Onur Bakir scite author profile

Onur Bakir

5Publications

24Citation Statements Received

140Citation Statements Given

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140

Affiliations

Usak University, Bilkent University, University of Michigan–Ann Arbor

Publications

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Scan Blindness Phenomenon in Conformal Finite Phased Arrays of Printed Dipoles

Ertürk

Bakir

Rojas

et al. 2006

IEEE Trans. Antennas Propagat.

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Abstract-Scan blindness phenomenon for finite phased arrays of printed dipoles on material coated, electrically large circular cylinders is investigated. Effects on the scan blindness mechanism of several array and supporting structure parameters, including curvature effects, are observed and discussed. A full-wave solution, based on a hybrid method of moments/Green's function technique in the spatial domain, is used to achieve the aforementioned goals. Numerical results show that the curvature affects the surface waves and hence the mutual coupling between array elements. As a result, the array current distribution of arrays mounted on coated cylinders are considerably different compared to similar arrays on planar platforms. Therefore, finite phased arrays of printed dipoles on coated cylinders show different behavior in terms of scan blindness phenomenon compared to their planar counterparts. Furthermore, this phenomenon is completely different for axially and circumferentially oriented printed dipoles on coated cylinders suggesting that particular element types might be important for cylindrical arrays.

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Adaptive integral method with fast Gaussian gridding for solving combined field integral equations

Bakir

Bağcı

Michielssen

2009

Waves in Random and Complex Media

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Adaptive integral method with fast Gaussian gridding

Bakir

Bağcı

Michielssen

2008

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Efficient Analysis of Phased Arrays of Microstrip Patches Using a Hybrid Generalized Forward Backward Method/Green's Function Technique With a DFT Based Acceleration Algorithm

Bakir

Çivi²,

Ertürk³

et al. 2008

IEEE Trans. Antennas Propagat.

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A hybrid method based on the combination of generalized forward backward method (GFBM) and Green's function for the grounded dielectric slab together with the acceleration of the combination via a discrete Fourier transform (DFT) based algorithm is developed for the efficient and accurate analysis of electromagnetic radiation/scattering from electrically large, irregularly contoured two-dimensional arrays consisting of finite number of probe-fed microstrip patches. In this method, unknown current coefficients corresponding to a single patch are first solved by a conventional Galerkin type hybrid method of moments (MoM)/Green's function technique that uses the grounded dielectric slab's Green's function. Because the current distribution on the microstrip patch can be expanded using an arbitrary number of subsectional basis functions, the patch can have any shape. The solution for the array currents is then found through GFBM, where it sweeps the current computation element by element. The computational complexity of this method, which is originally 2 tot (tot being the total number of unknowns) for each iteration, is reduced to (tot) using a DFT based acceleration algorithm making use of the fact that array elements are identical and the array is periodic. Numerical results in the form of array current distribution are given for various sized arrays of probe-fed microstrip patches with elliptical and/or circular boundaries, and are compared with the conventional MoM results to illustrate the efficiency and accuracy of the method. Index Terms-Discrete Fourier transform (DFT), finite arrays, generalized forward backward method (GFBM), method of moments (MoM). I. INTRODUCTION M AJORITY of commercial and military applications require phased arrays fabricated using the integrated circuit technology. However, a great portion of available design

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Investigation of planar and conformal printed arrays for MIMO performance analysis

Tunc

Ircı

Bakir

et al. 2006

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MIMO channel capacity of printed arrays with dipole elements is analyzed. A MIMO channel model based on electric fields is used. The effects of mutual interactions among the array elements through space and surface waves are included into the channel matrix using a fullwave hybrid Method of Moments (MoM)/Green's function technique in the spatial domain. MIMO capacity of printed arrays is then compared with that of free standing thin wire dipole arrays. Results show better performance of printed arrays.

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Onur Bakir

Scan Blindness Phenomenon in Conformal Finite Phased Arrays of Printed Dipoles

Adaptive integral method with fast Gaussian gridding for solving combined field integral equations

Adaptive integral method with fast Gaussian gridding

Efficient Analysis of Phased Arrays of Microstrip Patches Using a Hybrid Generalized Forward Backward Method/Green's Function Technique With a DFT Based Acceleration Algorithm

Investigation of planar and conformal printed arrays for MIMO performance analysis

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