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Textile‐Based Inductive Soft Strain Sensors for Fast Frequency Movement and Their Application in Wearable Devices Measuring Multiaxial Hip Joint Angles during Running

Mohammad Tavassolian, Tyler J. Cuthbert, Christopher Napier, Jingyang Peng, Carlo Menon

2020Advanced Intelligent Systems52 citationsDOIOpen Access PDF

Abstract

Wearable multiaxes motion tracking with inductive sensors and machine learning is presented. The production, characterization, and use of a modular and size‐adjustable inductive sensor for kinematic motion tracking are introduced. The sensor is highly stable and able to track high‐frequency (>15 Hz) and high strain rates (>450% s −1 ). Four sensors are used to fabricate a pair of motion capture shorts. A random forest machine learning algorithm is used to predict the sagittal, transverse, and frontal hip joint angle, using the raw signals from sport shorts during running with a cohort of 12 participants against a gold standard optical motion capture system to an accuracy as high as R 2 = 0.98 and root mean squared error of 2° in all three planes. Herein, an alternative strain sensor is provided to those typically used (piezoresistive/capacitive) for soft wearable motion capture devices with distinct advantages that can find applications in smart wearable devices, robotics, or direct integration into textiles.

Topics & Concepts

Motion captureCapacitive sensingWearable computerPiezoresistive effectMatch movingComputer scienceKinematicsTracking (education)Artificial intelligenceAcousticsBendingSimulationComputer visionMotion (physics)EngineeringPhysicsElectrical engineeringStructural engineeringEmbedded systemClassical mechanicsPsychologyOperating systemPedagogyMuscle activation and electromyography studiesAdvanced Sensor and Energy Harvesting MaterialsSports Performance and Training
Textile‐Based Inductive Soft Strain Sensors for Fast Frequency Movement and Their Application in Wearable Devices Measuring Multiaxial Hip Joint Angles during Running | Litcius