16 research outputs found
Lagrangian descriptors and their applications to deterministic chaos
We present our recent contributions to the theory of Lagrangian descriptors
for discriminating ordered and deterministic chaotic trajectories. The class of
Lagrangian Descriptors we are dealing with is based on the Euclidean length of
the orbit over a finite time window. The framework is free of tangent vector
dynamics and is valid for both discrete and continuous dynamical systems. We
review its last advancements and touch on how it illuminated recently Dvorak's
quantities based on maximal extent of trajectories' observables, as
traditionally computed in planetary dynamics.Comment: Submitted as part of the proceedings of the Complex Planetary Systems
II - Kalvi-IAU Symposium 382. 3 figures. Limited to 6 page
Drift and its mediation in terrestrial orbits
The slow deformation of terrestrial orbits in the medium range, subject to
lunisolar resonances, is well approximated by a family of Hamiltonian flow with
degree-of-freedom. The action variables of the system may experience
chaotic variations and large drift that we may quantify. Using variational
chaos indicators, we compute high-resolution portraits of the action space.
Such refined meshes allow to reveal the existence of tori and structures
filling chaotic regions. Our elaborate computations allow us to isolate precise
initial conditions near specific zones of interest and study their asymptotic
behaviour in time. Borrowing classical techniques of phase- space
visualisation, we highlight how the drift is mediated by the complement of the
numerically detected KAM tori.Comment: 22 pages, 11 figures, 1 table, 52 references. Comments and feedbacks
greatly appreciated. This article is part of the Research Topic `The
Earth-Moon System as a Dynamical Laboratory', confer
https://www.frontiersin.org/research-topics/5819/the-earth-moon-system-as-a-dynamical-laborator
Detection of separatrices and chaotic seas based on orbit amplitudes
The Maximum Eccentricity Method (MEM) is a standard tool for the analysis of
planetary systems and their stability. The method amounts to estimating the
maximal stretch of orbits over sampled domains of initial conditions. The
present paper leverages on the MEM to introduce a sharp detector of
separatrices and chaotic seas. After introducing the MEM analogue for
nearly-integrable action-angle Hamiltonians, i.e., diameters, we use
low-dimensional dynamical systems with multi-resonant modes and junctions,
supporting chaotic motions, to recognise the drivers of the diameter metric.
Once this is appreciated, we present a second-derivative based index measuring
the regularity of this application. This quantity turns to be a sensitive and
robust indicator to detect separatrices, resonant webs and chaotic seas. We
discuss practical applications of this framework in the context of -body
simulations for the planetary case affected by mean-motion resonances, and
demonstrate the ability of the index to distinguish minute structures of the
phase space, otherwise undetected with the original MEM.Comment: Under review at Celestial Mechanics and Dynamical Astronomy. 8
Figures, 59 references, 17 pages. Comments and feedback welcom
From order to chaos in Earth satellite orbits
We consider Earth satellite orbits in the range of semi-major axes where the
perturbing effects of Earth's oblateness and lunisolar gravity are of
comparable order. This range covers the medium-Earth orbits (MEO) of the Global
Navigation Satellite Systems and the geosynchronous orbits (GEO) of the
communication satellites. We recall a secular and quadrupolar model, based on
the Milankovitch vector formulation of perturbation theory, which governs the
long-term orbital evolution subject to the predominant gravitational
interactions. We study the global dynamics of this two-and-a-half
degrees-of-freedom Hamiltonian system by means of the fast Lyapunov indicator
(FLI), used in a statistical sense. Specifically, we characterize the degree of
chaoticity of the action space using angle-averaged normalized FLI maps,
thereby overcoming the angle dependencies of the conventional stability maps.
Emphasis is placed upon the phase-space structures near secular resonances,
which are of first importance to the space debris community. We confirm and
quantify the transition from order to chaos in MEO, stemming from the critical
inclinations, and find that highly inclined GEO orbits are particularly
unstable. Despite their reputed normality, Earth satellite orbits can possess
an extraordinarily rich spectrum of dynamical behaviors, and, from a
mathematical perspective, have all the complications that make them very
interesting candidates for testing the modern tools of chaos theory.Comment: 30 pages, 9 figures. Accepted for publication in the Astronomical
Journa
The Resident Space Objects Network:A Complex System Approach for Shaping Space Sustainability
Near-earth space continues to be the focus of critical services and capabilities provided to the society. With the steady increase of space traffic, the number of Resident Space Objects (RSOs) has recently boomed in the context of growing concern due to space debris. The need of a holistic and unified approach for addressing orbital collisions, assess the global in-orbit risk, and define sustainable practices for space traffic management has emerged as a major societal challenge. Here, we introduce and discuss a versatile framework rooted on the use of the complex network paradigm to introduce a novel risk index for space sustainability criteria. With an entirely data-driven, but flexible, formulation, we introduce the Resident Space Object Network (RSONet) by connecting RSOs that experience near-collisions events over a finite-time window. The structural collisional properties of RSOs are thus encoded into the RSONet and analysed with the tools of network science. We formulate a geometrical index highlighting the key role of specific RSOs in building up the risk of collisions with respect to the rest of the population. Practical applications based on Two-Line Elements and Conjunction Data Message databases are presented
A new analysis of the three--body problem
In the recent papers~[18],~[5], respectively, the existence of motions where
the perihelions afford periodic oscillations about certain equilibria and the
onset of a topological horseshoe have been proved. Such results have been
obtained using, as neighbouring integrable system, the so--called two--centre
(or {\it Euler}) problem and a suitable canonical setting proposed
in~[16],~[17]. Here we review such results.Comment: 27 pages, 3 figure
The dynamical structure of the MEO region: long-term stability, chaos, and transport
It has long been suspected that the Global Navigation Satellite Systems exist
in a background of complex resonances and chaotic motion; yet, the precise
dynamical character of these phenomena remains elusive. Recent studies have
shown that the occurrence and nature of the resonances driving these dynamics
depend chiefly on the frequencies of nodal and apsidal precession and the rate
of regression of the Moon's nodes. Woven throughout the inclination and
eccentricity phase space is an exceedingly complicated web-like structure of
lunisolar secular resonances, which become particularly dense near the
inclinations of the navigation satellite orbits. A clear picture of the
physical significance of these resonances is of considerable practical interest
for the design of disposal strategies for the four constellations. Here we
present analytical and semi-analytical models that accurately reflect the true
nature of the resonant interactions, and trace the topological organization of
the manifolds on which the chaotic motions take place. We present an atlas of
FLI stability maps, showing the extent of the chaotic regions of the phase
space, computed through a hierarchy of more realistic, and more complicated,
models, and compare the chaotic zones in these charts with the analytical
estimation of the width of the chaotic layers from the heuristic Chirikov
resonance-overlap criterion. As the semi-major axis of the satellite is
receding, we observe a transition from stable Nekhoroshev-like structures at
three Earth radii, where regular orbits dominate, to a Chirikov regime where
resonances overlap at five Earth radii. From a numerical estimation of the
Lyapunov times, we find that many of the inclined, nearly circular orbits of
the navigation satellites are strongly chaotic and that their dynamics are
unpredictable on decadal timescales.Comment: Submitted to Celestial Mechanics and Dynamical Astronomy. Comments
are greatly appreciated. 28 pages, 15 figure
Dynamical properties of the Molniya satellite constellation: long-term evolution of orbital eccentricity
The aim of this work is to analyze the orbital evolution of the mean
eccentricity given by the Two-Line Elements (TLE) set of the Molniya satellites
constellation. The approach is bottom-up, aiming at a synergy between the
observed dynamics and the mathematical modeling. Being the focus the long-term
evolution of the eccentricity, the dynamical model adopted is a doubly-averaged
formulation of the third-body perturbation due to Sun and Moon, coupled with
the oblateness effect on the orientation of the satellite. The numerical
evolution of the eccentricity, obtained by a two-degree-of-freedom model
assuming different orders in the series expansion of the third-body effect, is
compared against the mean evolution given by the TLE. The results show that,
despite being highly elliptical orbits, the second order expansion catches
extremely well the behavior. Also, the lunisolar effect turns out to be
non-negligible for the behavior of the longitude of the ascending node and the
argument of pericenter. The role of chaos in the timespan considered is also
addressed. Finally, a frequency series analysis is proposed to show the main
contributions that can be detected from the observational data
Lagrangian descriptors and their applications to deterministic chaos
We present our recent contributions to the theory of Lagrangian descriptors for discriminating ordered and deterministic chaotic trajectories. The class of Lagrangian Descriptors we are dealing with is based on the Euclidean length of the orbit over a finite time window. The framework is free of tangent vector dynamics and is valid for both discrete and continuous dynamical systems. We review its last advancements and touch on how it illuminated recently Dvorak’s quantities based on maximal extent of trajectories’ observables, as traditionally computed in planetary dynamics