Study of a Novel Capacitive Pressure Sensor Using Spiral Comb Electrodes

TL;DR

This paper introduces a spiral comb electrode design for capacitive pressure sensors, significantly enhancing sensitivity and linearity over traditional straight electrode sensors through theoretical, simulation, and experimental validation.

Contribution

The novel spiral electrode design improves pressure sensitivity and linearity in capacitive sensors, verified by simulations and experiments, offering a new approach for high-sensitivity pressure detection.

Findings

Mechanical sensitivity of 1.5x10^-4 m/Pa

Capacitive sensitivity of 1.10 aF/Pa

Nonlinear error of 3.63%

Abstract

For traditional capacitive pressure sensors, high nonlinearity and poor sensitivity greatly limited their sensing applications. Hence, an innovative design of capacitors based on spiral comb electrodes is proposed for high-sensitivity pressure detection in this work. Compared to traditional capacitive pressure sensors with straight plate electrodes, the proposed sensor with the spiral electrodes increases the overlap areas of electrodes sufficiently, the pressure sensitivity can thus be greatly improved. Moreover, the capacitance variation of the proposed sensor is dominated by the change of the overlap area of the electrodes rather than the electrode's distance, the linearity can also thus be improved to higher than 0.99. Theoretical analysis and COMSOL-based finite element simulation have been implemented for principle verification and performance optimization. Simulation results show that the proposed design has a mechanical sensitivity of 1.5x10-4 m/Pa, capacitive sensitivity of 1.10 aF/Pa, and nonlinear error of 3.63%, respectively, at the pressure range from 0 to 30 kPa. An equivalent experiment has been further carried out for verification. Experimental results also show that both the sensitivity and linearity of capacitive pressure sensors with spiral electrodes are higher than those with straight electrodes. This work not only provides a new avenue for capacitor design, but also can be applied to high-sensitivity pressure detection.