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Using physics-based simulation towards eliminating empiricism in extraterrestrial terramechanics applications (2405.11001v1)

Published 17 May 2024 in astro-ph.IM, astro-ph.EP, and cs.RO

Abstract: Recently, there has been a surge of international interest in extraterrestrial exploration targeting the Moon, Mars, the moons of Mars, and various asteroids. This contribution discusses how current state-of-the-art Earth-based testing for designing rovers and landers for these missions currently leads to overly optimistic conclusions about the behavior of these devices upon deployment on the targeted celestial bodies. The key misconception is that gravitational offset is necessary during the \textit{terramechanics} testing of rover and lander prototypes on Earth. The body of evidence supporting our argument is tied to a small number of studies conducted during parabolic flights and insights derived from newly revised scaling laws. We argue that what has prevented the community from fully diagnosing the problem at hand is the absence of effective physics-based models capable of simulating terramechanics under low gravity conditions. We developed such a physics-based simulator and utilized it to gauge the mobility of early prototypes of the Volatiles Investigating Polar Exploration Rover (VIPER), which is slated to depart for the Moon in November 2024. This contribution discusses the results generated by this simulator, how they correlate with physical test results from the NASA-Glenn SLOPE lab, and the fallacy of the gravitational offset in rover and lander testing. The simulator developed is open sourced and made publicly available for unfettered use; it can support principled studies that extend beyond trafficability analysis to provide insights into in-situ resource utilization activities, e.g., digging, bulldozing, and berming in low gravity.

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References (93)
  1. An innovative space rover with extended climbing abilities, in: Robotics 2000, 2000, pp. 333–339.
  2. Mineralogy at gusev crater from the mossbauer spectrometer on the spirit rover, Science 305 (2004) 833–836.
  3. Mars 2020 mission overview, Space Science Reviews 216 (2020) 1–41.
  4. Surface characteristics of the zhurong mars rover traverse at utopia planitia, Nature Geoscience 15 (2022a) 171–176.
  5. A 2-year locomotive exploration and scientific investigation of the lunar farside by the yutu-2 rover, Science Robotics 7 (2022b) eabj6660.
  6. Evaluations of lunar regolith simulants, Planetary and Space Science 126 (2016) 1–7. URL: https://www.sciencedirect.com/science/article/pii/S003206331630023X. doi:https://doi.org/10.1016/j.pss.2016.04.005.
  7. Gravity-off-loading system for large-displacement ground testing of spacecraft mechanisms, in: Proceedings of the 40th aerospace mechanisms symposium, 2010.
  8. Advantages of continuous excavation in lightweight planetary robotic operations, The International Journal of Robotics Research 35 (2016) 1121–1139.
  9. P. Valle, Reduced gravity testing of robots (and humans) using the active response gravity offload system, in: International Conference on Intelligent Robots and Systems (IROS), JSC-CN-40487, 2017.
  10. Global planning on the mars exploration rovers: Software integration and surface testing, Journal of Field Robotics 26 (2009) 337–357.
  11. Traverse performance characterization for the Mars Science Laboratory rover, Journal of Field Robotics 30 (2013) 835–846.
  12. Design and characterization of GRC-1: A soil for lunar terramechanics testing in earth-ambient conditions, Journal of Terramechanics 47 (2010) 361–377. URL: https://www.sciencedirect.com/science/article/pii/S0022489810000388. doi:https://doi.org/10.1016/j.jterra.2010.04.006.
  13. Experimental evaluation of cone index gradient as a metric for the prediction of wheel performance in reduced gravity, Journal of Terramechanics 99 (2022) 1–16.
  14. Similitude studies of soil-machine systems, Journal of Terramechanics 7 (1970b) 25–58.
  15. Application of to soil-machine systems, Journal of Terramechanics 13 (1976) 153–182.
  16. General scaling relations for locomotion in granular media, Physical Review E 95 (2017) 052901.
  17. Expanded scaling relations for locomotion in sloped or cohesive granular beds, Physical Review Fluids 5 (2020) 114301.
  18. Granular scaling laws for helically driven dynamics, Physical Review E 102 (2020a) 032902.
  19. Comparative performance of granular scaling laws for lightweight grouser wheels in sand and lunar simulant, Powder Technology 373 (2020b) 336–346. URL: https://www.sciencedirect.com/science/article/pii/S0032591020304885. doi:https://doi.org/10.1016/j.powtec.2020.05.114.
  20. Z. Janosi, B. Hanamoto, The analytical determination of drawbar pull as a function of slip for tracked vehicles in deformable soils, in: Proc of the 1st int conf mech soil–vehicle systems. Turin, Italy, 1961.
  21. J. Y. Wong, A. R. Reece, Prediction of rigid wheel performance based on the analysis of soil-wheel stresses part I. Performance of driven rigid wheels, Journal of Terramechanics 4 (1967a) 81–98.
  22. J. Y. Wong, A. R. Reece, Prediction of rigid wheel performance based on the analysis of soil-wheel stresses: Part II. performance of towed rigid wheels, Journal of Terramechanics 4 (1967b) 7–25.
  23. Online terrain parameter estimation for wheeled mobile robots with application to planetary rovers, Robotics, IEEE Transactions on 20 (2004) 921–927.
  24. An equivalent soil mechanics formulation for rigid wheels in deformable terrain, with application to planetary exploration rovers, Journal of Terramechanics 42 (2005) 1–13.
  25. Experimental and simulation results of wheel-soil interaction for planetary rovers, in: 2005 IEEE/RSJ international conference on intelligent robots and systems, IEEE, 2005, pp. 586–591.
  26. Terramechanics-based model for steering maneuver of planetary exploration rovers on loose soil, Journal of Field robotics 24 (2007) 233–250.
  27. Contact dynamics simulation of rover locomotion, in: 9th International Symposium on Artificial Intelligence, Robotics and Automation in Space (iSAIRA), Universal City, CA, 2008.
  28. R. Krenn, G. Hirzinger, SCM – a soil contact model for multi-body system simulations, in: 11th European Regional Conference of the International Society for Terrain-Vehicle Systems - ISTVS 2009, 2009. URL: http://elib.dlr.de/60535/.
  29. R. Krenn, A. Gibbesch, Soft soil contact modeling technique for multi-body system simulation, in: Trends in computational contact mechanics, Springer, 2011, pp. 135–155.
  30. Physical and mechanical characteristics of lunar soil at the Chang’E-4 landing site, Geophysical Research Letters 47 (2020) e2020GL089499. URL: https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2020GL089499. doi:https://doi.org/10.1029/2020GL089499. arXiv:https://agupubs.onlinelibrary.wiley.com/doi/pdf/10.1029/2020GL089499.
  31. Real time simulation of ground vehicles on deformable terrain, in: Proceedings of ASME IDETC/CIE 2022, St. Louis, MO, 2022.
  32. The human-in-the-loop design approach to the longitudinal automation system for an intelligent vehicle, IEEE Transactions on Systems, Man, and Cybernetics-Part A: Systems and Humans 40 (2010) 708–720.
  33. Human-in-the-loop control of a humanoid robot for disaster response: a report from the darpa robotics challenge trials, Journal of Field Robotics 32 (2015) 275–292.
  34. Comparison of discrete element method and traditional modeling methods for steady-state wheel-terrain interaction of small vehicles, Journal of Terramechanics 56 (2014) 61–75.
  35. G. Meirion-Griffith, M. Spenko, A modified pressure–sinkage model for small, rigid wheels on deformable terrains, Journal of Terramechanics 48 (2011) 149–155.
  36. Mobility performance of a rigid wheel in low gravity environments, Journal of Terramechanics 47 (2010) 261–274.
  37. Interaction mechanics model for rigid driving wheels of planetary rovers moving on sandy terrain with consideration of multiple physical effects, Journal of Field Robotics 32 (2015) 827–859.
  38. J. Wong, Predicting the performances of rigid rover wheels on extraterrestrial surfaces based on test results obtained on earth, Journal of Terramechanics 49 (2012) 49–61. URL: https://www.sciencedirect.com/science/article/pii/S0022489811001005. doi:https://doi.org/10.1016/j.jterra.2011.11.002.
  39. A systematic approach to reliably characterize soils based on bevameter testing, Journal of Terramechanics 48 (2011) 360–371.
  40. Bevameter testing on simulant fillite for planetary rover mobility applications, Journal of Terramechanics 70 (2017) 13–26.
  41. A 2-year locomotive exploration and scientific investigation of the lunar farside by the yutu-2 rover, Science Robotics 7 (2022) eabj6660. URL: https://www.science.org/doi/abs/10.1126/scirobotics.abj6660. doi:10.1126/scirobotics.abj6660. arXiv:https://www.science.org/doi/pdf/10.1126/scirobotics.abj6660.
  42. Lunar rock investigation and tri-aspect characterization of lunar farside regolith by a digital twin, Nature Communications 15 (2024) 2098.
  43. On-line terrain parameter estimation for planetary rovers, in: Robotics and Automation, 2002. Proceedings. ICRA’02. IEEE International Conference on, volume 3, IEEE, 2002, pp. 3142–3147.
  44. Terrain characterization and classification with a mobile robot, Journal of field robotics 23 (2006) 103–122.
  45. A dynamic terramechanic model for small lightweight vehicles with rigid wheels and grousers operating in sandy soil, Journal of Terramechanics 48 (2011) 307–318. URL: https://www.sciencedirect.com/science/article/pii/S0022489811000334. doi:https://doi.org/10.1016/j.jterra.2011.05.001.
  46. High-speed mobility on planetary surfaces: A technical review, Journal of Field Robotics 36 (2019) 1436–1455.
  47. A particle method for history-dependent materials, Computer methods in applied mechanics and engineering 118 (1994) 179–196.
  48. The material point method for granular materials, Computer methods in applied mechanics and engineering 187 (2000) 529–541.
  49. Lagrangian meshfree particles method (sph) for large deformation and failure flows of geomaterial using elastic–plastic soil constitutive model, International Journal for Numerical and Analytical Methods in Geomechanics 32 (2008) 1537–1570.
  50. W. Chen, T. Qiu, Numerical simulations for large deformation of granular materials using smoothed particle hydrodynamics method, Int. J. Geomechanics 12 (2012) 127–135.
  51. J. Chauchat, M. Médale, A three-dimensional numerical model for dense granular flows based on the μ𝜇\muitalic_μ(I) rheology, Journal of Computational Physics 256 (2014) 696–712.
  52. Viscoplastic modeling of granular column collapse with pressure-dependent rheology, Journal of Non-Newtonian Fluid Mechanics 219 (2015) 1–18.
  53. S. Dunatunga, K. Kamrin, Continuum modeling of projectile impact and penetration in dry granular media, Journal of the Mechanics and Physics of Solids 100 (2017) 45–60.
  54. P. A. Cundall, O. D. Strack, A discrete numerical model for granular assemblies, Geotechnique 29 (1979) 47–65.
  55. DEM simulation of granular media—structure interface: effects of surface roughness and particle shape, International journal for numerical and analytical methods in geomechanics 23 (1999) 531–547.
  56. Discrete element method simulations of Mars exploration rover wheel performance, Journal of Terramechanics 62 (2015) 31–40.
  57. Three-dimensional discrete element modeling (DEM) of tillage: Accounting for soil cohesion and adhesion, Biosystems Engineering 129 (2015) 298–306.
  58. C.-L. Zhao, M.-Y. Zang, Application of the FEM/DEM and alternately moving road method to the simulation of tire-sand interactions, Journal of Terramechanics 72 (2017) 27–38.
  59. A high-fidelity approach for vehicle mobility simulation: Nonlinear finite element tires operating on granular material, Journal of Terramechanics 72 (2017) 39 – 54. URL: http://www.sciencedirect.com/science/article/pii/S0022489816301173. doi:https://doi.org/10.1016/j.jterra.2017.04.002.
  60. Traction control design for off-road mobility using an SPH-DAE co-simulation framework, Multibody System Dynamics 55 (2022) 165–188.
  61. Trends in large-deformation analysis of landslide mass movements with particular emphasis on the material point method, Géotechnique 66 (2016) 248–273.
  62. A. S. Baumgarten, K. Kamrin, A general fluid–sediment mixture model and constitutive theory validated in many flow regimes, Journal of Fluid Mechanics 861 (2019) 721–764.
  63. A new SPH-based approach to simulation of granular flows using viscous damping and stress regularisation, Landslides 14 (2017) 69–81.
  64. R. C. Hurley, J. E. Andrade, Continuum modeling of rate-dependent granular flows in SPH, Computational Particle Mechanics 4 (2017) 119–130.
  65. Analysis of fluid-particle interaction in granular materials using coupled sph-dem method, Powder Technology 353 (2019) 459–472.
  66. Gpu-accelerated smoothed particle hydrodynamics modeling of granular flow, Powder Technology 359 (2020) 94–106.
  67. Modeling granular material dynamics and its two-way coupling with moving solid bodies using a continuum representation and the SPH method, Computer Methods in Applied Mechanics and Engineering 385 (2021) 114022.
  68. Geotechnical properties of GRC-3 lunar simulant, Journal of Aerospace Engineering 26 (2013) 528–534.
  69. Chrono: An open source multi-physics dynamics engine, in: T. Kozubek (Ed.), High Performance Computing in Science and Engineering – Lecture Notes in Computer Science, Springer International Publishing, 2016, pp. 19–49.
  70. Compliant versus rigid contact: A comparison in the context of granular dynamics, Phys. Rev. E 96 (2017). doi:DOI:10.1103/PhysRevE.96.042905.
  71. Posing multibody dynamics with friction and contact as a differential complementarity problem, ASME JCND 13 (2017) 014503. doi:10.1115/1.4037415.
  72. Calibration of an expeditious terramechanics model using a higher-fidelity model, Bayesian inference, and a virtual bevameter test, Journal of Field Robotics in-print (2023). URL: {}{}}{https://doi.org/10.1002/rob.22276}{cmtt}.
  73. Surprising simplicity in the modeling of dynamic granular intrusion, Science Advances 7 (2021) eabe0631.
  74. L.~B. Lucy, A numerical approach to the testing of the fission hypothesis, The Astronomical Journal 82 (1977) 1013--1024.
  75. R.~A. Gingold, J.~J. Monaghan, Smoothed particle hydrodynamics-theory and application to non-spherical stars, Monthly Notices of the Royal Astronomical Society 181 (1977) 375--389.
  76. A sph approach for large deformation analysis with hypoplastic constitutive model, Acta Geotechnica 10 (2015) 703--717.
  77. S.~Dunatunga, K.~Kamrin, Continuum modelling and simulation of granular flows through their many phases, Journal of Fluid Mechanics 779 (2015) 483--513. doi:10.1017/jfm.2015.383.
  78. A.~Haeri, K.~Skonieczny, Three-dimensionsal granular flow continuum modeling via material point method with hyperelastic nonlocal granular fluidity, Computer Methods in Applied Mechanics and Engineering 394 (2022) 114904.
  79. J.~J. Monaghan, SPH without a tensile instability, Journal of Computational Physics 159 (2000) 290--311.
  80. SPH elastic dynamics, Computer methods in applied mechanics and engineering 190 (2001) 6641--6662.
  81. Continuum foam: A material point method for shear-dependent flows, ACM Transactions on Graphics (TOG) 34 (2015) 1--20.
  82. J.~J. Monaghan, Smoothed Particle Hydrodynamics, Reports on Progress in Physics 68 (2005) 1703--1759.
  83. R.~Fatehi, M.~T. Manzari, Error estimation in smoothed particle hydrodynamics and a new scheme for second derivatives, Computers & Mathematics with Applications 61 (2011) 482--498.
  84. A consistent spatially adaptive smoothed particle hydrodynamics method for fluid-structure interactions, Comp. Meth. in Applied Mech. and Eng. 347 (2019) 402--424.
  85. Numerical simulation of viscous flow by smoothed particle hydrodynamics, Progress of Theoretical Physics 92 (1994) 939--960.
  86. Modeling low Reynolds number incompressible flows using SPH, Journal of Computational Physics 136 (1997) 214--226.
  87. Smooth particle hydrodynamics simulations of low Reynolds number flows through porous media, International Journal for Numerical and Analytical Methods in Geomechanics 35 (2011) 419--437.
  88. Modeling electrokinetic flows by consistent implicit incompressible smoothed particle hydrodynamics, Journal of Computational Physics 334 (2017) 125--144.
  89. A consistent multi-resolution smoothed particle hydrodynamics method, Computer Methods in Applied Mechanics and Engineering 324 (2017) 278--299.
  90. Three-dimensional modeling of granular flow impact on rigid and deformable structures, Computers and Geotechnics 112 (2019) 257--271.
  91. X.~Bian, M.~Ellero, A splitting integration scheme for the SPH simulation of concentrated particle suspensions, Computer Physics Communications 185 (2014) 53--62.
  92. J.~J. Monaghan, On the problem of penetration in particle methods, Journal of Computational Physics 82 (1989) 1--15.
  93. J.~J. Monaghan, Simulating free surface flows with SPH, Journal of Computational Physics 110 (1994) 399--399.
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