Modern measurement systems often operate with single 5-V power supplies, yet their input signals may have large common-mode voltages that exceed the supply by tens or hundreds of volts. Also, unless the converter is driven differentially, the noise on the analog-to-digital converter (ADC) reference pin is indistinguishable from a real signal.
The circuit of Figure 1 solves both of these problems. It provides a gain of 2, along with differential inputs and a differential output. The ADC reference sets the output common-mode level. The amplifier is constructed with two subtractors, each compliant to high common-mode voltage. These subtractors are set up so that the positive input of one connects to the negative input of the other, and vice versa. Their reference pins are tied together and connected to the ADC's reference pin.
As the input signal increases, one output, OUTP, increases, while the other output, OUTN, decreases. Both outputs remain centered with respect to the common-mode level set by the ADC's reference.
Figure 2 illustrates the circuit's performance with a single 5-V power supply. At the top is a 1-kHz, 2-V p-p input signal. At the bottom are the two outputs in antiphase to produce a 4-V p-p signal centered around the 2.5-V reference.
Figure 3 demonstrates the system's ability to reject a 1-kHz, 60-V p-p common-mode signal. The upper waveform shows the common-mode input, while the lower waveform shows the output.
Bigger power supplies, such as ±15 V, can be used for larger common-mode signals. Figure 4 shows that the system can reject a 400-V p-p common-mode signal (upper waveform), with the residual error of less than 10 mV p-p shown in the lower waveform.
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