Abstract
Analysis of complex human movements can provide valuable insights for movement rehabilitation, sports training, humanoid robot design and control, and human–robot interaction. To accomplish complex movement, the central nervous system must coordinate the musculo-skeletal system to achieve task and internal (e.g., effort minimisation) objectives. This paper proposes an inverse optimal control approach for analysing complex human movement that does not assume that the control objective(s) remains constant throughout the movement. The movement trajectory is assumed to be optimal with respect to a cost function composed of the sum of weighted basis cost functions, which may be time varying. The weights of the cost function are recovered using a sliding window. To illustrate the proposed approach, a dataset consisting of standing broad jump to targets at three different distances is collected. The method can be used to extract control objectives that influence task success, identify different motion strategies/styles, as well as to observe how control strategy changes during the motor learning process. Kinematic analysis confirms that the identified control objectives, including centre-of-mass takeoff vector and foot placement upon landing are important to ensure that a given participant lands on the target. The dataset, including nearly 800 jump trajectories from 22 participants is also provided.
Highlights
Analysis of complex human movements can provide valuable insights for movement rehabilitation, sports training, humanoid robot design and control, and human–robot interaction
The focus of this paper is to develop a methodology for analysing dynamic human movement by identifying the features or characteristics which are crucial to task success, and understanding optimal motor control behaviour required to complete the movement
This paper investigates an approach for identifying the control objectives from human movement data during complex movements
Summary
Analysis of complex human movements can provide valuable insights for movement rehabilitation, sports training, humanoid robot design and control, and human–robot interaction. This paper proposes an inverse optimal control approach for analysing complex human movement that does not assume that the control objective(s) remains constant throughout the movement. The focus of this paper is to develop a methodology for analysing dynamic human movement by identifying the features or characteristics which are crucial to task success, and understanding optimal motor control behaviour required to complete the movement. This paper investigates an approach for identifying the control objectives from human movement data during complex movements. We extend the prior work by applying the IOC analysis to a full body model, and a large data set of nearly 800 movement trajectories from 22 participants. The task has a clear task objective and metric of success, which facilitates evaluating task performance
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