Non-averaged regularized formulations as an alternative to semi-analytical orbit propagation methods

Amato, Davide; Bombardelli, Claudio; Baù, Giulio; Morand, Vincent; Rosengren, Aaron J.

doi:10.1007/s10569-019-9897-1

Cited by 24 publications

(15 citation statements)

References 47 publications

(48 reference statements)

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“…Amato et al [44] showed that special perturbation methods based on regularized formulations can compete and even outperform the semi-analytical methods for the long-term propagations (on the order of decades) of objects orbiting around the Earth. For this kind of applications, the Cowell formulation has never been used because of the required small integration step sizes, which causes strong accumulation of round-off error and long computational time.…”

Section: Work On the Ks And Quaternion Regularization Of The Two-body Problem Equations By Other Authorsmentioning

confidence: 99%

“…Stiefel and Scheifele [37] , Bordovitsyna [38] , Bordovitsyna and Avdyushev [39] , Fukushima [40][41] , Pelaez et al [42] , Bau et al [43] , Amato et al [44] , and Bau and Roa [45] demonstrated the results of comparing the numerical solutions to the equations of orbital motion of celestial and cosmic bodies in the KS variables, Euler parameters, and other variables. These results prove the efficiency of the KS variables and Euler parameters in celestial mechanics and astrodynamics.…”

Section: Introductionmentioning

confidence: 99%

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Quaternion methods and models of regular celestial mechanics and astrodynamics

Chelnokov

2022

Appl. Math. Mech.-Engl. Ed.

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This paper is a review, which focuses on our work, while including an analysis of many works of other researchers in the field of quaternionic regularization. The regular quaternion models of celestial mechanics and astrodynamics in the Kustaanheimo-Stiefel (KS) variables and Euler (Rodrigues-Hamilton) parameters are analyzed. These models are derived by the quaternion methods of mechanics and are based on the differential equations of the perturbed spatial two-body problem and the perturbed spatial central motion of a point particle. This paper also covers some applications of these models. Stiefel and Scheifele are known to have doubted that quaternions and quaternion matrices can be used efficiently to regularize the equations of celestial mechanics. However, the author of this paper and other researchers refuted this point of view and showed that the quaternion approach actually leads to efficient solutions for regularizing the equations of celestial mechanics and astrodynamics.This paper presents convenient geometric and kinematic interpretations of the KS transformation and the KS bilinear relation proposed by the present author. More general (compared with the KS equations) quaternion regular equations of the perturbed spatial two-body problem in the KS variables are presented. These equations are derived with the assumption that the KS bilinear relation was not satisfied. The main stages of the quaternion theory of regularizing the vector differential equation of the perturbed central motion of a point particle are presented, together with regular equations in the KS variables and Euler parameters, derived by the aforementioned theory. We also present the derivation of regular quaternion equations of the perturbed spatial two-body problem in the Levi-Civita variables and the Euler parameters, developed by the ideal rectangular Hansen coordinates and the orientation quaternion of the ideal coordinate frame.This paper also gives new results using quaternionic methods in the perturbed spatial restricted three-body problem.

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Section: Work On the Ks And Quaternion Regularization Of The Two-body Problem Equations By Other Authorsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quaternion methods and models of regular celestial mechanics and astrodynamics

Chelnokov

2022

Appl. Math. Mech.-Engl. Ed.

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“…This is a very demanding process in terms of CPU time (the computation of MiSO initial conditions for an individual constellation plane can take a few hours with an Intel Core processor i7-4790@3.6GHz) where the use of a very efficient orbit propagator is paramount. All numerical propagations were performed using the THALASSA orbit propagator [16], [17].…”

Section: Minimum Space Occupancy (Miso) Orbitsmentioning

confidence: 99%

Space Occupancy in Low-Earth Orbit

Bombardelli¹,

Falco²,

Amato³

et al. 2020

Preprint

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With the upcoming launch of large constellations of satellites in the low-Earth orbit (LEO) region it will become important to organize the physical space occupied by the different operating satellites in order to minimize critical conjunctions and avoid collisions. Here, we introduce the definition of space occupancy as the domain occupied by an individual satellite as it moves along its nominal orbit under the effects of environmental perturbations throughout a given interval of time. After showing that space occupancy for the zonal problem is intimately linked to the concept of frozen orbits and proper eccentricity, we provide

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“…Discussions on symplectic integration methods applied to celestial mechanics and astrodynamics can be found in [21,22,23,24]. Formulations tailored for specific problems include the DROMO regularized propagator [25] and its developments [26,27,28]. [29] describes a fast numerical integration technique using a low-fidelity force model for tracking purposes.…”

Section: Introductionmentioning

confidence: 99%

A method for accurate and efficient propagation of satellite orbits: A case study for a Molniya orbit

Flores

Burhani

Fantino

2021

Alexandria Engineering Journal

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Fast and precise propagation of satellite orbits is required for mission design, orbit determination and payload data analysis. We present a method to improve the computational performance of numerical propagators and simultaneously maintain the accuracy level required by any particular application. This is achieved by determining the positional accuracy needed and the corresponding acceptable error in acceleration on the basis of the mission requirements, removing those perturbation forces whose effect is negligible compared to the accuracy requirement, implementing an efficient and precise algorithm for the harmonic synthesis of the geopotential gradient (i.e., the gravitational acceleration) and adjusting the tolerance of the numerical propagator to achieve the prescribed accuracy level with minimum cost. In particular, to achieve the optimum balance between accuracy and computational performance, the number of geopotential spherical harmonics to retain is adjusted during the integration on the basis of the accuracy requirement. The contribution of high-order harmonics decays rapidly with altitude, so the minimum expansion degree meeting the target accuracy decreases with height. The optimum degree for each altitude is determined by making the truncation error of the harmonic synthesis equal to the admissible acceleration error. This paper presents a detailed description of the technique and test cases highlighting its accuracy and efficiency.

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Non-averaged regularized formulations as an alternative to semi-analytical orbit propagation methods

Cited by 24 publications

References 47 publications

Quaternion methods and models of regular celestial mechanics and astrodynamics

Quaternion methods and models of regular celestial mechanics and astrodynamics

Space Occupancy in Low-Earth Orbit

A method for accurate and efficient propagation of satellite orbits: A case study for a Molniya orbit

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