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Active Braking Control Design for Road Vehicles focuses on two main brake system technologies: hydraulically-activated brakes with on-off dynamics and electromechanical brakes, tailored to brake-by-wire control. The physical differences of such actuators enjoin the use of different control schemes so as to be able fully to exploit their characteristics.The authors show how these different control approaches are complementary, each having specific peculiarities in terms of either performance or of the structural properties of the closed-loop system. They also consider other problems related to the design of braking control systems, namely:- longitudinal vehicle speed estimation and its relationship with braking control system design;- tire-road friction estimation;- direct estimation of tire-road contact forces via in-tire sensors, providing a treatment of active vehicle braking control from a wider perspective linked to both advanced academic research and industrial reality.
List of contents
Braking Control Systems Design: Introduction and Modelling.- to Active Braking Control Systems.- Control-oriented Models of Braking Dynamics.- Braking Control Systems Design: Basic Solutions.- Braking Control Systems Design: Actuators with Continuous Dynamics.- Braking Control Systems Design: Actuators with Discrete Dynamics.- Longitudinal Wheel Slip Estimation.- Braking Control Systems Design: Advanced Solutions.- Mixed Slip and Deceleration Control.- Nonlinear Wheel Slip Control Design.- Identification of Tyre-road Friction Conditions.
About the author
Sergio M. Savaresi is Full Professor in Automatic Control at Politecnico di Milano since 2006 and head of the 'mOve' research team.
Summary
Active Braking Control Design for Road Vehicles focuses on two main brake system technologies: hydraulically-activated brakes with on–off dynamics and electromechanical brakes, tailored to brake-by-wire control. The physical differences of such actuators enjoin the use of different control schemes so as to be able fully to exploit their characteristics.
The authors show how these different control approaches are complementary, each having specific peculiarities in terms of either performance or of the structural properties of the closed-loop system. They also consider other problems related to the design of braking control systems, namely:
• longitudinal vehicle speed estimation and its relationship with braking control system design;
• tire–road friction estimation;
• direct estimation of tire–road contact forces via in-tire sensors, providing a treatment of active vehicle braking control from a wider perspective linked to both advanced academic research and industrial reality.
