Optimized curvilinear potential field based multi-objective satellite collision avoidance maneuver
| dc.Affiliation | October University for modern sciences and Arts (MSA) | |
| dc.contributor.author | Refaat A. | |
| dc.contributor.author | Badawy A. | |
| dc.contributor.author | Omer A.A. | |
| dc.contributor.author | Ashry M. | |
| dc.contributor.other | Egyptian Armed Forces | |
| dc.contributor.other | Cairo | |
| dc.contributor.other | 11528 | |
| dc.contributor.other | Egypt; October University for Modern Sciences and Arts MSA | |
| dc.contributor.other | Cairo | |
| dc.contributor.other | 12566 | |
| dc.contributor.other | Egypt; Military technical college | |
| dc.contributor.other | MTC | |
| dc.contributor.other | Cairo | |
| dc.contributor.other | 11712 | |
| dc.contributor.other | Egypt | |
| dc.date.accessioned | 2020-01-09T20:40:43Z | |
| dc.date.available | 2020-01-09T20:40:43Z | |
| dc.date.issued | 2019 | |
| dc.description | Scopus | |
| dc.description.abstract | Recently, as the incredible growth of space objects, the most important issue for nearly all centers of space mission control (MCC) try to avoid is the problem of collision avoidance and allow a free path for the spacecraft during the whole lifetime, as the problem can be broken into two main parts the first is supply by data and some organizations play this role as the SPACE DATA ASSOCIATION CONJUNCTION ANALYSIS OPERATIONS in USA and SMARTnet in Germany, the second part is our Circle of Concern to use such information for automated task of collision avoidance maneuver planning and execution. This paper develops a new technique used usually during docking operations known as artificial potential field (APF) but as the key factors before performing any maneuver in space are the fuel budget, time and the safety of the new trajectory, so a new genetic-APF is used. In this paper, a new potential field technique is used with genetic algorithm for optimizing the coefficients in the algorithm, Moreover the criteria for judging the collision is based upon the curvilinear distance between the satellites not the Euclidean distance for calculating the Time to collision (TTC), a real case study output with calculation of orbit dynamics of spacecraft using ARE_orbit_propagator, a high precision orbit propagation developed using c#, output the velocity (?v) required for each case that will be supplied to the propulsion control module is used between the Chinese �cz_4� and the United States �DMSP 5D-2 F7� satellites to clarify the difference between the traditional potential field and the new genetic-based artificial potential field with also comparing the results with the well-known Hohmann maneuver for changing the altitude. � 2019, American Institute of Aeronautics and Astronautics Inc, AIAA. All rights reserved. | en_US |
| dc.identifier.doi | https://doi.org/10.2514/6.2019-3875 | |
| dc.identifier.doi | PubMed ID : | |
| dc.identifier.isbn | 9.78E+12 | |
| dc.identifier.other | https://doi.org/10.2514/6.2019-3875 | |
| dc.identifier.other | PubMed ID : | |
| dc.identifier.uri | https://t.ly/PMPDX | |
| dc.language.iso | English | en_US |
| dc.publisher | [publishername] American Institute of Aeronautics and Astronautics Inc, AIAA | en_US |
| dc.relation.ispartofseries | AIAA Propulsion and Energy Forum and Exposition, 2019 | |
| dc.subject | Altitude control | en_US |
| dc.subject | Budget control | en_US |
| dc.subject | Collision avoidance | en_US |
| dc.subject | Free flight | en_US |
| dc.subject | Genetic algorithms | en_US |
| dc.subject | Orbits | en_US |
| dc.subject | Satellites | en_US |
| dc.subject | Space flight | en_US |
| dc.subject | Artificial potential fields | en_US |
| dc.subject | Collision avoidance maneuver | en_US |
| dc.subject | Docking operations | en_US |
| dc.subject | Euclidean distance | en_US |
| dc.subject | Orbit propagation | en_US |
| dc.subject | Planning and execution | en_US |
| dc.subject | Propulsion control | en_US |
| dc.subject | Time to collision | en_US |
| dc.subject | Spacecraft propulsion | en_US |
| dc.title | Optimized curvilinear potential field based multi-objective satellite collision avoidance maneuver | en_US |
| dc.type | Conference Paper | en_US |
| dcterms.isReferencedBy | Kim, Y., An, J., Robust navigational system for a transporter using GPS/INS fusion (2018), 65 (4), pp. 3346-3354. , No., pp; Akyildiz, I.F., Kak, A.J.C.N., The Internet of Space Things/CubeSats: A ubiquitous cyberphysical system for the connected world (2019) Vol., 150, pp. 134-149. , pp; Bengtson, M.T., Schaub, H., Remote Sensing of Spacecraft Potential at Geosynchronous Orbit using Secondary and Photo Electrons (2019) AIAA Scitech 2019 Forum, p. 0311. , p; Akari, K., Hoshi, K., (2019), pp. 1-11. , and Rockets. "Lorentz Force Effects on Orbit and Lifetime of Micrometer-Size Space Debris,", pp; Braun, V., Horstmann, A., Reihs, B., Lemmens, S., Merz, K., (2019) Exploiting Orbital Data and Observation Campaigns to Improve Space Debris Models, pp. 1-18. , pp; Maury, T., Loubet, P., Trisolini, M., Gallice, A., Sonnemann, G., Assessing the impact of space debris on orbital resource in life cycle assessment: A proposed method and case study (2019), 667, pp. 780-791. , pp; Bettinger, R., Hess, J., Lingenfelter, A.J., Tatman, L., Spacecraft Survivability in a Catastrophic Formation Mishap (2019) AIAA Scitech 2019 Forum, p. 0521. , p; Braun, V., Klinkrad, H., Stoll, E.J.A.A., Orbit information of predetermined accuracy and its sharing in the space situational awareness context (2019) Vol., 159, pp. 410-417. , pp; Wei, B., Nener, B.D.J.I.A., Multi-Sensor Space Debris Tracking for Space Situational Awareness With Labeled Random Finite Sets (2019) Vol., 7, pp. 36991-37003. , pp; Adilov, N., Alexander, P.J., Cunningham, B.M., An economic �Kessler Syndrome�: A dynamic model of earth orbit debris (2018) Economics Letters, 166, pp. 79-82. , Vol., pp; Cabrera, J.V., Nag, S., Murakami, D.D., (2019) An Initial Analysis of Automating Conjunction Assessment and Collision Avoidance Planning in Space Traffic Management; Kessler, D.J., Johnson, N.L., Liou, J., The kessler syndrome: Implications to future space operations (2010), 137 (8), p. 2010. , No., p; Dawson, L., (2018) Space Debris as a Weapon, pp. 46-60. , War in Space. Springer, pp; Wei, S., Jia, B., Chen, Z., Lu, J., Chen, G., Pham, K., Blasch, E., High performance enabled space object tracking via cloud computing 2018 IEEE Aerospace Conference. IEEE, 2018, pp. 1-9; Migliorini, L.F., Graser, E., Osborne, D., Unmaneuverable to Maneuverable�Developing Collision Avoidance Operations for a 17 Year Old Satellite, , 2018 SpaceOps Conference. 2018, p. 2679; Hamed, A.R., Badawy, A., Omer, A.A., Ashry, M., Hussein, W.M., "Multiple Debris Orbital Collision Avoidance (2019) 2019 IEEE Aerospace Conference. IEEE, pp. 1-8. , pp; Faber, W.R., (2018) Multiple Space Object Tracking Using a Randomized Hypothesis Generation Technique; Gremyachikh, L., Dubov, D., Kazeev, N., Kulibaba, A., Skuratov, A., Tereshkin, A., Ustyuzhanin, A., Shiryaeva, L., (2019) Space Navigator: A Tool for the Optimization of Collision Avoidance Maneuvers; Aida, S., Kirschner, M., Wermuth, M., Kiehling, R., Center, G.S.O., Collision avoidance operations for LEO satellites controlled by GSOC," Space Operations: Exploration, Scientific Utilization, and Technology (2010) Development, p. 71. , p; Ahmed Refaat, A.B., Ashry, M., Omar, A., High Accuracy Spacecraft Orbit Propagator Validation (2018) The 18Th International Conference (2018) on Applied Mechanics and Mechanical Engineering, , AMME-2018; Jung, O.-C., Seong, J., Ahn, S., Conjunction Assessment-Flow Automation Support Tool in KARI: From Design to Operations (2018) 2018 Spaceops Conference., p. 2373. , p; Bussy-Virat, C., Getchius, J., Ridley, A., The Spacecraft Orbital Characterization Kit and its Applications to the CYGNSS Mission (2018) 2018 Space Flight Mechanics Meeting., p. 1973. , p; Nga, N.G.-I.A., Earth Orientation Parameter Prediction (EOPP) Description; Chen, L., X, B., Liang, Y.G., Li, K.B., Close Approach Analysis Between Space Object (2017) Orbital Data Applications for Space Objects, , Springer," Springer, Singapore; Kannan, M.R., Manikantan, P., Kumar, D., Vasanth, S., Selvamani, S., Guruprasad, K., Jantikar, R., Shenoy, H., (2015) "COLLISION AVOIDANCE ASSESSMENT AND MITIGATION MEASURES FOR CONTROLLED GEO/GSO SPACECRAFTS WITH ORBITAL DEBRIS," 7Th European Conference on Space Debris, , ESA/ESOC, Darmstadt/Germany; Khatib, O., (1986) Real-Time Obstacle Avoidance for Manipulators and Mobile Robots, pp. 396-404. , Autonomous robot vehicles. Springer, pp; Badawy, A., McInnes, C.R., On-orbit assembly using superquadric potential fields (2008) Journal of Guidance, Control, and Dynamics, 31 (1), pp. 30-43. , Vol., No., pp; Badawy, A., McInnes, C.R., Small spacecraft formation using potential functions (2009) Acta Astronautica, 65 (11-12), pp. 1783-1788. , Vol., No., pp; Radice, G., Autonmous Slew Manoeuvring and Attitude Control Using the Potential Function Method Advances in the Astronautical Sciences, 116, pp. 1745-1765. , III, 2004, pp; Badawy, A., McInnes, C., (2006) Autonomous Structure Assembly Using Potential Field Functions, , AIAA 57th International Astronautical Congress; Rybus, T., Obstacle avoidance in space robotics: Review of major challenges and proposed solutions (2018) Progress in Aerospace Sciences; Cao, L., Qiao, D., Xu, J., Suboptimal artificial potential function sliding mode control for spacecraft rendezvous with obstacle avoidance (2018) Acta Astronautica, 143, pp. 133-146. , Vol., pp; Izzo, D., Pettazzi, L., Autonomous and distributed motion planning for satellite swarm (2007) Journal of Guidance, Control, and Dynamics, 30 (2), pp. 449-459. , Vol., No., pp; Lock, R.E., Bailey, Z.J., Kowalkowski, T.D., Nilsen, E.L., Mattingly, R.L., Mars Sample Return Orbiter Concepts Using Solar Electric Propulsion for the Post-Mars2020 Decade (2014) Aerospace Conference, 2014 IEEE. IEEE, pp. 1-10. , pp; Zhang, C., Fang, J., Li, B., Application of the Improved Artificial Potential Field Method in Obstacle Avoidance of Robot Destech Transactions on Computer Science and Engineering, (iceiti), p. 2017. , No; Bachmann, E.R., Hodgson, E., Hoffbauer, C., Messinger, J.J., (2019) I. T. O. V., and Graphics, C. "Multi User Redirected Walking and Resetting Using Artificial Potential Fields,", 25 (5), pp. 2022-2031. , Vol., No., pp; Wilhelm, J., Clem, G., Casbeer, D., Circumnavigation and obstacle avoidance guidance for UAVs using Gradient Vector Fields (2019) AIAA Scitech 2019 Forum, p. 1791. , p | |
| dcterms.source | Scopus |
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