An eight-neuron network for quadruped locomotion with hip-knee joint control

TL;DR

This paper presents an eight-neuron neural network inspired by biological CPGs, capable of generating multiple gaits and coordinating hip-knee joint control in quadruped robots, validated through simulations and real robot experiments.

Contribution

It introduces a symmetry-based design of an eight-neuron network for quadruped gait generation, enabling diverse gait patterns and joint coordination.

Findings

The network can produce five different gaits.

It achieves stable gait transitions via neuronal stimulation.

Successful implementation on a quadruped robot demonstrates practical feasibility.

Abstract

The gait generator, which is capable of producing rhythmic signals for coordinating multiple joints, is an essential component in the quadruped robot locomotion control framework. The biological counterpart of the gait generator is the Central Pattern Generator (abbreviated as CPG), a small neural network consisting of interacting neurons. Inspired by this architecture, researchers have designed artificial neural networks composed of simulated neurons or oscillator equations. Despite the widespread application of these designed CPGs in various robot locomotion controls, some issues remain unaddressed, including: (1) Simplistic network designs often overlook the symmetry between signal and network structure, resulting in fewer gait patterns than those found in nature. (2) Due to minimal architectural consideration, quadruped control CPGs typically consist of only four neurons, which restricts the network's direct control to leg phases rather than joint coordination. (3) Gait changes are achieved by varying the neuron couplings or the assignment between neurons and legs, rather than through external stimulation. We apply symmetry theory to design an eight-neuron network, composed of Stein neuronal models, capable of achieving five gaits and coordinated control of the hip-knee joints. We validate the signal stability of this network as a gait generator through numerical simulations, which reveal various results and patterns encountered during gait transitions using neuronal stimulation. Based on these findings, we have developed several successful gait transition strategies through neuronal stimulations. Using a commercial quadruped robot model, we demonstrate the usability and feasibility of this network by implementing motion control and gait transitions.