Rollover

About: Rollover is a research topic. Over the lifetime, 3166 publications have been published within this topic receiving 33077 citations.

Development and experimental evaluation of a slip angle estimator for vehicle stability control

Abstract: Real-time knowledge of the slip angle in a vehicle is useful in many active vehicle safety applications, including yaw stability control, rollover prevention and lane departure avoidance. Sensors to measure slip angle, including two antenna GPS systems and optical sensors are too expensive for ordinary automotive applications. This paper develops a realtime algorithm for estimation of slip angle using inexpensive sensors normally available for yaw stability control applications. Compared to previous results on slip angle estimation that have been published in literature, the algorithm utilizes a combination of model-based estimation and kinematics-based estimation and compensates for the presence of variations in tire-road characteristics. The developed algorithm is evaluated through experimental tests on a Volvo XC90 sport utility vehicle. Detailed experimental results show that the developed system can accurately estimate slip angle for a variety of test maneuvers.

Vehicle rollover sensing

Abstract: A rollover sensing apparatus and method are provided for predicting rollover and/or pitchover conditions of a vehicle. An angular rate sensor senses attitude rate of the vehicle, a first accelerometer measures horizontal acceleration of the vehicle, and a second accelerometer measures vertical acceleration of the vehicle. A current attitude angle is estimated with Kalman filtering and a future attitude angle is predicted at an advance time. The predicted attitude angle is compared to a threshold and an output is produced for indicating a predicted vehicle rollover condition based on the comparison. A vehicle rollover condition about the longitudinal axis of the vehicle is predicted by comparing a future roll angle to a rollover angle threshold, while a pitchover condition about the lateral axis of a vehicle is predicted by comparing a future pitch angle to a pitch angle threshold.

Vehicle rollover sensing using short-term integration

Abstract: A rollover sensing apparatus and method are provided for predicting rollover and/or pitchover conditions of a vehicle. An angular rate sensor senses attitude rate of the vehicle and an accelerometer measures vertical acceleration of the vehicle. A current attitude angle is estimated by integration, and a future attitude angle is predicted at an advance time as a function of the estimated current attitude angle and sensed attitude rate. The predicted attitude angle is compared to a threshold and an output is produced for indicating a predicted vehicle rollover condition based on the comparison. A vehicle rollover condition about the longitudinal axis of the vehicle is predicted by comparing a future roll angle to a rollover angle threshold, while a pitchover condition about the lateral axis of a vehicle is predicted by comparing a future pitch angle to a pitch angle threshold.

Understanding the limitations of different vehicle models for roll dynamics studies

Abstract: An accurate and realistic vehicle model is essential for the development of effective vehicle control systems. Many different vehicle models have been developed for use in various vehicle control systems. The complexity of these models and the assumptions made in their development depend on their application. This article looks into the development and validity of vehicle models for prediction of roll behavior and their suitability for application in roll control systems. A 14 DOF vehicle model that includes dynamics of roll center and nonlinear effects due to vehicle geometry changes is developed. The limitations, validity of simplified equations, and various modeling assumptions are discussed by analyzing their effect on the model roll responses in various vehicle maneuvers. A formulation of the popular 8 DOF vehicle model that gives good correlation with the 14 DOF model is presented. The possible limitations of the 14 DOF model compared with an actual vehicle are also discussed.