Easy-To-Wear Auxetic SMA Knot-Architecture for Spatiotemporal and Multimodal Haptic Feedbacks

Wearable haptic interfaces prioritize user comfort, but also value the ability to provide diverse feedback patterns for immersive interactions with the virtual or augmented reality. Here, to provide both comfort and diverse tactile feedback, an easy-to-wear and multimodal wearable haptic auxetic fabric (WHAF) is prepared by knotting shape-memory alloy wires into an auxetic-structured fabric. This unique meta-design allows the WHAF to completely expand and contract in 3D, providing superior size-fitting and shape-fitting capabilities. Additionally, a microscale thin layer of Parylene is coated on the surface to create electrically separated zones within the WHAF, featuring zone-specified actuation for conveying diverse spatiotemporal information to users with using the WHAF alone. Depending on the body part it is worn on, the WHAF conveys either cutaneous or kinesthetic feedback, thus, working as a multimodal wearable haptic interface. As a result, when worn on the forearm, the WHAF intuitively provides spatiotemporal information to users during hands-free navigation and teleoperation in virtual reality, and when worn on the elbow, the WHAF guides users to reach the desired elbow flexion, like a personal exercise advisor. A novel auxetic-architectured wearable fabric actuator is developed by interlacing and knotting shape-memory alloy wires into auxetic structures. By incorporating meta-design, the auxetic-architectured fabric actuator shows unprecedented feature of size-fitting and self-fitting for superior wearability. Moreover, surface electrical property is adjusted to ensure zone-specified actuation, providing the wearer with spatiotemporally diverse multimodal tactile feedbackimage.

Automated summary

In this study, a wearable haptic auxetic fabric (WHAF) is developed by knotting shape-memory alloy wires into an auxetic-structured fabric. The WHAF expands and contracts in 3D, providing superior size-fitting and shape-fitting capabilities. It can convey cutaneous or kinesthetic feedback depending on the body part it is worn on, making it a multimodal wearable haptic interface.