Abstract
To maintain balance during dynamic locomotion, the effects of proprioceptive sensory feedback control (e.g. reflexive control) should not be ignored because of its simple sensation and fast reaction time. Scientists have identified the pathways of reflexes; however, it is difficult to investigate their effects during locomotion because locomotion is controlled by a complex neural system and current technology does not allow us to change the control pathways in living humans. To understand these effects, we construct a musculoskeletal bipedal robot, which has similar body structure and dynamics to those of a human. By conducting experiments on this robot, we investigate the effects of reflexes (stretch reflex and crossed inhibitory response) on posture during hopping, a simple and representative bouncing gait with complex dynamics. Through over 300 hopping trials, we confirm that both the stretch reflex and crossed response can contribute to reducing the lateral inclination during hopping. These reflexive pathways do not use any prior knowledge of the dynamic information of the body such as its inclination. Beyond improving the understanding of the human neural system, this study provides roboticists with biomimetic ideas for robot locomotion control.
Highlights
The effects of brain control on dynamic locomotion have been widely investigated and recognized [1]
Through 382 hopping trials, we demonstrate that the stretch reflex can help in reducing lateral inclination, and a combination of the stretch reflex and crossed response can contribute to the reduction of lateral inclination even further
To obtain insight into the effects of the reflexes, in figure 4, we demonstrate the representative air pressure of the soleus muscles from touchdown to post lift-off (0–600 ms) and lateral inclination (u) over time during the stance phase with left-leaning landing (258, utd, 2 48) trails
Summary
The effects of brain control (e.g. visual and vestibular feedback control) on dynamic locomotion have been widely investigated and recognized [1] Proprioceptive control, such as reflexive control, should never be ignored as it can immediately react to a simple sensation. Understanding the human reflexive control can help scientists develop rehabilitation strategies for patients suffering from stroke [2,3] and spinal cord injuries [4,5]. It can can help roboticists develop methods for robot locomotion control [6,7]
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