What question did this study set out to answer?

This research aims to develop a control method for the double-steering wheeled climbing robot under uncertainties.

March 15, 2026Open Access

Modeling and Trajectory Tracking Control for Double- Steering Wheeled Climbing Robot Based on Adaptive Dynamic Programming

Key Points

This research aims to develop a control method for the double-steering wheeled climbing robot under uncertainties.
Established a dynamic model using Lagrange equation, considering slipping and friction effects.
Proposed an adaptive dynamic programming controller to address tracking problems.
Conducted simulations and prototype experiments to verify the control method's effectiveness.
Demonstrated stability of the tracking system and weight convergence in neural networks.
Showed robustness of the proposed control method under state and model uncertainties.
Verified optimality through simulations and experimental outcomes.

Abstract

A model and tracking control method for a double-steering wheeled climbing robot (DSWCR) are presented in this article. The dynamic model of the DSWCR system is established using the Lagrange equation, considering the effects of slipping, variations in gravity and the friction coefficient, and wall/wheel interaction forces. During wall motion, the DSWCR is subject to uncertainties introduced from both the state and model. To address the tracking problem of the DSWCR under state and model uncertainties, an adaptive dynamic programming (ADP) controller based on zero-sum theory is proposed. The stability of the DSWCR tracking system and the convergence of the weights in a neural network are demonstrated. Finally, simulations and a prototype experiment are conducted to verify the optimality and robustness of the proposed control method.

Modeling and Trajectory Tracking Control for Double- Steering Wheeled Climbing Robot Based on Adaptive Dynamic Programming

Key Points

Abstract

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