capacitor for

power-supply bypassing, placed as closely as

possible to the supply and ground pins.

The input filter circuit consisting of R_F1, R_F2, and C_Fis

not necessary in most applications. If the need for

filtering is unknown, reserve board space for the

components and install 0Ω resistors unless a filter is

needed. See the Filtering and Input Considerations

section.

Data transfer is then initiated and eight bits of data

are sent, followed by an Acknowledge bit. During

data transfer, SDA must remain stable while SCL is

HIGH. Any change in SDA while SCL is HIGH is

interpreted as a START or STOP condition.

The pull-up resistors shown on the SDA and SCL

lines are not needed if there are pull-up resistors on

these same lines elsewhere in the system. Resistor

values shown are typical: consult either the I²C or

SMBus specification to determine the acceptable

minimum or maximum values.

Once all data have been transferred, the master

generates a STOP condition, indicated by pulling

SDA from LOW to HIGH while SCL is HIGH. The

INA219 includes a 28ms timeout on its interface to

prevent locking up an SMBus.

BUS OVERVIEW

The INA219 offers compatibility with both I²C and

SMBus interfaces. The I²C and SMBus protocols are

essentially compatible with one another.

Current

Supply Voltage

(INA219 Power Supply Range is

3V to 5.5V)

Shunt

Power Bus

(0V to 26V)

Load

R_F1

R_F2

C_BYPASS

0.1mF

C_F

(typical)

R_PULLUP

V_IN+

V_IN-

3.3kW

(typical)

INA219

SDA

Power Register

Current Register

Voltage Register

´

Data (SDA)

Clock (SCL)

SCL

A0

I²C

Interface

PGA

ADC

A1

GND

Figure 13. Typical Application Circuit

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Serial Bus Address

WRITING TO/READING FROM THE INA219

To communicate with the INA219, the master must

first address slave devices via a slave address byte.

The slave address byte consists of seven address

bits, and a direction bit indicating the intent of

executing a read or write operation.

Accessing a particular register on the INA219 is

accomplished by writing the appropriate value to the

register pointer. Refer to Table 4 for a complete list of

registers and corresponding addresses. The value for

the register pointer as shown in Figure 17 is the first

byte transferred after the slave address byte with the

R/W bit LOW. Every write operation to the INA219

requires a value for the register pointer.

The INA219 has two address pins, A0 and A1.

Table 2 describes the pin logic levels for each of the

16 possible addresses. The state of pins A0 and A1

is sampled on every bus communication and should

be set before any activity on the interface occurs. The

address pins are read at the start of each

communication event.

Writing to a register begins with the first byte

transmitted by the master. This byte is the slave

address, with the R/W bit LOW. The INA219 then

acknowledges receipt of a valid address. The next

byte transmitted by the master is the address of the

register to which data will be written. This register

address value updates the register pointer to the

desired register. The next two bytes are written to the

register addressed by the register pointer. The

INA219 acknowledges receipt of each data byte. The

master may terminate data transfer by generating a

START or STOP condition.

Table 2. INA219 Address Pins and

Slave Addresses

A1

A0

SLAVE ADDRESS

1000000

1000001

1000010

1000011

1000100

1000101

1000110

1000111

1001000

1001001

1001010

1001011

1001100

1001101

1001110

1001111

GND

V_S+

GND

V_S+

SDA

SCL

GND

V_S+

When reading from the INA219, the last value stored

in the register pointer by a write operation determines

which register is read during a read operation. To

change the register pointer for a read operation, a

new value must be written to the register pointer. This

write is accomplished by issuing a slave address byte

with the R/W bit LOW, followed by the register pointer

byte. No additional data are required. The master

then generates a START condition and sends the

slave address byte with the R/W bit HIGH to initiate

the read command. The next byte is transmitted by

the slave and is the most significant byte of the

register indicated by the register pointer. This byte is

followed by an Acknowledge from the master; then

the slave transmits the least significant byte. The

master acknowledges receipt of the data byte. The

master may terminate data transfer by generating a

Not-Acknowledge after receiving any data byte, or

generating a START or STOP condition. If repeated

reads from the same register are desired, it is not

necessary to continually send the register pointer

bytes; the INA219 retains the register pointer value

until it is changed by the next write operation.

V_S+

SDA

SCL

GND

V_S+

SDA

SCL

SDA

SCL

GND

V_S+

SDA

SCL

Serial Interface

The INA219 operates only as a slave device on the

I²C bus and SMBus. Connections to the bus are

made via the open-drain I/O lines SDA and SCL. The

SDA and SCL pins feature integrated spike

suppression filters and Schmitt triggers to minimize

the effects of input spikes and bus noise. The INA219

supports the transmission protocol for fast (1kHz to

400kHz) and high-speed (1kHz to 3.4MHz) modes.

All data bytes are transmitted most significant byte

first.

Figure 14 and Figure 15 show read and write

operation timing diagrams, respectively. Note that

register bytes are sent most-significant byte first,

followed by the least significant byte. Figure 16

shows the timing diagram for the SMBus Alert

response operation. Figure 17 illustrates a typical

register pointer configuration.

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Figure 15. Timing Diagram for Read Word Format

Figure 14. Timing Diagram for Write Word Format

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ALERT

1

9

1

9

SCL

SDA

0

1

0

R/W

1

0

A3

A2

A1

A0

0

Start By

Master

ACK By

From

INA219

NACK By Stop By

INA219

Master

Frame 1 SMBus ALERT Response Address Byte

Frame 2 Slave Address Byte⁽¹⁾

NOTE (1): The value of the Slave Address Byte is determined by the settings of the A0 and A1 pins. Refer to Table 1.

Figure 16. Timing Diagram for SMBus ALERT

1

9

1

9

SCL

SDA

¼

1

0

A3

A2

A1

A0 R/W

P7

P6

P5

P4

P3

P2

P1

P0

Stop

Start By

Master

ACK By

INA219

Frame 1 Two-Wire Slave Address Byte⁽¹⁾

Frame 2 Register Pointer Byte

NOTE (1): The value of the Slave Address Byte is determined by the settings of the A0 and A1 pins. Refer to Table 1.

Figure 17. Typical Register Pointer Set

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High-Speed I²C Mode

The master then generates a repeated start condition

(a repeated start condition has the same timing as

the start condition). After this repeated start condition,

the protocol is the same as F/S mode, except that

transmission speeds up to 3.4Mbps are allowed.

Instead of using a stop condition, repeated start

conditions should be used to secure the bus in

HS-mode. A stop condition ends the HS-mode and

switches all the internal filters of the INA219 to

support the F/S mode.

When the bus is idle, both the SDA and SCL lines are

pulled high by the pull-up devices. The master

generates a start condition followed by a valid serial

byte containing High-Speed (HS) master code

00001XXX. This transmission is made in fast

(400kbps) or standard (100kbps) (F/S) mode at no

more than 400kbps. The INA219 does not

acknowledge the HS master code, but does

recognize it and switches its internal filters to support

3.4Mbps operation.

t_(LOW)

t_F

t_R

t_(HDSTA)

SCL

SDA

t_(SUSTO)

t_(HDSTA)

t_(HIGH)t_(SUSTA)

t_(HDDAT)

t_(SUDAT)

t_(BUF)

P

S

P

Figure 18. Bus Timing Diagram

Bus Timing Diagram Definitions

FAST MODE

HIGH-SPEED MODE

PARAMETER

MIN

MAX

MIN

MAX

UNITS

SCL Operating Frequency

f_(SCL)

t_(BUF)

0.001

0.4

0.001

3.4

MHz

Bus Free Time Between STOP and START

Condition

600

100

160

100

ns

Hold time after repeated START condition.

t_(HDSTA)

ns

After this period, the first clock is generated.

Repeated START Condition Setup Time

STOP Condition Setup Time

Data Hold Time

t_(SUSTA)

t_(SUSTO)

t_(HDDAT)

t_(SUDAT)

t_(LOW)

t_(HIGH)

t_F

100

0

100

0

ns

Data Setup Time

100

1300

600

10

SCL Clock LOW Period

160

60

SCL Clock HIGH Period

Clock/Data Fall Time

300

160

Clock/Data Rise Time

t_R

Clock/Data Rise Time for SCLK ≤ 100kHz

t_R

1000

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Power-Up Conditions

(Configuration Register, BADC bits). The Mode

control in the Configuration Register also permits

selecting modes to convert only voltage or current,

either continuously or in response to an event

(triggered).

Power-up conditions apply to a software reset via the

RST bit (bit 15) in the Configuration Register, or the

I²C bus General Call Reset.

BASIC ADC FUNCTIONS

All current and power calculations are performed in

the background and do not contribute to conversion

time; conversion times shown in the Electrical

Characteristics table can be used to determine the

actual conversion time.

The two analog inputs to the INA219, V_IN+and V_IN–

,

connect to a shunt resistor in the bus of interest. The

INA219 is typically powered by a separate supply

from +3V to +5.5V. The bus being sensed can vary

from 0V to 26V. There are no special considerations

for power-supply sequencing (for example, a bus

voltage can be present with the supply voltage off,

and vice-versa). The INA219 senses the small drop

across the shunt for shunt voltage, and senses the

voltage with respect to ground from V_IN–for the bus

voltage. Figure 19 illustrates this operation.

Power-Down mode reduces the quiescent current

and turns off current into the INA219 inputs, avoiding

any supply drain. Full recovery from Power-Down

requires 40μs. ADC Off mode (set by the

Configuration Register, MODE bits) stops all

conversions.

Writing any of the triggered convert modes into the

Configuration Register (even if the desired mode is

already programmed into the register) triggers a

single-shot conversion. Table 7 lists the triggered

convert mode settings.

When the INA219 is in the normal operating mode

(that is, MODE bits of the Configuration Register are

set to '111'), it continuously converts the shunt

voltage up to the number set in the shunt voltage

averaging function (Configuration Register, SADC

bits). The device then converts the bus voltage up to

the number set in the bus voltage averaging

V_SHUNT= V_IN+- V_IN-

Typically < 50mV

-

+

Current

Shunt

INA219 Power-Supply Voltage

3V to 5.5V

Supply

Load

3.3V Supply

V_IN+

V_IN-

V_S

INA219

Power Register

´

Data (SDA)

Clock (SCL)

I²C

V_BUS= V_IN-- GND

Current Register

Interface

A0

Range of 0V to 26V

PGA

ADC

Typical Application 12V

A1

Voltage Register

GND

Figure 19. INA219 Configured for Shunt and Bus Voltage Measurement

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Compatibility with TI Hot Swap Controllers

Although the INA219 can be read at any time, and

the data from the last conversion remain available,

the Conversion Ready bit (Status Register, CNVR bit)

is provided to help co-ordinate one-shot or triggered

conversions. The Conversion Ready bit is set after all

conversions, averaging, and multiplication operations

are complete.

The INA219 is designed for compatibility with hot

swap controllers such the TI TPS2490. The TPS2490

uses a high-side shunt with a limit at 50mV; the

INA219 full-scale range of 40mV enables the use of

the same shunt for current sensing below this limit.

When sensing is required at (or through) the 50mV

sense point of the TPS2490, the PGA of the INA219

can be set to ÷2 to provide an 80mV full-scale range.

The Conversion Ready bit clears under these

conditions:

1. Writing to the Configuration Register, except

when configuring the MODE bits for Power Down

or ADC off (Disable) modes;

Filtering and Input Considerations

Measuring current is often noisy, and such noise can

be difficult to define. The INA219 offers several

options for filtering by choosing resolution and

averaging in the Configuration Register. These

filtering options can be set independently for either

voltage or current measurement.

2. Reading the Status Register; or

3. Triggering a single-shot conversion with the

Convert pin.

Power Measurement

The internal ADC is based on a delta-sigma (ΔΣ)

front-end with a 500kHz (±30%) typical sampling rate.

This architecture has good inherent noise rejection;

however, transients that occur at or very close to the

sampling rate harmonics can cause problems.

Because these signals are at 1MHz and higher, they

can be dealt with by incorporating filtering at the input

of the INA219. The high frequency enables the use of

low-value series resistors on the filter for negligible

effects on measurement accuracy. In general, filtering

the INA219 input is only necessary if there are

transients at exact harmonics of the 500kHz (±30%)

sampling rate (>1MHz). Filter using the lowest

possible series resistance and ceramic capacitor.

Recommended values are 0.1μF to 1.0μF. Figure 20

shows the INA219 with an additonal filter added at

the input.

Current and bus voltage are converted at different

points in time, depending on the resolution and

averaging mode settings. For instance, when

configured for 12-bit and 128 sample averaging, up to

68ms in time between sampling these two values is

possible. Again, these calculations are performed in

the background and do not add to the overall

conversion time.

PGA Function

If larger full-scale shunt voltages are desired, the

INA219 provides a PGA function that increases the

full-scale range up to 2, 4, or 8 times (320mV).

Additionally, the bus voltage measurement has two

full-scale ranges: 16V or 32V.

Current

Shunt

Supply

Load

R_FILTER10W

Supply Voltage

3.3V Supply

0.1mF to 1mF

Ceramic Capacitor

V_IN+V_IN-

V_S

INA219

Power Register

´

Data (SDA)

Clock (SCL)

I²C

Interface

Current Register

Voltage Register

A0

A1

PGA

ADC

GND

Figure 20. INA219 with Input Filtering

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Simple Current Shunt Monitor Usage

(No Programming Necessary)

Overload conditions are another consideration for the

INA219 inputs. The INA219 inputs are specified to

tolerate 26V across the inputs. A large differential

scenario might be a short to ground on the load side

of the shunt. This type of event can result in full

power-supply voltage across the shunt (as long the

power supply or energy storage capacitors support it).

It must be remembered that removing a short to

ground can result in inductive kickbacks that could

exceed the 26V differential and common-mode rating

of the INA219. Inductive kickback voltages are best

dealt with by zener-type transient-absorbing devices

(commonly called transzorbs) combined with

sufficient energy storage capacitance.

The INA219 can be used without any programming if

it is only necessary to read a shunt voltage drop and

bus voltage with the default 12-bit resolution, 320mV

shunt full-scale range (PGA = ÷8), 32V bus full-scale

range, and continuous conversion of shunt and bus

voltage.

Without programming, current is measured by

reading the shunt voltage. The Current Register and

Power Register are only available if the Calibration

Register contains a programmed value.

Programming the INA219

In applications that do not have large energy storage

electrolytics on one or both sides of the shunt, an

input overstress condition may result from an

excessive dV/dt of the voltage applied to the input. A

hard physical short is the most likely cause of this

event, particularly in applications with no large

electrolytics present. This problem occurs because an

excessive dV/dt can activate the ESD protection in

the INA219 in systems where large currents are

available. Testing has demonstrated that the addition

of 10Ω resistors in series with each input of the

INA219 sufficiently protects the inputs against dV/dt

failure up to the 26V rating of the INA219. These

resistors have no significant effect on accuracy.

The default power-up states of the registers are

shown in the INA219 register descriptions section of

this data sheet. These registers are volatile, and if

programmed to other than default values, must be

re-programmed at every device power-up. Detailed

information on programming the Calibration Register

specifically is given in the section, Programming the

INA219 Power Measurement Engine

.

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PROGRAMMING THE INA219 POWER

MEASUREMENT ENGINE

Calibration Register can also be selected to provide

values in the Current and Power Registers that either

provide direct decimal equivalents of the values being

measured, or yield a round LSB number. After these

choices have been made, the Calibration Register

also offers possibilities for end user system-level

calibration, where the value is adjusted slightly to

cancel total system error.

Calibration Register and Scaling

The Calibration Register makes it possible to set the

scaling of the Current and Power Registers to

whatever values are most useful for

application. One strategy may be to set the

Calibration Register such that the largest possible

number is generated in the Current Register or Power

Register at the expected full-scale point; this

approach yields the highest resolution. The

a given

Below are two examples for configuring the INA219

calibration. Both examples are written so the

information directly relates to the calibration setup

found in the INA219EVM software.

Calibration Example 1: Calibrating the INA219 with no possibility for overflow. (Note that the numbers

used in this example are the same used with the INA219EVM software as shown in Figure 21.)

1. Establish the following parameters:

V_{BUS_MAX}= 32

V_{SHUNT_MAX}= 0.32

R_SHUNT= 0.5

2. Using Equation 1, determine the maximum possible current .

V_{SHUNT_MAX}

MaxPossible_I =

R_SHUNT

MaxPossible_I = 0.64

(1)

3. Choose the desired maximum current value. This value is selected based on system expectations.

Max_Expected_I = 0.6

4. Calculate the possible range of current LSBs. To calculate this range, first compute a range of LSBs that is

appropriate for the design. Next, select an LSB within this range. Note that the results will have the most

resolution when the minimum LSB is selected. Typically, an LSB is selected to be the nearest round number

to the minimum LSB value.

Max_Expected_I

Minimum_LSB =

32767

-6

Minimum_LSB = 18.311 ´ 10

(2)

Max_Expected_I

Maximum_LSB =

4096

-6

Maximum_LSB = 146.520 ´ 10

(3)

Choose an LSB in the range: Minimum_LSB<Selected_LSB < Maximum_LSB

Current_LSB = 20 × 10^–6

Note:

This value was selected to be a round number near the Minimum_LSB. This selection allows for

good resolution with a rounded LSB.

5. Compute the Calibration Register value using Equation 4:

0.04096

Current_LSB ´ R_SHUNT

Cal = trunc

Cal = 4096

(4)

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6. Calculate the Power LSB, using Equation 5. Equation 5 shows a general formula; because the bus voltage

measurement LSB is always 4mV, the power formula reduces to the calculated result.

Power_LSB = 20 Current_LSB

-6

Power_LSB = 400 ´ 10

(5)

7. Compute the maximum current and shunt voltage values (before overflow), as shown by Equation 6 and

Equation 7. Note that both Equation 6 and Equation 7 involve an If - then condition:

Max_Current = Current_LSB ´ 32767

Max_Current = 0.65534

(6)

If Max_Current ≥ Max Possible_I then

Max_Current_Before_Overflow = MaxPossible_I

Else

Max_Current_Before_Overflow = Max_Current

End If

(Note that Max_Current is greater than MaxPossible_I in this example.)

Max_Current_Before_Overflow = 0.64 (Note: This result is displayed by software as seen in Figure 21.)

Max_ShuntVoltage = Max_Current_Before_Overflow ´ R_SHUNT

Max_ShuntVoltage = 0.32

(7)

If Max_ShuntVoltage ≥ V_{SHUNT_MAX}

Max_ShuntVoltage_Before_Overflow = V_{SHUNT_MAX}

Else

Max_ShuntVoltage_Before_Overflow= Max_ShuntVoltage

End If

(Note that Max_ShuntVoltage is greater than V_{SHUNT_MAX}in this example.)

Max_ShuntVoltage_Before_Overflow = 0.32 (Note: This result is displayed by software as seen in

Figure 21.)

8. Compute the maximum power with Equation 8.

MaximumPower = Max_Current_Before_Overflow ´ V_{BUS_MAX}

MaximumPower = 20.48

(8)

9. (Optional second Calibration step.) Compute corrected full-scale calibration value based on measured

current.

INA219_Current = 0.63484

MeaShuntCurrent = 0.55

Cal ´ MeasShuntCurrent

Corrected_Full_Scale_Cal = trunc

INA219_Current

Corrected_Full_Scale_Cal = 3548

(9)

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Figure 21 illustrates how to perform the same

procedure discussed in this example using the

automated INA219EVM software. Note that the same

numbers used in the nine-step example are used in

the software example in Figure 21. Also note that

Figure 21 illustrates which results correspond to

which step (for example, the information entered in

Step 1 is enclosed in a box in Figure 21 and labeled).

Step1

Optional

Step9

Equ9

Step2

Equ1

Step3

Step4

Equ2, 3

Step5

Equ4

Step7

Equ6, 7

Step6

Equ4

Step8

Equ8

Figure 21. INA219 Calibration Sofware Automatically Computes Calibration Steps 1-9

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Calibration Example 2 (Overflow Possible)

software. Note that the same numbers used in the

nine-step example are used in the software example

in Figure 22. Also note that Figure 22 illustrates which

results correspond to which step (for example, the

information entered in Step 1 is circled in Figure 22

and labeled).

This design example uses the nine-step procedure for

calibrating the INA219 where overflow is possible.

Figure 22 illustrates how the same procedure is

performed using the automated INA219EVM

1. Establish the following parameters:

V_{BUS_MAX}= 32

V_{SHUNT_MAX}= 0.32

R_SHUNT= 5

2. Determine the maximum possible current using Equation 10:

V_{SHUNT_MAX}

MaxPossible_I =

R_SHUNT

MaxPossible_I = 0.064

(10)

3. Choose the desired maximum current value: Max_Expected_I, ≤ MaxPossible_I. This value is selected

based on system expectations.

Max_Expected_I = 0.06

4. Calculate the possible range of current LSBs. This calculation is done by first computing a range of LSB's

that is appropriate for the design. Next, select an LSB withing this range. Note that the results will have the

most resolution when the minimum LSB is selected. Typically, an LSB is selected to be the nearest round

number to the minimum LSB.

Max_Expected_I

Minimum_LSB =

32767

-6

Minimum_LSB = 1.831 ´ 10

(11)

Max_Expected_I

Maximum_LSB =

4096

-6

Maximum_LSB = 14.652 ´ 10

(12)

Choose an LSB in the range: Minimum_LSB<Selected_LSB<Maximum_LSB

Current_LSB = 1.9 × 10^–6

Note:

This value was selected to be a round number near the Minimum_LSB. This section allows for good

resolution with a rounded LSB.

5. Compute the calibration register using Equation 13:

0.04096

Current_LSB ´ R_SHUNT

Cal = trunc

Cal = 4311

(13)

6. Calculate the Power LSB using Equation 14. Equation 14 shows a general formula; because the bus voltage

measurement LSB is always 4mV, the power formula reduces to calculate the result.

Power_LSB = 20 Current_LSB

-6

Power_LSB = 38 ´ 10

(14)

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7. Compute the maximum current and shunt voltage values (before overflow), as shown by Equation 15 and

Equation 16. Note that both Equation 15 and Equation 16 involve an If - then condition.

Max_Current = Current_LSB ´ 32767

Max_Current = 0.06226

(15)

If Max_Current ≥ Max Possible_I then

Max_Current_Before_Overflow = MaxPossible_I

Else

Max_Current_Before_Overflow = Max_Current

End If

(Note that Max_Current is less than MaxPossible_I in this example.)

Max_Current_Before_Overflow = 0.06226 (Note: This result is displayed by software as seen in Figure 22.)

Max_ShuntVoltage = Max_Current_Before_Overflow ´ R_SHUNT

Max_ShuntVoltage = 0.3113

(16)

If Max_ShuntVoltage ≥ V_{SHUNT_MAX}

Max_ShuntVoltage_Before_Overflow = V_{SHUNT_MAX}

Else

Max_ShuntVoltage_Before_Overflow= Max_ShuntVoltage

End If

(Note that Max_ShuntVoltage is less than V_{SHUNT_MAX}in this example.)

Max_ShuntVoltage_Before_Overflow = 0.3113 (Note: This result is displayed by software as seen in

Figure 22.)

8. Compute the maximum power with equation 8.

MaximumPower = Max_Current_Before_Overflow ´ V_{BUS_MAX}

MaximumPower = 1.992

(17)

9. (Optional second calibration step.) Compute the corrected full-scale calibration value based on measured

current.

INA219_Current = 0.06226

MeaShuntCurrent = 0.05

Cal ´ MeasShuntCurrent

Corrected_Full_Scale_Cal = trunc

INA219_Current

Corrected_Full_Scale_Cal = 3462

(18)

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Figure 22 illustrates how to perform the same

procedure discussed in this example using the

automated INA219EVM software. Note that the same

numbers used in the nine-step example are used in

the software example in Figure 22.

Also note that Figure 22 illustrates which results

correspond to which step (for example, the

information entered in Step 1 is enclosed in a box in

Figure 22 and labeled).

Step1

Optional

Step9

Equ18

Step2

Equ10

Step3

Step4

Equ11, 12

Step5

Equ13

Step7

Equ15, 16

Step6

Equ14

Step8

Equ17

Figure 22. Calibration Software Automatically Computes Calibration Steps 1-9

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CONFIGURE/MEASURE/CALCULATE

EXAMPLE

shunt voltage. By knowing the value of the shunt

resistor, the device can then calculate the amount of

current that created the measured shunt voltage drop.

The first step when calculating the calibration value is

setting the current LSB. The Calibration Register

value is based on a calculation that has its precision

capability limited by the size of the register and the

Current Register LSB. The device can measure

bidirectional current; thus, the MSB of the Current

Register is a sign bit that allows for the rest of the 15

bits to be used for the Current Register value. It is

common when using the current value calculations to

use a resolution between 12 bits and 15 bits.

Calculating the current LSB for each of these

resolutions provides minimum and maximum values.

These values are calculated assuming the maximum

current that will be expected to flow through the

current shunt resistor, as shown in Equation 2 and

Equation 3. To simplify the mathematics, it is

common to choose a round number located between

these two points. For this example, the maximum

current LSB is 3.66mA/bit and the minimum current

LSB would be 457.78µA/bit assuming a maximum

expected current of 15A. For this example, a value of

1mA/bit was chosen for the current LSB. Setting the

current LSB to this value allows for sufficient

precision while serving to simplify the math as well.

Using Equation 4 results in a Calibration Register

value of 20480, or 5000h.

In this example, the 10A load creates a differential

voltage of 20mV across a 2mΩ shunt resistor. The

voltage present at the V_IN–pin is equal to the

common-mode voltage minus the differential drop

across the resistor. The bus voltage for the INA219 is

internally measured at the V_IN–pin to measure the

voltage level delivered to the load. For this example,

the voltage at the V_IN–pin is 11.98V. For this

particular range (40mV full-scale), this small

difference is not a significant deviation from the 12V

common-mode voltage. However, at larger full-scale

ranges, this deviation can be much larger.

Note that the Bus Voltage Register bits are not

right-aligned. In order to compute the value of the

Bus Voltage Register contents using the LSB of 4mV,

the register must be shifted right by three bits. This

shift puts the BD0 bit in the LSB position so that the

contents can be multiplied by the 4mV LSB value to

compute the bus voltage measured by the device.

The shifted value of the bus voltage register contents

is now equal to BB3h, a decimal equivalent of 2995.

This value of 2995 multiplied by the 4mV LSB results

in a value of 11.98V.

The Calibration Register (05h) is set in order to

provide the device information about the current

shunt resistor that was used to create the measured

+3.3V to +5V

R_SHUNT

2mW

10mF

0.1mF

10A

Load

+12V

VCM

V_S(Supply Voltage)

SDA

SCK

Power Register

Current Register

Voltage Register

´

I²C

Interface

V

V_IN+

V_IN-

A0

A1

I

GND

Figure 23. Example Circuit Configuration

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The Current Register (04h) is then calculated by

multiplying the shunt voltage contents by the

Calibration Register and then dividing by 4096. For

this example, the shunt voltage of 2000 is multiplied

by the calibration register of 20480 and then divided

by 4096 to yield a Current Register of 2710h.

this result by the power LSB that is 20 times the

1 × 10^-3current LSB, or 20 × 10^-3, results in a power

calculation of 5990

× 20mW/bit, which equals

119.8W. This result matches what is expected for this

register. A manual calculation for the power being

delivered to the load would use 11.98V (12VCM –

20mV shunt drop) multiplied by the load current of

10A to give a 119.8W result.

The Power Register (03h) is then be calculated by

multiplying the Current Register of 10000 by the Bus

Voltage Register of 2995 and then dividing by 5000.

For this example, the Power Register contents are

1766h, or a decimal equivalent of 5990. Multiplying

Table 3 shows the steps for configuring, measuring,

and calculating the values for current and power for

this device.

Table 3. Configure/Measure/Calculate Example⁽¹⁾

STEP #

Step 1

Step 2

Step 3

Step 4

Step 5

Step 6

REGISTER NAME

Configuration

Shunt

ADDRESS

00h

CONTENTS

019Fh

ADJ

DEC

LSB

VALUE

01h

07D0h

5D98h

5000h

2000

2995

10µV

20mV

Bus

02h

0BB3

4mV

11.98V

Calibration

Current

05h

20480

10000

5990

04h

2710h

1mA

10.0A

Power

03h

1766h

20mW

119.8W

(1) Conditions: load = 10A, V_CM= 12V, R_SHUNT= 2mΩ, V_SHUNTFSR = 40mV, and V_BUS= 16V.

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REGISTER INFORMATION

The INA219 uses a bank of registers for holding

configuration settings, measurement results,

maximum/minimum limits, and status information.

Table 4 summarizes the INA219 registers; Figure 12

illustrates registers.

Register contents are updated 4μs after completion of

the write command. Therefore, a 4μs delay is

required between completion of a write to a given

register and a subsequent read of that register

(without changing the pointer) when using SCL

frequencies in excess of 1MHz.

Table 4. Summary of Register Set

POINTER

ADDRESS

POWER-ON RESET

HEX

REGISTER NAME

FUNCTION

BINARY

HEX

TYPE⁽¹⁾

All-register reset, settings for bus

voltage range, PGA Gain, ADC

resolution/averaging.

00

Configuration Register

00111001 10011111

399F

R/W

01

02

03

Shunt Voltage

Bus Voltage

Power⁽²⁾

Shunt voltage measurement data.

Bus voltage measurement data.

Power measurement data.

Shunt voltage

Bus voltage

—

R

00000000 00000000

0000

Contains the value of the current flowing

through the shunt resistor.

04

Current⁽²⁾

00000000 00000000

0000

R

Sets full-scale range and LSB of current

and power measurements. Overall

system calibration.

05

Calibration

00000000 00000000

0000

R/W

(1) Type: R = Read-Only, R/W = Read/Write.

(2) The Power Register and Current Register default to '0' because the Calibration Register defaults to '0', yielding a zero current value until

the Calibration Register is programmed.

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REGISTER DETAILS

All INA219 registers 16-bit registers are actually two 8-bit bytes via the I²C interface.

Configuration Register 00h (Read/Write)

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

RST

—

BRNG

PG1

PG0

BADC4

BADC3

BADC2

BADC1

SADC4

SADC3

SADC2

SADC1 MODE3 MODE2 MODE1

POR

VALUE

0

1

0

1

0

1

Bit Descriptions

RST:

Reset Bit

Bit 15

Setting this bit to '1' generates a system reset that is the same as power-on reset. Resets all registers to default

values; this bit self-clears.

BRNG:

Bus Voltage Range

Bit 13

0 = 16V FSR

1 = 32V FSR (default value)

PG:

PGA (Shunt Voltage Only)

Bits 11, 12

Sets PGA gain and range. Note that the PGA defaults to ÷8 (320mV range). Table 5 shows the gain and range for

the various product gain settings.

Table 5. PG Bit Settings⁽¹⁾

PG1

PG0

GAIN

1

RANGE

±40mV

0

1

0

1

0

1

÷2

±80mV

÷4

±160mV

±320mV

÷8

(1) Shaded values are default.

BADC:

BADC Bus ADC Resolution/Averaging

Bits 7–10

These bits adjust the Bus ADC resolution (9-, 10-, 11-, or 12-bit) or set the number of samples used when

averaging results for the Bus Voltage Register (02h).

26

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SADC:

SADC Shunt ADC Resolution/Averaging

Bits 3–6

These bits adjust the Shunt ADC resolution (9-, 10-, 11-, or 12-bit) or set the number of samples used when

averaging results for the Shunt Voltage Register (01h).

BADC (Bus) and SADC (Shunt) ADC resolution/averaging and conversion time settings are shown in Table 6.

Table 6. ADC Settings⁽¹⁾

ADC4

ADC3

ADC2

ADC1

MODE/SAMPLES

CONVERSION TIME

84μs

0

1

X⁽²⁾

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

0

1

9-bit

10-bit

11-bit

12-bit

2

148μs

276μs

532μs

0

1.06ms

0

4

2.13ms

0

8

4.26ms

1

16

8.51ms

1

32

17.02ms

34.05ms

68.10ms

1

64

1

128

(1) Shaded values are default.

(2) X = Don't care.

MODE:

Operating Mode

Bits 0–2

Selects continuous, triggered, or power-down mode of operation. These bits default to continuous shunt and bus

measurement mode. The mode settings are shown in Table 7.

Table 7. Mode Settings⁽¹⁾

MODE3

MODE2

MODE1

MODE

0

1

0

1

0

1

0

1

0

1

0

1

0

1

Power-Down

Shunt Voltage, Triggered

Bus Voltage, Triggered

Shunt and Bus, Triggered

ADC Off (disabled)

Shunt Voltage, Continuous

Bus Voltage, Continuous

Shunt and Bus, Continuous

(1) Shaded values are default.

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DATA OUTPUT REGISTERS

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Shunt Voltage Register 01h (Read-Only)

The Shunt Voltage Register stores the current shunt voltage reading, V_SHUNT. Shunt Voltage Register bits are

shifted according to the PGA setting selected in the Configuration Register (00h). When multiple sign bits are

present, they will all be the same value. Negative numbers are represented in two's complement format.

Generate the two's complement of a negative number by complementing the absolute value binary number and

adding 1. Extend the sign, denoting a negative number by setting the MSB = '1'. Extend the sign to any

additional sign bits to form the 16-bit word.

Example: For a value of V_SHUNT= –320mV:

1. Take the absolute value (include accuracy to 0.01mV)==> 320.00

2. Translate this number to a whole decimal number ==> 32000

3. Convert it to binary==> 111 1101 0000 0000

4. Complement the binary result : 000 0010 1111 1111

5. Add 1 to the Complement to create the Two’s Complement formatted result ==> 000 0011 0000 0000

6. Extend the sign and create the 16-bit word: 1000 0011 0000 0000 = 8300h (Remember to extend the sign to

all sign-bits, as necessary based on the PGA setting.)

At PGA = ÷8, full-scale range = ±320mV (decimal = 32000, positive value hex = 7D00, negative value hex =

8300), and LSB = 10μV.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

SIGN

SD14_8 SD13_8 SD12_8 SD11_8 SD10_8

SD9_8

SD8_8

SD7_8

SD6_8

SD5_8

SD4_8

SD3_8

SD2_8

SD1_8

SD0_8

POR

VALUE

0

At PGA = ÷4, full-scale range = ±160mV (decimal = 16000, positive value hex = 3E80, negative value hex =

C180), and LSB = 10μV.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

SIGN

SD13_4 SD12_4 SD11_4 SD10_4

SD9_4

SD8_4

SD7_4

SD6_4

SD5_4

SD4_4

SD3_4

SD2_4

SD1_4

SD0_4

POR

VALUE

0

At PGA = ÷2, full-scale range = ±80mV (decimal = 8000, positive value hex = 1F40, negative value hex = E0C0),

and LSB = 10μV.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

SIGN

SD12_2 SD11_2 SD10_2

SD9_2

SD8_2

SD7_2

SD6_2

SD5_2

SD4_2

SD3_2

SD2_2

SD1_2

SD0_2

POR

VALUE

0

At PGA = ÷1, full-scale range = ±40mV (decimal = 4000, positive value hex = 0FA0, negative value hex = F060),

and LSB = 10μV.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

SIGN

SD11_1 SD10_1

SD9_1

SD8_1

SD7_1

SD6_1

SD5_1

SD4_1

SD3_1

SD2_1

SD1_1

SD0_1

POR

VALUE

0

28

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Table 8. Shunt Voltage Register Format⁽¹⁾

V_SHUNT

Reading (mV)

Decimal

Value

PGA = ÷ 8

(D15…..................D0)

PGA = ÷ 4

(D15…..................D0)

PGA = ÷ 2

(D15…..................D0)

PGA = ÷ 1

(D15…..................D0)

320.02

320.01

320.00

319.99

319.98

32002

32001

32000

31999

31998

0111 1101 0000 0000

0111 1100 1111 1111

0111 1100 1111 1110

0011 1110 1000 0000

0001 1111 0100 0000

0000 1111 1010 0000

160.02

160.01

160.00

159.99

159.98

16002

16001

16000

15999

15998

0011 1110 1000 0010

0011 1110 1000 0001

0011 1110 1000 0000

0011 1110 0111 1111

0011 1110 0111 1110

0011 1110 1000 0000

0011 1110 0111 1111

0011 1110 0111 1110

0001 1111 0100 0000

0000 1111 1010 0000

80.02

80.01

80.00

79.99

79.98

8002

8001

8000

7999

7998

0001 1111 0100 0010

0001 1111 0100 0001

0001 1111 0100 0000

0001 1111 0011 1111

0001 1111 0011 1110

0001 1111 0100 0010

0001 1111 0100 0001

0001 1111 0100 0000

0001 1111 0011 1111

0001 1111 0011 1110

0001 1111 0100 0000

0001 1111 0011 1111

0001 1111 0011 1110

0000 1111 1010 0000

40.02

40.01

40.00

39.99

39.98

4002

4001

4000

3999

3998

0000 1111 1010 0010

0000 1111 1010 0001

0000 1111 1010 0000

0000 1111 1001 1111

0000 1111 1001 1110

0000 1111 1010 0010

0000 1111 1010 0001

0000 1111 1010 0000

0000 1111 1001 1111

0000 1111 1001 1110

0000 1111 1010 0010

0000 1111 1010 0001

0000 1111 1010 0000

0000 1111 1001 1111

0000 1111 1001 1110

0000 1111 1010 0000

0000 1111 1001 1111

0000 1111 1001 1110

0.02

0.01

0

2

1

0000 0000 0000 0010

0000 0000 0000 0001

0000 0000 0000 0000

1111 1111 1111 1111

1111 1111 1111 1110

0000 0000 0000 0010

0000 0000 0000 0001

0000 0000 0000 0000

1111 1111 1111 1111

1111 1111 1111 1110

0000 0000 0000 0010

0000 0000 0000 0001

0000 0000 0000 0000

1111 1111 1111 1111

1111 1111 1111 1110

0000 0000 0000 0010

0000 0000 0000 0001

0000 0000 0000 0000

1111 1111 1111 1111

1111 1111 1111 1110

0

–0.01

–0.02

–1

–2

–39.98

–39.99

–40.00

–40.01

–40.02

–3998

–3999

–4000

–4001

–4002

1111 0000 0110 0010

1111 0000 0110 0001

1111 0000 0110 0000

1111 0000 0101 1111

1111 0000 0101 1110

1111 0000 0110 0010

1111 0000 0110 0001

1111 0000 0110 0000

1111 0000 0101 1111

1111 0000 0101 1110

1111 0000 0110 0010

1111 0000 0110 0001

1111 0000 0110 0000

1111 0000 0101 1111

1111 0000 0101 1110

1111 0000 0110 0010

1111 0000 0110 0001

1111 0000 0110 0000

–79.98

–79.99

–80.00

–80.01

–80.02

–7998

–7999

–8000

–8001

–8002

1110 0000 1100 0010

1110 0000 1100 0001

1110 0000 1100 0000

1110 0000 1011 1111

1110 0000 1011 1110

1110 0000 1100 0010

1110 0000 1100 0001

1110 0000 1100 0000

1110 0000 1011 1111

1110 0000 1011 1110

1110 0000 1100 0010

1110 0000 1100 0001

1110 0000 1100 0000

1111 0000 0110 0000

–159.98

–159.99

–160.00

–160.01

–160.02

–15998

–15999

–16000

–16001

–16002

1100 0001 1000 0010

1100 0001 1000 0001

1100 0001 1000 0000

1100 0001 0111 1111

1100 0001 0111 1110

1100 0001 1000 0010

1100 0001 1000 0001

1100 0001 1000 0000

1110 0000 1100 0000

1111 0000 0110 0000

–319.98

–319.99

–320.00

–320.01

–320.02

–31998

–31999

–32000

–32001

–32002

1000 0011 0000 0010

1000 0011 0000 0001

1000 0011 0000 0000

1100 0001 1000 0000

1110 0000 1100 0000

1111 0000 0110 0000

(1) Out-of-range values are shown in grey shading.

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Bus Voltage Register 02h (Read-Only)

The Bus Voltage Register stores the most recent bus voltage reading, V_BUS

.

At full-scale range = 32V (decimal = 8000, hex = 1F40), and LSB = 4mV.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

BD12

BD11

BD10

BD9

BD8

BD7

BD6

BD5

BD4

BD3

BD2

0

BD1

BD0

—

CNVR

0

OVF

POR

VALUE

0

At full-scale range = 16V (decimal = 4000, hex = 0FA0), and LSB = 4mV.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

0

BD11

BD10

BD9

BD8

BD7

BD6

BD5

BD4

BD3

BD2

BD1

BD0

—

CNVR

OVF

POR

VALUE

0

CNVR:

Conversion Ready

Bit 1

Although the data from the last conversion can be read at any time, the INA219 Conversion Ready bit (CNVR)

indicates when data from a conversion is available in the data output registers. The CNVR bit is set after all

conversions, averaging, and multiplications are complete. CNVR will clear under the following conditions:

1.) Writing a new mode into the Operating Mode bits in the Configuration Register (except for Power-Down or

Disable)

2.) Reading the Power Register

OVF:

Math Overflow Flag

Bit 0

The Math Overflow Flag (OVF) is set when the Power or Current calculations are out of range. It indicates that

current and power data may be meaningless.

Power Register 03h (Read-Only)

Full-scale range and LSB are set by the Calibration Register. See the Programming the INA219 Power

Measurement Engine section.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

PD15

PD14

PD13

PD12

PD11

PD10

PD9

PD8

PD7

PD6

PD5

PD4

PD3

PD2

PD1

PD0

POR

VALUE

0

The Power Register records power in watts by multiplying the values of the current with the value of the bus

voltage according to the equation:

Current ´ BusVoltage

Power =

5000

Current Register 04h (Read-Only)

Full-scale range and LSB depend on the value entered in the Calibration Register. See the Programming the

INA219 Power Measurement Engine section. Negative values are stored in two's complement format.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

BIT

NAME

CSIGN

CD14

CD13

CD12

CD11

CD10

CD9

CD8

CD7

CD6

CD5

CD4

CD3

CD2

CD1

CD0

POR

VALUE

0

The value of the Current Register is calculated by multiplying the value in the Shunt Voltage Register with the

value in the Calibration Register according to the equation:

ShuntVoltage ´ Calibration Register

Current =

4096

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CALIBRATION REGISTER

Calibration Register 05h (Read/Write)

Current and power calibration are set by bits D15 to D1 of the Calibration Register. Note that bit D0 is not used in

the calculation. This register sets the current that corresponds to a full-scale drop across the shunt. Full-scale

range and the LSB of the current and power measurement depend on the value entered in this register. See the

Programming the INA219 Power Measurement Engine section. This register is suitable for use in overall system

calibration. Note that the '0' POR values are all default.

BIT #

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0⁽¹⁾

BIT

NAME

FS15

FS14

FS13

FS12

FS11

FS10

FS9

FS8

FS7

FS6

FS5

FS4

FS3

FS2

FS1

FS0

POR

VALUE

0

(1) D0 is a void bit and will always be '0'. It is not possible to write a '1' to D0. CALIBRATION is the value stored in D15:D1.

space

REVISION HISTORY

NOTE: Page numbers for previous revisions may differ from page numbers in the current version.

Changes from Revision E (September 2010) to Revision F

Page

•

Changed values in text. ...................................................................................................................................................... 24

Changed step 5 and step 6 values in Table 3 .................................................................................................................... 24

Changes from Revision D (September 2010) to Revision E

Page

•

Updated Packaging Information table ................................................................................................................................... 2

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PACKAGE MATERIALS INFORMATION

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21-Sep-2011

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

A0

B0

K0

P1

W

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

INA219AIDCNR

INA219AIDCNT

INA219BIDCNR

INA219BIDCNT

SOT-23

DCN

8

3000

250

179.0

8.4

3.2

1.4

4.0

8.0

Q3

3000

250

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

21-Sep-2011

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

Length (mm) Width (mm) Height (mm)

INA219AIDCNR

INA219AIDCNT

INA219BIDCNR

INA219BIDCNT

SOT-23

DCN

8

3000

250

195.0

200.0

45.0

3000

250

Pack Materials-Page 2

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型号：	HPA00900AIDCNR
厂家：	TEXAS INSTRUMENTS
描述：	26-V, Bidirectional, Zero-Drift, High-Side, I<sup>2</sup>C Out Current/Power Monitor 8-SOT-23 -25 to 85 光电二极管
文件：	总40页 (文件大小：984K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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