LQR-based control strategy for improving human–robot companionship and natural obstacle avoidance

• Published in: Biomimetic intelligence and robotics Vol. 4; no. 4; p. 100185
• Main Authors: Su, Zefan, Yao, Hanchen, Peng, Jianwei, Liao, Zhelin, Wang, Zengwei, Yu, Hui, Dai, Houde, Lueth, Tim C.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.12.2024; Elsevier
• Subjects: Behavioral dynamics; Human-accompanying robots; Human–robot interaction; Linear quadratic regulator; Human–robot interaction; Linear quadratic regulator; Behavioral dynamics; Human-accompanying robots
• ISSN: 2667-3797; 2667-3797
• DOI: 10.1016/j.birob.2024.100185

In the dynamic and unstructured environment of human–robot symbiosis, companion robots require natural human–robot interaction and autonomous intelligence through multimodal information fusion to achieve effective collaboration. Nevertheless, the control precision and coordination of the accompanying actions are not satisfactory in practical applications. This is primarily attributed to the difficulties in the motion coordination between the accompanying target and the mobile robot. This paper proposes a companion control strategy based on the Linear Quadratic Regulator (LQR) to enhance the coordination and precision of robot companion tasks. This method enables the robot to adapt to sudden changes in the companion target’s motion. Besides, the robot could smoothly avoid obstacles during the companion process. Firstly, a human–robot companion interaction model based on nonholonomic constraints is developed to determine the relative position and orientation between the robot and the companion target. Then, an LQR-based companion controller incorporating behavioral dynamics is introduced to simultaneously avoid obstacles and track the companion target’s direction and velocity. Finally, various simulations and real-world human–robot companion experiments are conducted to regulate the relative position, orientation, and velocity between the target object and the robot platform. Experimental results demonstrate the superiority of this approach over conventional control algorithms in terms of control distance and directional errors throughout system operation. The proposed LQR-based control strategy ensures coordinated and consistent motion with target persons in social companion scenarios.