Unified Modeling and Structural Optimization of Multi-magnet Embedded Soft Continuum Robots for Enhanced Kinematic Performances

This paper presents a unified modeling and optimization framework to enhance the kinematic performance of multi-magnet embedded soft continuum robots (MeSCRs). To this end, we establish a differentiable system formulation based on an extended pseudo-rigid-body model. This formulation enables analysis of the equilibrium well-posedness and the geometry of the induced configuration under magnetic actuation. In particular, we show that the maximum controllable degrees of freedom of a MeSCR equal twice the number of embedded magnets. We subsequently develop a structural optimization framework based on differential geometry that links classical kinematic measures (e.g., manipulability and dexterity) to the configuration of embedded magnets. The resulting optimization condition reveals that improving local performance requires structurally modulating the spectrum of the configuration space metric to counteract its distortion. Closed-form solutions for optimal magnet configurations are derived under representative conditions, and a gradient-based numerical method is proposed for general design scenarios. Simulation studies validate the effectiveness of the proposed framework.