期刊
JOURNAL OF BIOMECHANICAL ENGINEERING-TRANSACTIONS OF THE ASME
卷 143, 期 4, 页码 -出版社
ASME
DOI: 10.1115/1.4049159
关键词
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资金
- National Science Foundation [1344954, 1544702, 10.13039/100000001]
- Direct For Computer & Info Scie & Enginr
- Division Of Computer and Network Systems [1544702] Funding Source: National Science Foundation
This study explored the system identification of human standing balance, revealing the necessity of complex balance motions, long duration tests, and nonlinear controller models to obtain comprehensive control laws. The results demonstrated that multiple time-delay paths and nonlinear properties are essential in fully explaining human feedback control of standing balance.
Standing balance is a simple motion task for healthy humans but the actions of the central nervous system (CNS) have not been described by generalized and sufficiently sophisticated control laws. While system identification approaches have been used to extracted models of the CNS, they either focus on short balance motions, leading to task-specific control laws, or assume that the standing balance system is linear. To obtain comprehensive control laws for human standing balance, complex balance motions, long duration tests, and nonlinear controller models are all needed. In this paper, we demonstrate that trajectory optimization with the direct collocation method can achieve these goals to identify complex CNS models for the human standing balance task. We first examined this identification method using synthetic motion data and showed that correct control parameters can be extracted. Then, six types of controllers, from simple linear to complex nonlinear, were identified from 100s of motion data from randomly perturbed standing. Results showed that multiple time-delay paths and nonlinear properties are both needed in order to fully explain human feedback control of standing balance.
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