In the implementation discussed in this reference design, the MSP430FR6043 MCU performs the complete acquisition process using the USS module in the device for signal conditioning. Figure 3-3 shows this acquisition process.

At the beginning of the sequence, the MSP430FR6043 MCU sends a train of pulses to the first transducer, XDCR₁. The signal is then received by the second transceiver, XDCR₂ , after propagation time T₁₂. The difference in time between transmission and reception determines the upstream (UPS) ToF, or ToF_UPS .

The MSP430FR6043 MCU repeats the same process in the opposite direction during the downstream stage, resulting in the propagation time, T₂₁, which represents the downstream (DNS) ToF, or ToF_DNS.

The DToF, Δt, can then be calculated as the difference between T₁₂ and T₂₁, as described in Equation 3.

The DToF is typically measured using two techniques: Zero-crossing using a time-to-digital converter (TDC) or through Correlation using the ADC captured signal

The TIDM-02003 design uses the ADC-based technique instead of the TDC technique due to the following advantages.

• Improved performance: the correlation acts as a digital filter to suppress noise, which results in a benefit of approximately three to four times lower noise standard deviation. Similarly, the correlation approach also acts as a low-pass filter that suppresses other interference like line noise.
• Improved robustness for signal amplitude variations: because the algorithm is insensitive to the received signal amplitude, transducer-to-transducer variation, and temperature variation.
• The envelope of the signal is obtained naturally. This signal enables tuning to the transducer frequencies, as well as slow variations in the envelope across time, which can be used to maintain performance even with aging transducers or meters.