Design and optimization techniques for the current return path in a composite aircraft

The emergence of new composite materials in the aeronautical domain requires a paradigm shift in the electrical system design, especially concerning the current return path. The composite fuselage cannot comply with the required functionalities, as the aluminium skin does, due to its heating and conductive natural limitations. The aim of this paper is to propose some solutions for the design and the optimisation of the current return path in this new aeronautical environment, using a complex modelling method (PEEC-AMLFMM) coupled with, firstly, a path finding algorithm followed by an optimization process, secondly, with a global routing tool followed by an optimisation process and, thirdly, with a multi-agent system approach. A comparison between these methods is made. The first results obtained using our methodologies are promising, providing some solutions for the current return path in a composite aircraft.

[1]  Mary Jane Irwin,et al.  An edge-based heuristic for Steiner routing , 1994, IEEE Trans. Comput. Aided Des. Integr. Circuits Syst..

[2]  Rolf Pfeifer,et al.  Understanding intelligence , 2020, Inequality by Design.

[3]  J. Perhac,et al.  Using path-finding algorithms of graph theory for route-searching in geographical information systems , 2008, 2008 6th International Symposium on Intelligent Systems and Informatics.

[4]  Jean-Michel Guichon,et al.  Towards the conception and optimisation of the current return path in a composite aircraft , 2010, 2010 IEEE International Systems Conference.

[5]  V. Rokhlin,et al.  Rapid Evaluation of Potential Fields in Three Dimensions , 1988 .

[6]  C. Hoer,et al.  Exact inductance equations for rectangular conductors with applications to more complicated geometries , 1965 .

[7]  B. McLaughlin Emergence and Supervenience , 1997 .

[8]  Alex Zelikovsky,et al.  Minimum Steiner Tree Construction , 2008, Handbook of Algorithms for Physical Design Automation.