Sunny Amatya, Amir Salimi Lafmejani, Souvik Poddar, Saivimal Sridar, T. Sugar, Panagiotis Polygerinos
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Design, Development, and Control of a Fabric-Based Soft Ankle Module to Mimic Human Ankle Stiffness
This paper investigates the design of a robotic fabric-based, soft ankle module capable of generating 50% of the human ankle stiffness, in plantarflexion and dorsiflexion for walking. Kinematics, dynamics, and anatomy of the human ankle joint are studied to set the functional requirements of the module. The design of the compliant and lightweight soft ankle module uses fabric-based inflatable actuator arrays for actuation. Models for the human ankle stiffness, as well as a data-driven model of soft ankle module is presented. A high-level stiffness controller utilizing the human ankle and soft ankle model with a low-level pressure controller is implemented. We demonstrate the ability to closely follow the ankle stiffness trajectory using soft ankle module.
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