Evolutionary Algorithm Guided Voxel-Encoding Printing of Functional Hard-Magnetic Soft Active Materials

TL;DR

This paper presents a novel voxel-encoding DIW printing method combined with an evolutionary algorithm to program complex magnetic density and direction distributions in hard-magnetic soft active materials, enabling advanced shape morphing and biomimetic motions.

Contribution

It introduces an EA-guided voxel-encoding printing technique that significantly expands the design space and functional capabilities of hmSAM structures.

Findings

Successfully programmed complex magnetic distributions in hmSAMs

Achieved advanced shape morphing with desired curvature distributions

Demonstrated biomimetic motions using the new printing method

Abstract

Hard-magnetic soft active materials (hmSAMs) have attracted a great amount of research interests due to their fast-transforming, untethered control, as well as excellent programmability. However, the current direct-ink-write (DIW) printing-based fabrication of hmSAM parts and structures only permits programmable magnetic direction with a constant magnetic density. Also, the existing designs rely on the brute-force approach to generate the assignment of magnetization direction distribution, which can only produce intuitional deformations. These two factors greatly limit the design space and the application potentials of hmSAMs. In this work, we introduce a voxel-encoding DIW printing method to program both the magnetic density and direction distributions during the hmSAM printing. The voxel-encoding DIW printing is then integrated with an evolutionary algorithm (EA)-based design strategy to achieve the desired magnetic actuation and motion with complex geometry variations and curvature distributions. With the new EA-guided voxel-encoding DIW printing technique, we demonstrate the functional hmSAMs that produce complicated shape morphing with desired curvature distributions for advanced applications such as biomimetic motions. These demonstrations indicate that the proposed EA-guided voxel-encoding DIW printing method can significantly broaden the application potentials of the hmSAMs.