SLUAAI3 January 2022 TPS62810-Q1 , TPS62811-Q1 , TPS62812-Q1 , TPS62813-Q1 , TPS62816-Q1 , TPS628501 , TPS628501-Q1 , TPS628502 , TPS628502-Q1 , TPS628503 , TPS628503-Q1 , TPS628510 , TPS628511 , TPS628512 , TPS62870 , TPS62870-Q1 , TPS62871 , TPS62871-Q1 , TPS62872 , TPS62872-Q1 , TPS62873 , TPS62873-Q1 , TPS62874-Q1 , TPS62875-Q1 , TPS62876-Q1 , TPS62877-Q1 , TPS62A01 , TPS62A01A , TPS62A02 , TPS62A02A , TPS62A06 , TPS62A06A , TPSM82810 , TPSM82813 , TPSM8287A06 , TPSM8287A12 , TPSM8287A15

2 2-Port Shunt-Through Measurement Theory

Figure 2-1 2-Port Shunt-Through Circuit Configuration

Figure 2-1 shows the 2-Port Shunt-Through circuit configuration to measure $Z_{1}^{}$ impedance. First of all, the S-parameter $S_{21}^{}$ is calculated to derive the $Z_{1}^{}$ impedance value. As per definition, $S_{21}^{}$ is:

Equation 1.

S_{21}^{} = \frac{V_{2}^{} + I_{2}^{} R_{0}^{}}{V_{1}^{} + I_{1}^{} R_{0}^{}} = \frac{{2 Z}_{1}^{}}{{2 Z}_{1}^{} + R_{0}^{}}

Assuming that $R_{0}^{}$ = 50 Ω and $S_{21}^{}$ << 1 (for very small impedance / resistances - $Z_{1}^{}$ << $R_{0}^{}$ ) when solving for $Z_{1}^{}$ , the result is:

Equation 2.

Z_{1}^{} = \frac{{25 S}_{21}^{}}{1- S_{21}^{}} ~ {25 S}_{21}^{}

It is important to note that the measure of $S_{21}^{}$ is influenced by the VNA performance such as the dynamic range, the signal-to-noise ratio and the effective number of bits.

As all grounds in a VNA refer to the same point, an additional common mode current is created and affects measurement accuracy resulting in measurement errors. A Semi-floating differential amplifier is then used as a ground isolator to minimize ground loop currents.

Figure 2-2 2-Port Shunt-Through Circuit Configuration

Figure 2-2 shows a 2-port shunt-through measurement setup. The 2-port shunt-through measurement uses a vector network analyzer (VNA) to compute impedances at very high frequency and a semi-floating differential amplifier to measure impedances down to 1 mΩ. Selecting a semi-floating differential amplifier with a large resistance to common mode current is paramount to improve the accuracy of the measurements especially at lower frequencies.