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dc.contributor.authorÇALIK, NURULLAH
dc.contributor.authorKoziel, Slawomir
dc.contributor.authorMAHOUTİ, Peyman
dc.contributor.authorBelen, Mehmet Ali
dc.contributor.authorSzczepanski, Stanislaw
dc.date.accessioned2021-12-10T10:51:00Z
dc.date.available2021-12-10T10:51:00Z
dc.identifier.citationKoziel S., MAHOUTİ P., ÇALIK N., Belen M. A. , Szczepanski S., "Improved Modeling of Microwave Structures Using Performance-Driven Fully-Connected Regression Surrogate", IEEE ACCESS, cilt.9, ss.71470-71481, 2021
dc.identifier.issn2169-3536
dc.identifier.otherav_58154744-c1fd-4bbf-bd6f-6a1f695347e7
dc.identifier.othervv_1032021
dc.identifier.urihttp://hdl.handle.net/20.500.12627/170707
dc.identifier.urihttps://doi.org/10.1109/access.2021.3078432
dc.description.abstractFast replacement models (or surrogates) have been widely applied in the recent years to accelerate simulation-driven design procedures in microwave engineering. The fundamental reason is a considerable-and often prohibitive-CPU cost of massive full-wave electromagnetic (EM) analyses related to solving common tasks such as parametric optimization or uncertainty quantification. The most popular class of surrogates are data-driven models, which are fast to evaluate, versatile, and easy to handle. Notwithstanding, the curse of dimensionality as well as the utility demands (e.g., so that the model covers sufficiently broad ranges of the system operating conditions), limit the applicability of conventional methods. A performance-driven modeling paradigm allows for mitigating these issue by focusing the surrogate setup process in a constrained domain encapsulating designs being of high quality w.r.t. the assumed figures of interest. The nested kriging framework capitalizing on this idea, renders the constrained surrogate using kriging interpolation, and has been shown to surpass traditional approaches. In pursuit of further accuracy improvements, this work incorporates the performance-driven concept into the fully-connected regression model (FRCM). The latter has been recently introduced in the context of frequency selective surfaces, and combined deep neural networks with Bayesian optimization, the latter employed to determine the network architecture and hyper-parameters. Using two examples of miniaturized microstrip couplers, our methodology is demonstrated to outperform both conventional modeling techniques and nested kriging, with reliable models constructed over multi-dimensional parameters spaces using just a few hundreds of samples.
dc.language.isoeng
dc.subjectSinyal İşleme
dc.subjectBilgisayar Bilimleri
dc.subjectBilgi Güvenliği ve Güvenilirliği
dc.subjectMühendislik ve Teknoloji
dc.subjectSignal Processing
dc.subjectGeneral Engineering
dc.subjectGeneral Computer Science
dc.subjectEngineering (miscellaneous)
dc.subjectElectrical and Electronic Engineering
dc.subjectComputer Science (miscellaneous)
dc.subjectComputer Networks and Communications
dc.subjectComputer Science Applications
dc.subjectInformation Systems
dc.subjectTELEKOMÜNİKASYON
dc.subjectPhysical Sciences
dc.subjectBilgi Sistemleri, Haberleşme ve Kontrol Mühendisliği
dc.subjectMühendislik
dc.subjectMÜHENDİSLİK, ELEKTRİK VE ELEKTRONİK
dc.subjectMühendislik, Bilişim ve Teknoloji (ENG)
dc.subjectBilgisayar Bilimi
dc.subjectBİLGİSAYAR BİLİMİ, BİLGİ SİSTEMLERİ
dc.titleImproved Modeling of Microwave Structures Using Performance-Driven Fully-Connected Regression Surrogate
dc.typeMakale
dc.relation.journalIEEE ACCESS
dc.contributor.departmentReykjavík University , ,
dc.identifier.volume9
dc.identifier.startpage71470
dc.identifier.endpage71481
dc.contributor.firstauthorID2637917


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