Development of Novel Wearable Sensor System Capable of Measuring and Distinguishing Between Compression and Shear Forces for Biomedical Applications

Dimitrija Dusko Pecoski (8797031)

21 June 2022

<p>There are no commercially available wearable shoe in-sole sensors that are capable of measuring and distinguishing between shear and compression forces. Companies have already developed shoe sensors that simply measure pressure and make general inferences on the collected data with elaborate software [2, 3, 4, 5]. Researchers have also attempted making sensors that are capable of measuring shear forces, but they are not well suited for biomedical applications [61, 62, 63, 64]. This work focuses on the development of a novel wearable sensor system that is capable of identifying and measuring shear and compression forces through the use of capacitive sensing. Custom hardware and software tools such as materials test systems and capacitive measurement systems were developed during this work. Numerous sensor prototypes were developed, characterized, and optimized during the scope of this project. Upon analysis of the data, the best capacitive measurement system developed in this work utilized the CAV444 IC chip, whereas the use of the Arduino-derived measurement system required data filtering using median and Butterworth zero phase low pass filters. The highest dielectric constant reported from optimization experiments yielded 9.7034 (+/- 0.0801 STD) through the use of 60.2% by weight calcium copper titanate and ReoFlex-60 silicone. The experiments suggest certain sensors developed in this work feasibly measure and distinguish between shear and compressional forces. Applications for such technology focus on improving quality of life in areas such as managing diabetic ulcer formation, preventing injuries, optimizing performance for athletes and military personnel, and augmenting the scope of motion capture in biomechanical studies.</p>

Biomechanical engineering

Biomedical instrumentation

Medical devices

Circuits and systems

Microelectronics

Composite and hybrid materials

Wearables

Wearable Sensors

Sensors

Biomedical Engineering

Mechanical Engineering

Electrical Engineering

Biomechanics

Disease Management

Diabetic Neuropathy

Ulcer Prevention

Athlete Injury Prevention

Human Performance Optimization

Motion Capture Analysis Optimization

Sensor Development

Capacitive Sensing

Sensor Performance Characterization

Dielectric Materials

Composites

Measurement Systems

Instrumentation

Mechanical Testing

Materials Testing System

Sensor Design

Sensor Materials

Sensor Manufacturing

Sensor Data Analysis

Custom Hardware and Software Development

Sensor Systems

Capacitive Sensor Modeling

Biomechanical Engineering

Biomedical Instrumentation

Circuits and Systems

Composite and Hybrid Materials

Medical Devices

Microelectronics and Integrated Circuits