As part of H2020 EU project "AGILE", A Collaborative System of Systems Multidisciplinary Design Optimization research approach is presented in this paper. This approach relies on physics-based analysis to evaluate the correlations between the airframe design, as well as propulsion, aircraft systems, aerodynamics, structures and emission, from the early design process, and to exploit the synergies within a simultaneous optimization process. Further, the disciplinary analysis modules from multiple organizations, involved in the optimization are integrated within a distributed framework. The disciplinary analysis tools are not shared, but only the data are distributed among partners through a secured network of framework. In order to enable an...
The AGILE project has developed the next generation of aircraft Multidisciplinary Design and Optimiz...
In this paper methodological investigations regarding an innovative Multidisciplinary Design and Opt...
A Collaborative Multidisciplinary Design Optimization (MDO) methodology is presented, which uses phy...
As part of H2020 EU project “AGILE”, A Collaborative System of Systems Multidisciplinary Design Opt...
The research and innovation EU funded AGILE project has developed the next generation of aircraft Mu...
The research and innovation AGILE project developed the next generation of aircraft Multidisciplinar...
This paper presents methodological investigations performed in research activities in the field of M...
The EU funded AGILE project is developing the next generation of aircraft Multidisciplinary Design a...
This paper presents methodological investigations performed in research activities in the field of M...
AGILE Project is a 3rd generation Aircraft Design Optimization project involving heterogeneous teams...
The present paper deals with the design, analysis and optimization of a 90 passengers turboprop airc...
AGILE targets multidisciplinary optimization using distributed analysis frameworks. The involvement ...
Novel configuration design choices may help achieve revolutionary goals for reducing fuel burn, emis...
The AGILE project has developed the next generation of aircraft Multidisciplinary Design and Optimiz...
In this paper methodological investigations regarding an innovative Multidisciplinary Design and Opt...
A Collaborative Multidisciplinary Design Optimization (MDO) methodology is presented, which uses phy...
As part of H2020 EU project “AGILE”, A Collaborative System of Systems Multidisciplinary Design Opt...
The research and innovation EU funded AGILE project has developed the next generation of aircraft Mu...
The research and innovation AGILE project developed the next generation of aircraft Multidisciplinar...
This paper presents methodological investigations performed in research activities in the field of M...
The EU funded AGILE project is developing the next generation of aircraft Multidisciplinary Design a...
This paper presents methodological investigations performed in research activities in the field of M...
AGILE Project is a 3rd generation Aircraft Design Optimization project involving heterogeneous teams...
The present paper deals with the design, analysis and optimization of a 90 passengers turboprop airc...
AGILE targets multidisciplinary optimization using distributed analysis frameworks. The involvement ...
Novel configuration design choices may help achieve revolutionary goals for reducing fuel burn, emis...
The AGILE project has developed the next generation of aircraft Multidisciplinary Design and Optimiz...
In this paper methodological investigations regarding an innovative Multidisciplinary Design and Opt...
A Collaborative Multidisciplinary Design Optimization (MDO) methodology is presented, which uses phy...