Litcius/Paper detail

Biased-MPPI: Informing Sampling-Based Model Predictive Control by Fusing Ancillary Controllers

Elia Trevisan, Javier Alonso–Mora

2024IEEE Robotics and Automation Letters25 citationsDOI

Abstract

Motion planning for autonomous robots in dynamic environments poses numerous challenges due to uncertainties in the robot's dynamics and interaction with other agents. Sampling-based MPC approaches, such as Model Predictive Path Integral (MPPI) control, have shown promise in addressing these complex motion planning problems. However, the performance of MPPI relies heavily on the choice of sampling distribution. Existing literature often uses the previously computed input sequence as the mean of a Gaussian distribution for sampling, leading to potential failures and local minima. We propose a novel derivation of MPPI that allows for arbitrary sampling distributions to enhance efficiency, robustness, and convergence while alleviating the problem of local minima. We present an efficient importance sampling scheme that combines classical and learning-based ancillary controllers simultaneously, resulting in more informative sampling and control fusion. Several simulated and real-world demonstrate the validity of our approach.

Topics & Concepts

Maxima and minimaSampling (signal processing)Robustness (evolution)Motion planningImportance samplingComputer scienceMathematical optimizationConvergence (economics)Machine learningRobotArtificial intelligenceControl theory (sociology)Control (management)MathematicsMonte Carlo methodStatisticsFilter (signal processing)Computer visionEconomic growthBiochemistryChemistryEconomicsMathematical analysisGeneFault Detection and Control SystemsMarkov Chains and Monte Carlo MethodsStability and Control of Uncertain Systems