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Manipulation of the electromagnetic near‐fields by 3D printed coils: from design to fabrication
Author(s) -
Mohtadi Jafari Ali,
Abdolali Ali
Publication year - 2018
Publication title -
iet microwaves, antennas and propagation
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.555
H-Index - 69
eISSN - 1751-8733
pISSN - 1751-8725
DOI - 10.1049/iet-map.2017.0961
Subject(s) - electromagnetic coil , electrical conductor , magnetic field , electric field , 3d printing , fabrication , basis function , basis (linear algebra) , electromagnetic field , path (computing) , field (mathematics) , current (fluid) , voltage , fused deposition modeling , mechanical engineering , electronic engineering , computer science , electrical engineering , acoustics , engineering , physics , mathematics , geometry , medicine , alternative medicine , pathology , quantum mechanics , pure mathematics , programming language
Nowadays, the advancements in three‐dimensional (3D) printing technology have made it possible for sophisticated structures to be fabricated fast, accurate, and affordable. In this study, a new method is proposed for the manipulation of near‐electric and magnetic fields based on 3D coils. The manipulation of near‐fields is widely used in various electromagnetic problems. The 3D coils lead to 3D distributions of current paths. By changing the shape of the coil (i.e. the current path) the desired electric field or magnetic field can be achieved. During the design procedure, at first dyadic Green's functions are used to calculate the electric and magnetic fields. Also, proper basis functions are used to define the current paths. Following that, with the help of genetic algorithm, the coefficients of the basis functions, and thus the shape of 3D coils are derived for the realisation of the desired field. Finally, this method is used to realise a normal distribution on a curved path. The coils are fabricated with fused deposition modeling (FDM) 3D printing technology and by attaching the conductive wires to the printed structure. The results of design, numerical simulations, and experimental tests indicate the high performance of this technique for manipulation of near‐electric and magnetic fields.

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