A component modes projection and assembly model reduction methodology for articulated, multi-flexible body structures
Author(s) -
Allan Y. Lee,
Walter S. Tsuha
Publication year - 1992
Publication title -
guidance, navigation and control conference
Language(s) - English
Resource type - Conference proceedings
DOI - 10.2514/6.1992-4323
Subject(s) - component (thermodynamics) , projection (relational algebra) , model order reduction , reduction (mathematics) , mode (computer interface) , computer science , control theory (sociology) , algorithm , mathematics , artificial intelligence , control (management) , physics , thermodynamics , operating system , geometry
A two-stage model reduction methodology, combining the classical Component Mode Synthesis (CMS) method and the newly developed Enhanced Projection and Assembly (EP&A) method, is proposed in this research. The first stage of this methodology, called the COmponent Modes Projection and Assembly model REduction (COMPARE) method, involves the generation of CMS mode sets, such as the MacNeal-Rubin mode sets. These mode sets are then used to reduce the order of each component model in the Rayleigh-Ritz sense. The resultant component models are then combined to generate reduced-order system models at various system configurations. A composite mode set which retains important system modes at all system configurations is then selected from these reduced-order system models. In the second stage, the EP&A model reduction method is employed to reduce further the order of the system model generated in the first stage. The effectiveness of the COMPARE methodology has been successfully demonstrated on a high-order, finite-element model of the cruise-configured Galileo spacecraft.
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