论文信息 - Opening New Dimensions: Vehicle Motion Planning and Control using Brakes while Drifting

Opening New Dimensions: Vehicle Motion Planning and Control using Brakes while Drifting

Autonomous vehicles should be able to maintain control in scenarios that push them beyond the limits of handling. In case of unintended rear tire force saturation while driving, the vehicle should be able to decelerate while ensuring the navigation of an obstacle free path. With that objective, this paper presents a novel architecture capable of controlling a rear-wheel drive vehicle in a drift using brakes in addition to steering and throttle. We demonstrate the existence of another dimension of drift equilibria which allow motion planning algorithms to prescribe vehicle states independently even while drifting. A tangent space analysis illustrates the transformation from an under-actuated to a fully-actuated system with the use of front-wheel braking. Minimal modifications to existing state of the art in drifting can exploit the additional actuation to significantly increase the set of feasible actions for the vehicle. The framework is then experimentally validated for two different trajectories on MARTY, an electric DeLorean drift research platform.

J. C. Gerdes | J. Christian Gerdes | Jonathan Y. Goh | Tushar Goel | T. Goel

[1] J. Christian Gerdes,et al. A Controller Framework for Autonomous Drifting: Design, Stability, and Experimental Validation , 2014 .

[2] J. Christian Gerdes,et al. Toward Automated Vehicle Control Beyond the Stability Limits: Drifting Along a General Path , 2020 .

[3] Manfred Plöchl,et al. Handling characteristics and stability of the steady-state powerslide motion of an automobile , 2009 .

[4] J. Christian Gerdes,et al. Analysis and control of high sideslip manoeuvres , 2010 .

[5] J. Christian Gerdes,et al. Simultaneous stabilization and tracking of basic automobile drifting trajectories , 2016, 2016 IEEE Intelligent Vehicles Symposium (IV).

[6] Moritz Diehl,et al. CasADi: a software framework for nonlinear optimization and optimal control , 2018, Mathematical Programming Computation.

[7] J. Christian Gerdes,et al. Equilibrium Analysis of Drifting Vehicles for Control Design , 2009 .

[8] Morgan Quigley,et al. ROS: an open-source Robot Operating System , 2009, ICRA 2009.

[9] WächterAndreas,et al. On the implementation of an interior-point filter line-search algorithm for large-scale nonlinear programming , 2006 .

[10] Francesco Borrelli,et al. Predictive control for agile semi-autonomous ground vehicles using motion primitives , 2012, 2012 American Control Conference (ACC).

[11] Emilio Frazzoli,et al. Steady-state drifting stabilization of RWD vehicles , 2011 .