A novel method for computing state transition matrices due to the unscented transform

Rahil Makadia; Davide Farnocchia; Steven R. Chesley; Siegfried Eggl

doi:10.1007/s10569-025-10247-1

A novel method for computing state transition matrices due to the unscented transform

Rahil Makadia, Davide Farnocchia, Steven R. Chesley, Siegfried Eggl

Research output: Contribution to journal › Article › peer-review

Abstract

We present a new method for computing the state transition matrix of a nonlinear dynamical system. The proposed method does not require the implementation of complex partial derivatives or auto-differentiation of the dynamics, while removing the arbitrary choice of a perturbation step for traditional finite difference methods. We tested the new state transition matrices using three different applications: a simple two-body problem, a Mars atmospheric entry flight mechanics problem, and two future close encounters of the asteroid (101955) Bennu with the Earth. Results show that the unscented transform state transition matrices preserve symplecticity and perform just as well as the classical unscented transform. Furthermore, the new method can closely reproduce posterior distributions generated using Monte Carlo simulations, even in the presence of significant stiffness in the dynamics.

Original language	English (US)
Article number	18
Journal	CELESTIAL MECHANICS AND DYNAMICAL ASTRONOMY
Volume	137
Issue number	3
Early online date	Apr 28 2025
DOIs	https://doi.org/10.1007/s10569-025-10247-1
State	Published - Jun 2025

Keywords

Celestial mechanics
Dynamical systems theory
Entry flight mechanics
Unscented transform

ASJC Scopus subject areas

Modeling and Simulation
Mathematical Physics
Astronomy and Astrophysics
Space and Planetary Science
Computational Mathematics
Applied Mathematics

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10.1007/s10569-025-10247-1License: CC BY

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abstract = "We present a new method for computing the state transition matrix of a nonlinear dynamical system. The proposed method does not require the implementation of complex partial derivatives or auto-differentiation of the dynamics, while removing the arbitrary choice of a perturbation step for traditional finite difference methods. We tested the new state transition matrices using three different applications: a simple two-body problem, a Mars atmospheric entry flight mechanics problem, and two future close encounters of the asteroid (101955) Bennu with the Earth. Results show that the unscented transform state transition matrices preserve symplecticity and perform just as well as the classical unscented transform. Furthermore, the new method can closely reproduce posterior distributions generated using Monte Carlo simulations, even in the presence of significant stiffness in the dynamics.",

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author = "Rahil Makadia and Davide Farnocchia and Chesley, {Steven R.} and Siegfried Eggl",

note = "R.M. acknowledges funding from a NASA Space Technology Graduate Research Opportunities (NSTGRO) award, NASA contract No. 80NSSC22K1173. The work of S.R.C. and D.F. was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with NASA (No. 80NM0018D0004). S.E. acknowledges support by the National Science Foundation through Award AST-2307570. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the National Science Foundation. This research made use of data and services provided by the International Astronomical Union Minor Planet Center.",

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AU - Makadia, Rahil

AU - Farnocchia, Davide

AU - Chesley, Steven R.

AU - Eggl, Siegfried

N1 - R.M. acknowledges funding from a NASA Space Technology Graduate Research Opportunities (NSTGRO) award, NASA contract No. 80NSSC22K1173. The work of S.R.C. and D.F. was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with NASA (No. 80NM0018D0004). S.E. acknowledges support by the National Science Foundation through Award AST-2307570. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the National Science Foundation. This research made use of data and services provided by the International Astronomical Union Minor Planet Center.

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Y1 - 2025/6

N2 - We present a new method for computing the state transition matrix of a nonlinear dynamical system. The proposed method does not require the implementation of complex partial derivatives or auto-differentiation of the dynamics, while removing the arbitrary choice of a perturbation step for traditional finite difference methods. We tested the new state transition matrices using three different applications: a simple two-body problem, a Mars atmospheric entry flight mechanics problem, and two future close encounters of the asteroid (101955) Bennu with the Earth. Results show that the unscented transform state transition matrices preserve symplecticity and perform just as well as the classical unscented transform. Furthermore, the new method can closely reproduce posterior distributions generated using Monte Carlo simulations, even in the presence of significant stiffness in the dynamics.

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KW - Dynamical systems theory

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A novel method for computing state transition matrices due to the unscented transform

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