Abstract
While human walking has been well studied, the exact controller is unknown. This paper used human experimental walking data and system identification techniques to infer a human-like controller for a spring-loaded inverted pendulum (SLIP) model. Because the best system identification technique is unknown, three methods were used and compared. First, a linear system was found using ordinary least squares. A second linear system was found that both encoded the linearized SLIP model and matched the first linear system as closely as possible. A third nonlinear system used sparse identification of nonlinear dynamics (SINDY). When directly mapping states from the start to the end of a step, all three methods were accurate, with errors below 10% of the mean experimental values in most cases. When using the controllers in simulation, the errors were significantly higher but remained below 10% for all but one state. Thus, all three system identification methods generated accurate system models. Somewhat surprisingly, the linearized system was the most accurate, followed closely by SINDY. This suggests that nonlinear system identification techniques are not needed when finding a discrete human gait controller, at least for unperturbed walking. It may also suggest that human control of normal, unperturbed walking is approximately linear.
Highlights
While most people can walk without conscious thought, it requires appropriate coordination of leg joints, which arises from the central nervous system [1,2] and/or the natural dynamics of the system [3]
The third method used sparse identification of nonlinear dynamics (SINDY) with control and used a library of nonlinear functions to identify a linear combination of nonlinear functions that formed the system model and controller, referred to as the SINDY system JS and controller KS [28,29]
All three system identification methods performed well, with errors below 10% in most cases
Summary
While most people can walk without conscious thought, it requires appropriate coordination of leg joints, which arises from the central nervous system [1,2] and/or the natural dynamics of the system [3]. Given the redundancy in the human body, gait control is often assumed to follow a hierarchical structure such as the template and anchor paradigm [4]. Even with a simple template model, there are still many possible gaits, each of which can be described by a set of control parameters. The x m walking direction royalsocietypublishing.org/journal/rsos R.
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