Synthesis of Ballistic Capture Corridors at Mars via Polynomial Chaos Expansion

The space sector is experiencing a flourishing growth and evidence is mounting that the near future will be characterized by a large amount of deep-space missions. In the last decade, CubeSats have granted affordable access to space due to their reduced manufacturing costs compared to traditional missions. At the present-day, most miniaturized spacecraft have thus far been deployed into near-Earth orbits, but soon a multitude of interplanetary CubeSats will be employed for deep-space missions as well. Nevertheless, the current paradigm for deep-space missions strongly relies on ground-based operations. Although reliable, this approach will rapidly cause saturation of ground slots, thereby hampering the current momentum in space exploration. At the actual pace, human-in-the-loop, flight-related operations for deep-space missions will soon become unsustainable. Self-driving spacecraft are challenging the current paradigm under which spacecraft are piloted in interplanetary space. They are intended as machines capable of traveling in deep space and autonomously reaching their destination. In EXTREMA, these systems are used to engineer ballistic capture (BC), thereby proving the effectiveness of autonomy in a complex scenario. The key is to accomplish low-thrust orbits culminating in BC. For this, a bundle of BC orbits named ballistic capture corridor (BCC) can be targeted far away from a planet. To achieve BC at Mars without any a priori instruction, an inexpensive and accurate method to construct BCC directly on board is required. Therefore, granting spacecraft the capability to manipulate stable sets in order to self-compute a BCC is crucial. The goal of the paper is to numerically synthesize a corridor exploiting the polynomial chaos expansion (PCE) technique, thereby applying a suited uncertainty propagation technique to BC orbit propagation.

[1]  F. Topputo,et al.  Qualitative study of ballistic capture at Mars via Lagrangian descriptors , 2023, Commun. Nonlinear Sci. Numer. Simul..

[2]  F. Topputo,et al.  Stable sets mapping with Taylor differential algebra with application to ballistic capture orbits around Mars , 2022, Celestial Mechanics and Dynamical Astronomy.

[3]  F. Topputo,et al.  Onboard Orbit Determination for Deep-Space CubeSats , 2022, Journal of Guidance, Control, and Dynamics.

[4]  F. Topputo,et al.  Mars orbit insertion via ballistic capture and aerobraking , 2021 .

[5]  Yang Wang,et al.  Envelop of reachable asteroids by M-ARGO CubeSat , 2021 .

[6]  W. Folkner,et al.  The JPL Planetary and Lunar Ephemerides DE440 and DE441 , 2021 .

[7]  Zong-Fu Luo,et al.  The role of the mass ratio in ballistic capture , 2020 .

[8]  Francesco Topputo,et al.  High-Fidelity Trajectory Optimization with Application to Saddle-Point Transfers , 2019, Journal of Guidance, Control, and Dynamics.

[9]  A. Hein,et al.  Exploring Potential Environmental Benefits of Asteroid Mining , 2018, 1810.04749.

[10]  R. Russell,et al.  Survey Of Mars Ballistic Capture Trajectories Using Periodic Orbits , 2018 .

[11]  Stephen Schwartz,et al.  Network of Nano-Landers for In-Situ Characterization of Asteroid Impact Studies , 2017, ArXiv.

[12]  Francesco Topputo,et al.  Capability of satellite-aided ballistic capture , 2017, Commun. Nonlinear Sci. Numer. Simul..

[13]  Saptarshi Bandyopadhyay,et al.  Review of Formation Flying and Constellation Missions Using Nanosatellites , 2016 .

[14]  F. Topputo,et al.  Analysis of ballistic capture in Sun–planet models , 2015 .

[15]  Francesco Topputo,et al.  Earth–Mars transfers with ballistic capture , 2014, 1410.8856.

[16]  F. Topputo,et al.  Constructing ballistic capture orbits in the real Solar System model , 2014 .

[17]  A. Doostan,et al.  Nonlinear Propagation of Orbit Uncertainty Using Non-Intrusive Polynomial Chaos , 2013 .

[18]  F. Topputo,et al.  Method to Design Ballistic Capture in the Elliptic Restricted Three-Body Problem , 2010 .

[19]  D. Xiu Numerical Methods for Stochastic Computations: A Spectral Method Approach , 2010 .

[20]  Dongbin Xiu,et al.  The Wiener-Askey Polynomial Chaos for Stochastic Differential Equations , 2002, SIAM J. Sci. Comput..

[21]  John P. Carrico,et al.  CALCULATION OF WEAK STABILITY BOUNDARY BALLISTIC LUNAR TRANSFER TRAJECTORIES , 2000 .

[22]  J. K. Miller,et al.  Sun-Perturbed Earth-to-Moon Transfers with Ballistic Capture , 1993 .

[23]  Robert G. Gottlieb,et al.  Fast gravity, gravity partials, normalized gravity, gravity gradient torque and magnetic field: Derivation, code and data , 1993 .

[24]  M. Watkins,et al.  Relativistic effects for near-earth satellite orbit determination , 1990, Celestial Mechanics and Dynamical Astronomy.

[25]  J. Dormand,et al.  High order embedded Runge-Kutta formulae , 1981 .

[26]  B. V. Semenov,et al.  A look towards the future in the handling of space science mission geometry , 2018 .

[27]  F. Topputo,et al.  A Technique for Designing Earth-Mars Low-Thrust Transfers Culminating in Ballistic Capture , 2018 .

[28]  S. Ceccherini,et al.  TRAJECTORY DESIGN IN HIGH-FIDELITY MODELS , 2018 .

[29]  Alessandro Golkar,et al.  CubeSat evolution: Analyzing CubeSat capabilities for conducting science missions , 2017 .

[30]  Oliver Montenbruck,et al.  Satellite Orbits: Models, Methods and Applications , 2000 .

[31]  C. H. Acton,et al.  Ancillary data services of NASA's Navigation and Ancillary Information Facility , 1996 .