March 3, 2026

Robustness Analysis of Huygens Atmospheric Entry Flight Under Uncertain Initial Conditions

Key Points

The analysis establishes an upper bound for robustness regarding atmospheric entry, enhancing confidence in mission success.
Critical analysis reveals the limitations of Monte-Carlo simulations, which only offer lower bounds for worst case scenarios.
Evaluation employs a method based on linear time-varying systems, effectively describing deviations from the nominal trajectory.
This method aims to increase mission reliability under uncertain initial conditions, highlighting a need for further validation.

Abstract

ESA's Huygens probe had only one attempt to successfully enter Titan's atmosphere. Due to large uncertainties, it was crucial to ensure the mission's robustness during the development phase. Common methods like Monte-Carlo simulations are computationally expensive and provide only a lower bound for worst case values. Therefore, this paper presents a robustness analysis method that determines the upper bound to complement Monte-Carlo simulation results and to increase the confidence in the mission's robustness. The developed method is based on linear time-varying systems and quadratic constraints to describe deviations from the nominal trajectory resulting from a set of uncertain initial conditions.

Bookmark

Robustness Analysis of Huygens Atmospheric Entry Flight Under Uncertain Initial Conditions

Key Points

Abstract

Cite This Study