Modular Control of Limit Cycle Locomotion over Unperceived Rough Terrain

We present a general approach to design modular controllers for limit cycle locomotion over unperceived rough terrain. The control strategy uses a Central Pattern Generator (CPG) model implemented as coupled nonlinear oscillators as basis. Stumbling correction and leg extension reflexes are implemented as feedbacks for fast corrections, and model-based posture control mechanisms define feedbacks for continuous corrections. The control strategy is validated on a detailed physics-based simulated model of a compliant quadruped robot, the Oncilla robot. We demonstrate dynamic locomotion with a speed of more than 1.5 BodyLength/s over unperceived uneven terrains, steps, and slopes.

Modular Control of Limit Cycle Locomotion over Unperceived Rough Terrain

Online Bipedal Locomotion Adaptation for Stepping on Obstacles Using a Novel Foot Sensor

A computational modeling approach to study the neuromechanics of terrestrial locomotion

Sensory modulation of gait characteristics in human locomotion: A neuromusculoskeletal modeling study

A computational modeling approach to study the neuromechanics of terrestrial locomotion

Online Bipedal Locomotion Adaptation for Stepping on Obstacles Using a Novel Foot Sensor

Sensory modulation of gait characteristics in human locomotion: A neuromusculoskeletal modeling study