Mechanics of Solids
A Journal of Russian Academy of Sciences

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Issues > Archive of Issues > 2025-7 > pp.6200-6218

Archive of Issues

Total articles in the database:		13554
In Russian (Изв. РАН. МТТ):		8194
In English (Mech. Solids):		5360

<< Previous article \| Volume 60, Issue 7 / 2025 \| Next article >>
Hayder F.N. Al-Shuka, "Robust H-infinity Control for Cart-Pole Systems: A Multi-Scenario Approach to Swing-Up and Stabilization," Mech. Solids. 60 (7), 6200-6218 (2025)
Year	2025	Volume	60	Number	7	Pages	6200-6218
DOI	10.1134/S0025654425604926
Title	Robust H-infinity Control for Cart-Pole Systems: A Multi-Scenario Approach to Swing-Up and Stabilization
Author(s)	Hayder F.N. Al-Shuka (Aeronautical Engineering Department, College of Engineering, University of Baghdad, Baghdad, 10070 Iraq, dr.hayder.f.n@coeng.uobaghdad.edu.iq)
Abstract	The cart-pole (C-P) system remains a classic yet challenging benchmark for nonlinear and underactuated control. This paper proposes a general and comprehensive multi-scenario H-infinity (H_∞) control framework that addresses swing-up and stabilization tasks without requiring explicit switching between controllers and is readily extendable to applications such as bipedal walking. The framework is evaluated through three complementary robust control designs: (i) Gain-scheduled H_∞ control via interpolation of locally linearized models, (ii) Feedback linearization combined with robust optimal control, and (iii) Adaptive approximation using orthogonal basis functions for real-time estimation of unmodeled dynamics. Simulation results at upright (θ=0) and inverted (θ=π) positions show that the adaptive H∞ controller outperforms all others, achieving a 1.5 s settling time, 5.2% overshoot, and steady-state error below 0.01 rad. It performs much better than PID and LQR controllers. These had a slower convergence rate and caused larger cart excursions. The feedback-lin-earized H_∞ controller also achieved strong results with a favourable balance between performance and implementation complexity. The methods suggested are confirmed by comparative analyses to provide scenarios with faster convergence, more robust performance, less control effort, and greater accuracy. These findings endorse the framework’s worthiness for real-world use in robotic balance, rehabilitation systems, and dynamic locomotion under uncertain conditions.
Keywords	H-infinity control, gain scheduling techniques, feedback linearization, cart-pole system
Received	08 September 2025	Revised	24 October 2025	Accepted	27 October 2025
Link to Fulltext	https://link.springer.com/article/10.1134/S0025654425604926
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