Integrating Contact-aware Feedback CPG System for Learning-based Soft Snake Robot Locomotion Controllers

TL;DR

This paper presents a novel contact-aware control system for soft snake robots, integrating bio-inspired sensors and a modified Matsuoka CPG with sensory feedback, enabling effective obstacle navigation in complex environments.

Contribution

It introduces a new sensory feedback mechanism for the Matsuoka CPG and two reactive controllers, advancing contact-aware locomotion control in soft snake robots.

Findings

Successful implementation in both simulation and real robots

Enhanced obstacle navigation capabilities

Validation of the bio-inspired sensory feedback system

Abstract

This paper aims to solve the contact-aware locomotion problem of a soft snake robot by developing bio-inspired contact-aware locomotion controllers. To provide effective contact information for the controllers, we develop a scale-covered sensor structure mimicking natural snakes' scale sensilla. In the design of the control framework, our core contribution is the development of a novel sensory feedback mechanism for the Matsuoka central pattern generator (CPG) network. This mechanism allows the Matsuoka CPG system to work like a "spinal cord" in the whole contact-aware control scheme, which simultaneously takes the stimuli including tonic input signals from the "brain" (a goal-tracking locomotion controller) and sensory feedback signals from the "reflex arc" (the contact reactive controller), and generates rhythmic signals to actuate the soft snake robot to slither through densely allocated obstacles. In the "reflex arc" design, we develop two distinctive types of reactive controllers -- 1) a reinforcement learning (RL) sensor regulator that learns to manipulate the sensory feedback inputs of the CPG system, and 2) a local reflexive sensor-CPG network that directly connects sensor readings and the CPG's feedback inputs in a specific topology. Combining with the locomotion controller and the Matsuoka CPG system, these two reactive controllers facilitate two different contact-aware locomotion control schemes. The two control schemes are tested and evaluated in both simulated and real soft snake robots, showing promising performance in the contact-aware locomotion tasks. The experimental results also validate the advantages of the modified Matsuoka CPG system with a new sensory feedback mechanism for bio-inspired robot controller design.