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Sliding Mode Control for Rock Mass Vibration Stabilization: A Kelvin–Voigt Model with Impulsive Effects and Time-Varying Delays
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Sliding Mode Control for Rock Mass Vibration Stabilization: A Kelvin–Voigt Model with Impulsive Effects and Time-Varying Delays
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Journal Article
Sliding Mode Control for Rock Mass Vibration Stabilization: A Kelvin–Voigt Model with Impulsive Effects and Time-Varying Delays
2026
Overview
The stabilization of rock mass vibrations in underground excavations presents a critical engineering challenge due to the interplay of viscoelastic dynamics, impulsive shocks from blasting or rock bursts, and time-varying delays induced by wave propagation and sensor–actuator networks. In this paper, an integral sliding mode control scheme is developed for a Kelvin–Voigt type hyperbolic system subject to such impulsive effects and time-varying delays. To preserve sliding surface continuity under impulsive disturbances, the impulse information is explicitly incorporated into the design of the integral sliding function. The resulting sliding mode dynamics, which include discrete state jumps, are analyzed using a piecewise Lyapunov functional combined with inequality techniques; sufficient conditions are derived to guarantee asymptotic stability. Moreover, a sliding mode control law is synthesized to ensure that the system trajectories reach and remain on the sliding manifold from the initial time onward, despite parameter uncertainties and external disturbances. Numerical simulations with parameters reflecting realistic mining scenarios verify the effectiveness of the proposed control strategy, demonstrating its potential for practical rock mass vibration stabilization in geotechnical engineering.
Publisher
MDPI AG
