Chance-Constrained Sequential Convex Programming for Robust Trajectory Optimization
Thomas Lew, Riccardo Bonalli, Marco Pavone
Abstract
Planning safe trajectories for nonlinear dynamical systems subject to model uncertainty and disturbances is challenging. In this work, we present a novel approach to tackle chance-constrained trajectory planning problems with nonconvex constraints, whereby obstacle avoidance chance constraints are reformulated using the signed distance function. We propose a novel sequential convex programming algorithm and prove that under a discrete time problem formulation, it is guaranteed to converge to a solution satisfying first-order optimality conditions. We demonstrate the approach on an uncertain 6 degrees of freedom spacecraft system and show that the solutions satisfy a given set of chance constraints.
Topics & Concepts
Mathematical optimizationNonlinear programmingTrajectoryTrajectory optimizationComputer scienceConvex optimizationSet (abstract data type)Regular polygonFeasible regionOptimization problemObstacleFunction (biology)MathematicsNonlinear systemOptimal controlAstronomyLawEvolutionary biologyBiologyQuantum mechanicsPolitical scienceGeometryProgramming languagePhysicsAdvanced Control Systems OptimizationRisk and Portfolio OptimizationAdvanced Optimization Algorithms Research