FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2083273258> ?p ?o ?g. }

• W2083273258 endingPage "1392" @default.
• W2083273258 startingPage "1377" @default.
• W2083273258 abstract "*† In spite of the CFD revolution, significant challenges still face aerodynamicists in predicting and controlling various classes of flows. These include three-dimensional separation, boundary layer transition, interaction of separation and transition such as on reentry capsules, multi-element airfoils and wings, UAV low Reynolds number flows and high angle of attack applications. Others include multi-body flows such as those occurring in store and stage separation, “stiff” combustion reacting and unsteady flows as well as plasma aerodynamics and turbulence, to name a few. In many cases, diverse multiple scales are involved and the proper identification and treatment of associated disparate length and time scales is critical in obtaining accurate prediction and effective control. The solution of such multi-scale problems can be a hurdle to effective domain decomposition, even overset, unstructured adaptive gridding and ultimately, solution accuracy. Theoretical insights can help make proper decisions on numerical pre-processing, solution, post-processing and interpretation. Opportunities for a combined theoretical, computational and experimental approach will be discussed. These will be illustrated by examples from the author’s experience. As compared to the limited “pen and paper” theoretical methods of the 50’s, illustrations will be given of the effectiveness of combined asymptotics, similitude, group invariance, approximate physics-based modeling and numerical methods for conceptual vehicle design, flow control innovation, identification of key parameters, leveraging of computational solutions, reducing the parameter space as well as providing added insight into the basic physical processes. These will be related to tradeoffs between accuracy and response speed in typical aerospace environments." @default.
• W2083273258 created "2016-06-24" @default.
• W2083273258 creator A5024998345 @default.
• W2083273258 date "2006-07-01" @default.
• W2083273258 modified "2023-10-14" @default.
• W2083273258 title "Theoretical Aerodynamics in Today's Real World: Opportunities and Challenges" @default.
• W2083273258 cites W1524253852 @default.
• W2083273258 cites W185458522 @default.
• W2083273258 cites W1967705692 @default.
• W2083273258 cites W1971250360 @default.
• W2083273258 cites W1986965868 @default.
• W2083273258 cites W2010233430 @default.
• W2083273258 cites W2010330282 @default.
• W2083273258 cites W2012919712 @default.
• W2083273258 cites W2013897455 @default.
• W2083273258 cites W2016522892 @default.
• W2083273258 cites W2024242501 @default.
• W2083273258 cites W2027087330 @default.
• W2083273258 cites W2034760462 @default.
• W2083273258 cites W2047055819 @default.
• W2083273258 cites W2060056372 @default.
• W2083273258 cites W2063934044 @default.
• W2083273258 cites W2064477840 @default.
• W2083273258 cites W2077865030 @default.
• W2083273258 cites W2088602464 @default.
• W2083273258 cites W2095289047 @default.
• W2083273258 cites W2098385452 @default.
• W2083273258 cites W2104801764 @default.
• W2083273258 cites W2166800266 @default.
• W2083273258 cites W2168928276 @default.
• W2083273258 cites W2170294434 @default.
• W2083273258 cites W2315457440 @default.
• W2083273258 cites W2317772640 @default.
• W2083273258 cites W2321038736 @default.
• W2083273258 cites W2323954866 @default.
• W2083273258 cites W2325369565 @default.
• W2083273258 cites W2325435103 @default.
• W2083273258 cites W2327017885 @default.
• W2083273258 cites W2329085096 @default.
• W2083273258 cites W2331705863 @default.
• W2083273258 cites W4292360406 @default.
• W2083273258 cites W561340459 @default.
• W2083273258 cites W2044415874 @default.
• W2083273258 doi "https://doi.org/10.2514/1.18234" @default.
• W2083273258 hasPublicationYear "2006" @default.
• W2083273258 type Work @default.
• W2083273258 sameAs 2083273258 @default.
• W2083273258 citedByCount "11" @default.
• W2083273258 countsByYear W20832732582015 @default.
• W2083273258 countsByYear W20832732582018 @default.
• W2083273258 countsByYear W20832732582020 @default.
• W2083273258 crossrefType "journal-article" @default.
• W2083273258 hasAuthorship W2083273258A5024998345 @default.
• W2083273258 hasConcept C127413603 @default.
• W2083273258 hasConcept C13393347 @default.
• W2083273258 hasConcept C146978453 @default.
• W2083273258 hasConcept C178802073 @default.
• W2083273258 hasConcept C41008148 @default.
• W2083273258 hasConceptScore W2083273258C127413603 @default.
• W2083273258 hasConceptScore W2083273258C13393347 @default.
• W2083273258 hasConceptScore W2083273258C146978453 @default.
• W2083273258 hasConceptScore W2083273258C178802073 @default.
• W2083273258 hasConceptScore W2083273258C41008148 @default.
• W2083273258 hasIssue "7" @default.
• W2083273258 hasLocation W20832732581 @default.
• W2083273258 hasOpenAccess W2083273258 @default.
• W2083273258 hasPrimaryLocation W20832732581 @default.
• W2083273258 hasRelatedWork W1194358980 @default.
• W2083273258 hasRelatedWork W1524161552 @default.
• W2083273258 hasRelatedWork W1980176220 @default.
• W2083273258 hasRelatedWork W2021197601 @default.
• W2083273258 hasRelatedWork W2042197179 @default.
• W2083273258 hasRelatedWork W2080947273 @default.
• W2083273258 hasRelatedWork W2334763476 @default.
• W2083273258 hasRelatedWork W2899084033 @default.
• W2083273258 hasRelatedWork W4232669342 @default.
• W2083273258 hasRelatedWork W803780654 @default.
• W2083273258 hasVolume "44" @default.
• W2083273258 isParatext "false" @default.
• W2083273258 isRetracted "false" @default.
• W2083273258 magId "2083273258" @default.
• W2083273258 workType "article" @default.