Mixed-horizon optimal feedback control as a model of human movement

Computational optimal feedback control (OFC) models in the sensorimotor control literature span a vast range of different implementations. Among the popular algorithms, finite-horizon, receding-horizon or infinite-horizon linear-quadratic regulators (LQR) have been broadly used to model human reaching movements. While these different implementations have their unique merits, all three have limitations in simulating the temporal evolution of visuomotor feedback responses. Here we propose a novel approach - a mixed-horizon OFC - by combining the strengths of the traditional finite-horizon and the infinite-horizon controllers to address their individual limitations. Specifically, we use the infinite-horizon OFC to generate durations of the movements, which are then fed into the finite-horizon controller to generate control gains. We then demonstrate the stability of our model by performing extensive sensitivity analysis of both re-optimisation and different cost functions. Finally, we use our model to provide a fresh look to previously published studies by reinforcing the previous results, providing alternative explanations to previous studies, or generating new predictive results for prior experiments.      «

Computational optimal feedback control (OFC) models in the sensorimotor control literature span a vast range of different implementations. Among the popular algorithms, finite-horizon, receding-horizon or infinite-horizon linear-quadratic regulators (LQR) have been broadly used to model human reaching movements. While these different implementations have their unique merits, all three have limitations in simulating the temporal evolution of visuomotor feedback responses. Here we propose a novel...     »