Adaptive Optimal Tracking Control Applied for a Humanoid Robot Arm

David Hemmi; Guido Herrmann; Jing Na; Muhammad Mahyuddin

Adaptive Optimal Tracking Control Applied for a Humanoid Robot Arm

David Hemmi, Guido Herrmann, Jing Na, Muhammad Mahyuddin

Research output: Chapter in Book/Conference proceeding › Chapter › peer-review

Abstract

In this paper, a recently suggested adaptive online optimal control algorithm for the infinite-horizon tracking problem of continuous-time non-linear systems with partially unknown system dynamics is modified and empirically evalu- ated. Since we lack complete systems knowledge a parameter identifier, which works simultaneously with the updating of the online optimal control algorithm, is introduced. We maintain tracking performance by employing an adaptive steady-state controller based on the identified system parameters and a complementary self optimizing adaptive controller, designed to stabilize the plant. To approximate the optimal value function of the Hamilton-Jacobi-Bellman equation, which is required to construct the adaptive optimal stability controller, a single layer neural network is utilized. Both the findings obtained in practice by controlling a humanoid robot-arm , as well as the results produced in simulation, demonstrate the applicability of the introduced control scheme.

Original language	English
Title of host publication	Proceeding of the 2015 IEEE Multi-Conference on Systems and Control (IEEE International Symposium on Intelligent Control (ISIC)), Sydney, Australia
Publication status	Published - 2015

Cite this

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title = "Adaptive Optimal Tracking Control Applied for a Humanoid Robot Arm",

abstract = "In this paper, a recently suggested adaptive online optimal control algorithm for the infinite-horizon tracking problem of continuous-time non-linear systems with partially unknown system dynamics is modified and empirically evalu- ated. Since we lack complete systems knowledge a parameter identifier, which works simultaneously with the updating of the online optimal control algorithm, is introduced. We maintain tracking performance by employing an adaptive steady-state controller based on the identified system parameters and a complementary self optimizing adaptive controller, designed to stabilize the plant. To approximate the optimal value function of the Hamilton-Jacobi-Bellman equation, which is required to construct the adaptive optimal stability controller, a single layer neural network is utilized. Both the findings obtained in practice by controlling a humanoid robot-arm , as well as the results produced in simulation, demonstrate the applicability of the introduced control scheme.",

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language = "English",

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T1 - Adaptive Optimal Tracking Control Applied for a Humanoid Robot Arm

AU - Hemmi, David

AU - Herrmann, Guido

AU - Na, Jing

AU - Mahyuddin, Muhammad

PY - 2015

Y1 - 2015

N2 - In this paper, a recently suggested adaptive online optimal control algorithm for the infinite-horizon tracking problem of continuous-time non-linear systems with partially unknown system dynamics is modified and empirically evalu- ated. Since we lack complete systems knowledge a parameter identifier, which works simultaneously with the updating of the online optimal control algorithm, is introduced. We maintain tracking performance by employing an adaptive steady-state controller based on the identified system parameters and a complementary self optimizing adaptive controller, designed to stabilize the plant. To approximate the optimal value function of the Hamilton-Jacobi-Bellman equation, which is required to construct the adaptive optimal stability controller, a single layer neural network is utilized. Both the findings obtained in practice by controlling a humanoid robot-arm , as well as the results produced in simulation, demonstrate the applicability of the introduced control scheme.

AB - In this paper, a recently suggested adaptive online optimal control algorithm for the infinite-horizon tracking problem of continuous-time non-linear systems with partially unknown system dynamics is modified and empirically evalu- ated. Since we lack complete systems knowledge a parameter identifier, which works simultaneously with the updating of the online optimal control algorithm, is introduced. We maintain tracking performance by employing an adaptive steady-state controller based on the identified system parameters and a complementary self optimizing adaptive controller, designed to stabilize the plant. To approximate the optimal value function of the Hamilton-Jacobi-Bellman equation, which is required to construct the adaptive optimal stability controller, a single layer neural network is utilized. Both the findings obtained in practice by controlling a humanoid robot-arm , as well as the results produced in simulation, demonstrate the applicability of the introduced control scheme.

M3 - Chapter

BT - Proceeding of the 2015 IEEE Multi-Conference on Systems and Control (IEEE International Symposium on Intelligent Control (ISIC)), Sydney, Australia

ER -

Adaptive Optimal Tracking Control Applied for a Humanoid Robot Arm

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