In this paper, we describe the development of a bipedal robot that models the neuromuscular architecture of human walking.  The body is based on principles derived from human muscular architecture, using muscles on straps to mimic agonist/antagonist muscle action as well as bifunctional muscles.  Load sensors in the straps model Golgi tendon organs.  The neural architecture is a central pattern generator (CPG) composed of a half-center oscillator combined with phase-modulated reflexes that is simulated using a spiking neural network.  We show that the interaction between the reflex system, body dynamics and CPG results in a walking cycle that is entrained to the dynamics of the system.  We also show that the CPG helped stabilize the gait against perturbations relative to a purely reflexive system, and compared the joint trajectories to human walking data.  This robot represents a complete physical, or neurorobotic, model of the system, demonstrating the usefulness of this type of robotics research for investigating the neurophysiological processes underlying walking in humans and animals.  [Journal of Neural Engineering, 5 Jul 2012]

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