Optimization and synthesis of multilayer frequency selective surfaces via bioinspired hybrid techniques

Wirlan Gomes  Lima; Jasmine  Priscyla Leite  Leite de Araújo; Fabrício José Brito  Barros; Gervásio Protásio  Dos Santos Cavalcante; Cássio da Cruz  Nogueira; Bruno Souza  Lyra Castro; Miércio Cardoso  De Alcântara Neto

doi:10.31686/ijier.vol8.iss5.2371

Authors

Wirlan Gomes Lima Federal University of Pará
Jasmine Priscyla Leite Leite de Araújo Federal University of Pará
Fabrício José Brito Barros Federal University of Pará
Gervásio Protásio Dos Santos Cavalcante Federal University of Pará
Cássio da Cruz Nogueira Federal University of Pará
Bruno Souza Lyra Castro Federal University of Pará
Miércio Cardoso De Alcântara Neto Federal University of Pará

DOI:

https://doi.org/10.31686/ijier.vol8.iss5.2371

Keywords:

hybrid optimization methods, FSS, GRNN, MOGA, MOCS

Abstract

In this study, two bioinspired computation (BIC) techniques are discussed and applied to the project and synthesis of multilayer frequency selective surfaces (FSS) within the microwave band, specifically for C, X and Ku bands. The proposed BIC techniques consist of combining an artificial, general regression neural network to a genetic algorithm (GA) and a cuckoo search algorithm, respectively. The objective is to find the optimal values of separation between the investigated FSS. Numerical analysis of the electromagnetic properties of the device is made possible with the finite integration method (FIT) and validated through the finite element method (FEM), utilizing both softwares CST Microwave Studio and Ansys HFSS respectively. Thus, the BIC-optimized devices present good phase / angular stability for angles 10°, 20°, 30° and 40°, as well as being polarization independent. The cutoff frequencies to control the operating frequency range of the FSS, referring to transmission coefficient in decibels (dB), were obtained at a threshold of –10dB. Numerical results denote good accordance with measured data.

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Author Biographies

Wirlan Gomes Lima, Federal University of Pará

Telecommunication and Computation Laboratory
Jasmine Priscyla Leite Leite de Araújo, Federal University of Pará

Telecommunication and Computation Laboratory
Fabrício José Brito Barros, Federal University of Pará

Telecommunication and Computation Laboratory
Gervásio Protásio Dos Santos Cavalcante, Federal University of Pará

Telecommunication and Computation Laboratory
Cássio da Cruz Nogueira, Federal University of Pará

Telecommunication and Computation Laboratory
Bruno Souza Lyra Castro, Federal University of Pará

Telecommunication and Computation Laboratory
Miércio Cardoso De Alcântara Neto, Federal University of Pará

Telecommunication and Computation Laboratory

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