Andere Kunden interessierten sich auch für
![BATMAV: a Bio-inspired Micro-Air Vehicle for Flapping Flight]( "BATMAV: a Bio-inspired Micro-Air Vehicle for Flapping Flight")
BATMAV: a Bio-inspired Micro-Air Vehicle for Flapping Flight42,99 €![Unruly Passenger: The critical issue in commercial aviation]( "Unruly Passenger: The critical issue in commercial aviation")
Unruly Passenger: The critical issue in commercial aviation40,99 €![A Battery Powered Transport Aircraft]( "A Battery Powered Transport Aircraft")
A Battery Powered Transport Aircraft38,99 €![Biofiltration of Waste Gases in Africa and the Caribbean]( "Biofiltration of Waste Gases in Africa and the Caribbean")
Biofiltration of Waste Gases in Africa and the Caribbean37,99 €![Network Focused Integration of Geospatial Data in Avionics]( "Network Focused Integration of Geospatial Data in Avionics")
Network Focused Integration of Geospatial Data in Avionics16,99 €![Ion Propulsion Missions]( "Ion Propulsion Missions")
Ion Propulsion Missions35,99 €![Numerical study of icing of horizontal axis wind turbine blade]( "Numerical study of icing of horizontal axis wind turbine blade")
Numerical study of icing of horizontal axis wind turbine blade40,99 €
Revision with unchanged content. Sonic boom annoyance is an important technical showstopper for commercial supersonic aircraft operations. Choosing the right aircraft shape reflecting the design requirements is a crucial step that is usually simplified in the early stages of design by resorting to a qualitative selection of a baseline configuration based on historical designs and designer's bias. The shortcomings of traditional tools are overcome in this study. A diverse mix of tools is integrated to provide a simple, yet powerful procedure for sonic boom minimization. A shape optimization procedure for supersonic aircraft design using better geometry generation and improved tools is demonstrated. Varying atmospheric conditions could have a huge impact on the sonic boom annoyance metrics and a quick way of obtaining probability estimates of relevant metrics is demonstrated. Theoretical sonic boom minimization equations are generalized; relevant equations are derived to yield increased flexibility in aircraft design process. The unique shape optimization procedure in conjunction with parallel genetic algorithms improves the computational time of the analysis and allows quick exploration of the vast design space.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.