MeasurementAlgorithmBasedonMotorAlgebraforRelativePositionandAttitudeDeterminationofRVDSpacecraft

doi:10.3780/j.issn.1000-758X.2015.0４.011

Abstract

Abstract: Accuratemeasurementoftherelativepositionandattitudebetweentheactivespacecraftandthetargetspacecraftisthekeytothesuccessfulcompletionofrendezvousanddocking(RVD)mission.Inthetraditionalvectormeasurementmethods,thepositionandattitudeareusuallytreatedseparately,whichledtothedifficultyofalgorithmdesignandcomputationalcomplexity. AnewbinocularvisionmeasurementalgorithmbasedonmotoralgebrawasproposedtouniformlydescribetherelativepositionandtheattitudeofthetwoRVDspacecraft.Thisnewalgorithmhasamoreconciseformandsomecomputationaladvantagescomparedtothetraditionalmethods.Therelativepositionandattitudedeterminationproblemwassimplifiedtosolvingtwolinearequations.SimulationresultsshowthatthealgorithmcanmeetthemeasurementaccuracyrequirementsofRVDmissions.

Key words: Motoralgebra, Rendezvousanddocking, Relativepositionandattitude, Binocularvision, Spacecraft

CHEN Wei, CHEN Zhi-Ming, WANG Hui-南. MeasurementAlgorithmBasedonMotorAlgebraforRelativePositionandAttitudeDeterminationofRVDSpacecraft[J]. , doi: 10.3780/j.issn.1000-758X.2015.0４.011.

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URL: http://journal26.magtechjournal.com/kjkxjs/EN/10.3780/j.issn.1000-758X.2015.0４.011

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MeasurementAlgorithmBasedonMotorAlgebraforRelativePositionandAttitudeDeterminationofRVDSpacecraft

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