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We present a method for designing free gaits for a structurally symmetrical quadruped robot capable of performing statically stable,omnidirectional walking on irregular terrain.The robot’s virtual model is constructed and a control algorithm is proposed by applying virtual components at some strategic locations.The deliberative-based controller can generate fiexible sequences of leg transferences while maintaining walking speed,and choose optimum foothold for moving leg based on integration data of exteroceptive terrain profile.Simulation results are presented to show the gait’s efficiency and system’s stability in adapting to an uncertain terrain.
We present a method for designing free gaits for a structurally symmetrical quadruped robot capable of performing statically stable, omnidirectional walking on irregular terrain. The robot’s virtual model is constructed and a control algorithm is proposed by applying virtual components at some strategic locations. based controllers can generate fiexible sequences of leg transferences while maintaining walking speed, and choose optimum foothold for moving leg based on integration data of exteroceptive terrain profile. Simulation results are presented to show the gait’s efficiency and system’s stability in adapting to an uncertain terrain.