Changes to temperature, humidity, and air pressure influence the speed of sound and the transmission impedance characteristics of the transducer just as a variable parallel load at the transducer would. Temperature has the greatest impact on the performance of ultrasonic sensors. Sound and heat are both forms of kinetic energy, whereby an increase to temperature yields an increase to the rate of molecular vibration. Because of the fluctuation in molecular vibration, sound waves are able to travel from 300 to 400 m/s. Use Equation 1 to calculate the speed of sound in air (v) as a dependency to temperature (T).

Table 3-4 shows the speed of sound across temperature.

When converting the round-trip time of an ultrasonic time-of-flight based echo, the speed of sound must be considered in order to prevent ±15cm of error to the distance equivalent of the target.

The resonant frequency of the transducer decreases as temperature increases. Therefore, to compensate for the point at which the phase change will occur, the transducer must be driven at an offset frequency, or external passive components must be introduced beyond a certain temperature to retune the resonance towards the nominal frequency. The PGA460 device offers a temperature decoupling mode to introduce additional passives in parallel to the transducer beyond a user-specified temperature.