Efficient Robustness Analysis along a Trajectory with Uncertain Initial Conditions
Research output: Contribution to journal › Conference article › Contributed › peer-review
Contributors
Abstract
Robustness analysis of uncertain nonlinear systems is often dominated by computationally expensive Monte-Carlo simulations, motivating the development of alternative approaches, including deterministic methods for worst-case assessment. An efficient solution approach is developed for a finite-horizon robustness analysis method that is based on a linear time-varying model along a nominal trajectory with quadratic constraints capturing nonlinear effects. The method leverages a transformed Riccati differential equation formulation with analytically optimized time-varying parameters to reduce computational complexity. Local quadratic constraints are iteratively refined using sparse grids. Application to Huygens’ atmospheric entry flight demonstrates accurate estimation of worst-case bounds with moderate
conservatism.
conservatism.
Details
| Original language | English |
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| Journal | IFAC-PapersOnLine |
| Publication status | Published - 2026 |
| Peer-reviewed | Yes |
Conference
| Title | 23rd World Congress of the International Federation of Automatic Control |
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| Abbreviated title | IFAC World Congress 2026 |
| Conference number | 23 |
| Duration | 23 - 28 August 2026 |
| Website | |
| Location | BEXCO |
| City | Busan |
| Country | Korea, Republic of |
External IDs
| ORCID | /0000-0001-6734-704X/work/216555321 |
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