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SBOA551 June 2022 INA240

5.2 Reference Source Impedance Error in Difference Amplifier

Figure 5-2 shows a non-ideal voltage source, V_{ref_x}, driving the reference pin of a difference amplifier. The output impedance of V_{ref_x} is represented by R_x. The difference amplifier input is connected to common-mode voltage source V_cm, as well as differential voltage source V_diff.

Figure 5-2 Difference Amplifier Output Error Due to Reference Source Impedance

The following expression can be derived for the output:

Equation 10.

V_{o u t} = \frac{R_{i} + R_{f}}{R_{i} + R_{f} + R_{x}} V_{r e f_x} + \frac{R_{x}}{R_{i} + R_{f} + R_{x}} V_{c m} + \frac{R_{f}}{R_{i}} V_{d i f f} + \frac{R_{x}}{R_{i} + R_{f} + R_{x}} \frac{V_{d i f f}}{2}

For ideal V_{ref_x}, its output impedance equals to zero. Therefore, setting R_x = 0 yields the familiar ideal output equation:

Equation 11.

V_{o u t_i d e a l} = V_{r e f_x} + \frac{R_{f}}{R_{i}} V_{d i f f}

Note that V_ref = V_{ref_x} for ideal voltage source. Taking the difference of the two previous equations gives the equation for output error due to reference source impedance:

Equation 12.

V_{o u t_e r r o r} {= V}_{o u t} - V_{o u t_i d e a l} = \frac{\frac{R_{x}}{R_{i} + R_{f}}}{1 + \frac{R_{x}}{R_{i} + R_{f}}} ({- V}_{r e f_x} + V_{c m} + \frac{V_{d i f f}}{2})

Upon inspection, the following observations are made:

The first two terms are due to V_{ref_x} and V_cm respectively and have opposite signs. Combined together, it represents an equivalent output offset. The third term represents a gain error that is proportional to the differential input voltage.
The differential input is normally under a couple hundred millivolts considering the input range for common gain options and supply voltage range, while common-mode input could be many tens of volts. As a result, the offset term is normally much larger than the gain error term.
Both the offset and gain error terms are proportional to the ratio R_x / (R_i+R_f), when R_x << (R_i+R_f). This coefficient can be used as an indicator of the output error magnitude.
When referred to input, all terms in the output error are divided by the gain of the difference amplifier.

So far, it is assumed that the output is measured single-end relative to ground. The reference voltage V_{ref_x} is then subtracted from the measured results. If differential measurement is made with respect to the reference pin, the output error cancels. In this situation, the finite source impedance, R_x, has no impact on accuracy. Figure 5-3 shows the preferred measurement setup when using a voltage divider to drive the reference, or when output impedance of the driving source is not negligible.

Figure 5-3 Differential Measurement

Comparing with single-ended measurement, differential measurement is a great improvement. However, it does not mean that the source impedance has no impact on performance at all. The price to pay is output dynamic range. Because the error voltage is still added to the output and reduces its effective swing range that is otherwise available to respond to differential input.