📝 SummarXiv

Abstract

Inspired by spiking neural feedback, we propose a spiking controller for efficient locomotion in a soft robotic crawler. Its bistability, akin to neural fast positive feedback, combined with a sensorimotor slow negative feedback loop, generates rhythmic spiking. The closed-loop system is robust through the quantized actuation, and negative feedback ensures efficient locomotion with minimal external tuning. We prove that peristaltic waves arise from a supercritical Hopf bifurcation controlled by the sensorimotor gain. Dimensional analysis reveals a separation of mechanical and electrical timescales, and Geometric Singular Perturbation analysis explains endogenous crawling through relaxation oscillations. We further formulate and analytically solve an optimization problem in the singularly perturbed regime, proving that crawling at mechanical resonance maximizes speed by a matching of neuromechanical scales. Given the importance and ubiquity of rhythms and waves in soft-bodied locomotion, we envision that spiking control systems could be utilized in a variety of soft-robotic morphologies and modular distributed architectures, yielding significant robustness, adaptability, and energetic gains across scales.