SBOS793G April 2017 – May 2020 INA181 , INA2181 , INA4181

PRODUCTION DATA.

- 1 Features
- 2 Applications
- 3 Description
- 4 Revision History
- 5 Device Comparison Table
- 6 Pin Configuration and Functions
- 7 Specifications
- 8 Detailed Description
- 9 Application and Implementation
- 10Power Supply Recommendations
- 11Layout
- 12Device and Documentation Support
- 13Mechanical, Packaging, and Orderable Information

- DBV|6

The maximum value of the current sense resistor is calculated based on the maximum power loss requirement. By applying Equation 2, the maximum value of the current-sense resistor is calculated to be 1.125 mΩ. This is the maximum value for sense resistor R_{SENSE}; therefore, select R_{SENSE} to be 1 mΩ because it is the closest standard resistor value that meets the power-loss requirement.

The next step is to select the appropriate gain and reduce R_{SENSE}, if needed, to keep the output signal swing within the V_{S} range. The design requirements call for bidirectional current monitoring; therefore, a voltage between 0 and V_{S} must be applied to the REF pin. The bidirectional currents monitored are symmetric around 0 (that is, ±20 A); therefore, the ideal voltage to apply to V_{REF} is V_{S} / 2 or 2.5 V. If the positive current is greater than the negative current, using a lower voltage on V_{REF} has the benefit of maximizing the output swing for the given range of expected currents. Using Equation 3, and given that I_{MAX} = 20 A , R_{SENSE} = 1 mΩ, and V_{REF} = 2.5 V, the maximum current-sense gain calculated to avoid the positive swing-to-rail limitations on the output is 122.5. Likewise, using Equation 4 for the negative-swing limitation results in a maximum gain of 124.75. Selecting the gain-of-100 device maximizes the output range while staying within the output swing range. If the maximum calculated gains are slightly less than 100, the value of the current-sense resistor can be reduced to keep the output from hitting the output-swing limitations.

To calculate the accuracy at peak current, the two factors that must be determined are the gain error and the offset error. The gain error of the INAx181 is specified to be a maximum of 1%. The error due to the offset is constant, and is specified to be 500 µV (maximum) for the conditions where V_{CM} = 12 V and V_{S} = 5 V. Using Equation 7, the percentage error contribution of the offset voltage is calculated to be 2.5%, with total offset error = 500 µV, R_{SENSE} = 1 mΩ, and I_{SENSE} = 20 A.

Equation 7.

One method of calculating the total error is to add the gain error to the percentage contribution of the offset error. However, in this case, the gain error and the offset error do not have an influence or correlation to each other. A more statistically accurate method of calculating the total error is to use the RSS sum of the errors, as shown in Equation 8:

Equation 8.

After applying Equation 8, the total current sense error at maximum current is calculated to be 2.7%, and that is less than the design example requirement of 3.5%.

The INA181A3 (gain = 100) also has a bandwidth of 150 kHz that meets the small-signal bandwidth requirement of 100 kHz. If higher bandwidth is required, lower-gain devices can be used at the expense of either reduced output voltage range or an increased value of R_{SENSE}.