Litcius/Paper detail

Risk-Averse RRT* Planning with Nonlinear Steering and Tracking Controllers for Nonlinear Robotic Systems Under Uncertainty

Sleiman Safaoui, Benjamin Gravell, Venkatraman Renganathan, Tyler Summers

20212021 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)21 citationsDOI

Abstract

We propose a two-phase risk-averse architecture for controlling stochastic nonlinear robotic systems. We present Risk-Averse Nonlinear Steering RRT* (RANS-RRT*) as an RRT* variant that incorporates nonlinear dynamics by solving a nonlinear program (NLP) and accounts for risk by approximating the state distribution and performing a distributionally robust (DR) collision check to promote safe planning. The generated plan is used as a reference for a low-level tracking controller. We demonstrate three controllers: finite horizon linear quadratic regulator (LQR) with linearized dynamics around the reference trajectory, LQR with robustness-promoting multiplicative noise terms, and a nonlinear model predictive control law (NMPC). We demonstrate the effectiveness of our algorithm using unicycle dynamics under heavy-tailed Laplace process noise in a cluttered environment.

Topics & Concepts

Control theory (sociology)Nonlinear systemRobustness (evolution)Computer scienceLinear-quadratic regulatorMultiplicative noiseRobust controlMathematical optimizationControl engineeringEngineeringOptimal controlMathematicsArtificial intelligenceControl (management)BiochemistryAnalog signalComputer hardwareSignal transfer functionGenePhysicsChemistryQuantum mechanicsDigital signal processingAdvanced Control Systems OptimizationFault Detection and Control SystemsControl Systems and Identification