High-stretchability and low-hysteresis strain sensors using origami-inspired 3D mesostructures

Stretchable strain sensors are essential for various applications such as wearable electronics, prosthetics, and soft robotics. Strain sensors with high strain range, minimal hysteresis, and fast response speed are highly desirable for accurate measurements of large and dynamic deformations of soft bodies. Current stretchable strain sensors mostly rely on deformable conducting materials, which often have difficulties in achieving these properties simultaneously. In this study, we introduce capacitive strain sensor concepts based on origami-inspired three-dimensional mesoscale electrodes formed by a mechanically guided assembly process. These sensors exhibit up to 200% stretchability with 1.2% degree of hysteresis, < 22 ms response time, small sensing area (similar to 5 mm(2)), and directional strain responses. To showcase potential applications, we demonstrate the use of distributed strain sensors for measuring multimodal deformations of a soft continuum arm.

Automated summary

Stretchable strain sensors are important for various applications, and this study introduces capacitive strain sensor concepts based on origami-inspired three-dimensional electrodes, which have high stretchability, low hysteresis, fast response time, small sensing area, and directional strain responses. The potential application of distributed strain sensors for measuring multimodal deformations of a soft continuum arm is demonstrated.