Litcius/Paper detail

Risk-Averse Trajectory Optimization via Sample Average Approximation

Thomas Lew, Riccardo Bonalli, Marco Pavone

2023IEEE Robotics and Automation Letters19 citationsDOIOpen Access PDF

Abstract

Trajectory optimization under uncertainty underpins a wide range of applications in robotics. However, existing methods are limited in terms of reasoning about sources of epistemic and aleatoric uncertainty, space and time correlations, nonlinear dynamics, and non-convex constraints. In this work, we first introduce a continuous-time planning formulation with an average-value-at-risk constraint over the entire planning horizon. Then, we propose a sample-based approximation that unlocks an efficient and general-purpose algorithm for risk-averse trajectory optimization. We prove that the method is asymptotically optimal and derive finite-sample error bounds. Simulations demonstrate the high speed and reliability of the approach on problems with stochasticity in nonlinear dynamics, obstacle fields, interactions, and terrain parameters.

Topics & Concepts

TrajectoryMathematical optimizationNonlinear systemConstraint (computer-aided design)Range (aeronautics)Computer scienceRoboticsTrajectory optimizationObstacleSample (material)MathematicsRobotArtificial intelligenceOptimal controlEngineeringLawAstronomyQuantum mechanicsChromatographyPolitical sciencePhysicsChemistryGeometryAerospace engineeringRobotic Path Planning AlgorithmsAutonomous Vehicle Technology and SafetyAdvanced Multi-Objective Optimization Algorithms