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Implicit Trajectory Planning for Feedback Linearizable Systems: A Time-varying Optimization Approach

Tianqi Zheng, John W. Simpson-Porco, Enrique Mallada

202021 citationsDOI

Abstract

We develop an optimization-based framework for joint real-time trajectory planning and feedback control of feedback-linearizable systems. To achieve this goal, we define a target trajectory as the optimal solution of a time-varying optimization problem. In general, however, such trajectory may not be feasible due to, e.g., nonholonomic constraints. To solve this problem, we design a control law that generates feasible trajectories that asymptotically converge to the target trajectory. More precisely, for systems that are (dynamic) full-state linearizable, the proposed control law implicitly transforms the nonlinear system into an optimization algorithm of sufficiently high order. We prove global exponential convergence to the target trajectory for both the optimization algorithm and the original system. We illustrate the effectiveness of our proposed method on multi-object or multi-agent tracking problems with constraints.

Topics & Concepts

TrajectoryTrajectory optimizationNonholonomic systemConvergence (economics)Control theory (sociology)Computer scienceOptimization problemMathematical optimizationNonlinear systemOptimal controlMathematicsControl (management)RobotMobile robotArtificial intelligenceEconomicsAstronomyPhysicsEconomic growthQuantum mechanicsRobotic Path Planning AlgorithmsControl and Dynamics of Mobile RobotsDistributed Control Multi-Agent Systems
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