Robust Entry Vehicle Guidance with Sampling-Based Invariant Funnels
Abstract
Managing uncertainty is a fundamental and critical issue in spacecraft entry guidance. This paper presents a novel approach for uncertainty propagation during entry, descent and landing that relies on a new sum-of-squares robust verification technique. Unlike risk-based and probabilistic approaches, our technique does not rely on any probabilistic assumptions. It uses a set-based description to bound uncertainties and disturbances like vehicle and atmospheric parameters and winds. The approach leverages a recently developed sampling-based version of sum-of-squares programming to compute regions of finite time invariance, commonly referred to as "invariant funnels". We apply this approach to a three-degree-of-freedom entry vehicle model and test it using a Mars Science Laboratory reference trajectory. We compute tight approximations of robust invariant funnels that are guaranteed to reach a goal region with increased landing accuracy while respecting realistic thermal constraints.
Cite
@article{arxiv.2011.02441,
title = {Robust Entry Vehicle Guidance with Sampling-Based Invariant Funnels},
author = {Remy Derollez and Simon Le Cleac'h and Zachary Manchester},
journal= {arXiv preprint arXiv:2011.02441},
year = {2020}
}
Comments
submitted to IEEE Aerospace Conference (AeroConf2021), Big Sky, MT