Electronic Skins for Soft, Compact, Reversible Assembly of Wirelessly Activated Fully Soft Robots

Overview

Journal Sci Robot

Specialties Biomedical Engineering
Biotechnology

Date 2020 Nov 3

PMID 33141703

Citations 39

Authors

Junghwan Byun

Yoontaek Lee

Jaeyoung Yoon

Byeongmoon Lee

Eunho Oh

Seungjun Chung

Takhee Lee

Kyu-Jin Cho

Jaeha Kim

Yongtaek Hong

Affiliations

Soon will be listed here.

Abstract

Designing softness into robots holds great potential for augmenting robotic compliance in dynamic, unstructured environments. However, despite the body's softness, existing models mostly carry inherent hardness in their driving parts, such as pressure-regulating components and rigid circuit boards. This compliance gap can frequently interfere with the robot motion and makes soft robotic design dependent on rigid assembly of each robot component. We present a skin-like electronic system that enables a class of wirelessly activated fully soft robots whose driving part can be softly, compactly, and reversibly assembled. The proposed system consists of two-part electronic skins (e-skins) that are designed to perform wireless communication of the robot control signal, namely, "wireless inter-skin communication," for untethered, reversible assembly of driving capability. The physical design of each e-skin features minimized inherent hardness in terms of thickness (<1 millimeter), weight (~0.8 gram), and fragmented circuit configuration. The developed e-skin pair can be softly integrated into separate soft body frames (robot and human), wirelessly interact with each other, and then activate and control the robot. The e-skin-integrated robotic design is highly compact and shows that the embedded e-skin can equally share the fine soft motions of the robot frame. Our results also highlight the effectiveness of the wireless inter-skin communication in providing universality for robotic actuation based on reversible assembly.

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