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Design and analysis of a novel cascade control algorithm for braking-by-wire system based on electromagnetic direct-drive valves

Cao Tan, Haoxin Ren, Bo Li, Jiayu Lu, Dexiang Li, Wenming Tao

2022Journal of the Franklin Institute28 citationsDOIOpen Access PDF

Abstract

In order to improve the response speed and control precision of the braking system with parameters uncertainty and nonlinear friction, a braking-by-wire system based on the electromagnetic direct-drive valve and a novel cascade control algorithm was proposed in this paper. An electromagnetic linear actuator directly drives the valve spool and rapidly adjusts the pressure of braking wheel cylinders. A dynamic model of electromagnetic direct-drive valve considering improved LuGre dynamic friction is established. A novel cascade control algorithm with an outside loop pressure fuzzy controller and an inside loop electromagnetic direct-drive valve position controller was proposed. An adaptive integral robust inside loop controller is designed by combining friction compensation adaptive control law, linear feedback, and integral robust control. The uncertainty parameters and the friction state are estimated online. The stability of the cascade controller is proved by the Lyapunov method. Then a multi-objective opitimizemization design method of control parameters is proposed, which combines a multi-objective game theory and a technique for order preference by similarity to ideal solution (TOPSIS) based on entropy weight. The results show that the pressurization time of cascade control is less than 0.09 s under the 15 MPa step target signal. The control precision is improved effectively by the cascade controller under the ARTEMIS condition.

Topics & Concepts

CascadeComputer scienceControl engineeringControl theory (sociology)EngineeringAutomotive engineeringAlgorithmControl (management)Artificial intelligenceChemical engineeringHydraulic and Pneumatic SystemsElectric and Hybrid Vehicle TechnologiesVehicle Dynamics and Control Systems