Printed hybrid capacitive Kirigami sensor: enhancing flexibility and conformability for improved motion artifacts

Abstract

Abstract Capacitive sensing of electrophysiological signals is a promising alternative to traditional contact-type sensing for long-term and ubiquitous health monitoring. Many researchers are focusing on developing flexible capacitive electrodes to improve the conformability and the quality of acquisition of this family of sensors. However, current flexible devices still present many limitations due to the negative Poisson’s ratio of the materials used, which affects the dimensions and characteristics of the materials when under stress, and their incompatibility with traditional manufacturing methods and solid-state devices. We present a novel, inkjet-printed, hybrid capacitive Kirigami sensor design. This novel structure comprises different layers with different functionalities, in order to allow improved flexibility and conformability of the flexible Kirigami printed electrode, while securing its inclusion on a traditional rigid printed circuit board for a quality signal acquisition. The novel sensor design has been tested on different shapes and dimensions of sensing target and with different weights applied. Capacitive and electrical measurements were performed to obtain the main basic sensor characteristics such as coupled capacitance, acquired signal amplitude and cutoff frequency. When compared to an analog but rigid sensor, the novel designed hybrid flexible sensor showed significant improvement and enhanced uniformity of measurements, with an increase in amplitude value up to + 82 % for the bigger curvatures, while maintaining good electrical contact and integrity of all the layers.