Stability control of a double inverted pendulum using a decoupled backstepping sliding mode strategy

Danh-Huy Nguyen; Van-Truong Nguyen; Trung-Hieu Luong; Xuan-Truong Vu; Thi-Van-Anh Nguyen

doi:10.64032/mca.v29i4.326

Các tác giả

Danh-Huy Nguyen School of Electrical and Electronic Engineering, Hanoi University of Science and Technology, Hanoi 100000, Vietnam
Van-Truong Nguyen School of Electrical and Electronic Engineering, Hanoi University of Science and Technology, Hanoi 100000, Vietnam
Trung-Hieu Luong School of Electrical and Electronic Engineering, Hanoi University of Science and Technology, Hanoi 100000, Vietnam
Xuan-Truong Vu Đại học Bách Khoa Hà Nội
Thi-Van-Anh Nguyen Đại học Bách Khoa Hà Nội

DOI:

https://doi.org/10.64032/mca.v29i4.326

Từ khóa:

Double Inverted Pendulum, Nonlinear Control, Backstepping, Sliding Mode Control

Tóm tắt

The double inverted pendulum on a cart (DIPC) is a classical benchmark in nonlinear control due to its high instability, underactuated structure, and complex dynamic behavior. Traditional control approaches, such as Linear Quadratic Regulators (LQR) or conventional Sliding Mode Control (SMC), often face limitations in robustness and dynamic decoupling when applied to such systems. In response to these challenges, this study presents a Decoupled Backstepping Sliding Mode Control (DB-SMC) strategy that integrates the systematic design framework of backstepping with the robustness properties of sliding mode control. By introducing intermediate virtual control surfaces, the DB-SMC method effectively decouples the dynamics of the cart and the two pendulums, simplifying controller design and improving system stability. The control law is derived using Lyapunov stability theory to ensure convergence and robustness in the presence of uncertainties. Simulation results demonstrate that the proposed method achieves fast convergence, reduced overshoot, and strong disturbance rejection compared to traditional methods. The effectiveness of the DB-SMC controller highlights its potential for broader applications in nonlinear and underactuated systems.