Development and validation of a predictive model for the diagnosis of solid solitary pulmonary nodules using data mining methods

Abstract-In this paper, circular and hexagonal array geometries for smart antenna applications are compared. Uniform circular (UCA) and hexagonal arrays (UHA) with 18 half-wave dipole elements are examined; also planar (2 concentric rings of radiators) uniform circular (PUCA) and hexagonal arrays (PUHA) are considered. The effect of rotating the outer ring of the PUCA is studied. In our analysis, the method of moments is used to compute the response of the uniform circular and hexagonal dipole arrays in a mutual coupling environment. The particle swarm optimization (PSO) algorithm is used to optimize the complex excitations, amplitudes and phases, of the adaptive arrays elements for beamforming.

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Analysis of uniform circular arrays for adaptive beamforming applications using particle swarm optimization algorithm

Mahmoud

Eladawy

Bansal

et al. 2007

Int J RF and Microwave Comp Aid Eng

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In this article, the particle swarm optimization algorithm is used to calculate the complex excitations, amplitudes and phases, of the adaptive circular array elements. To illustrate the performance of this method for steering a signal in the desired direction and imposing nulls in the direction of interfering signals by controlling the complex excitation of each array element, two types of arrays are considered. A uniform circular array (UCA) and a planar uniform circular array (PUCA) with 16 elements of half-wave dipoles are examined. Also, the performance of an adaptive array using 3-bit amplitude and 4-bit phase shifters are studied. In our analysis, the method of moments is used to estimate the response of the dipole UCAs in a mutual coupling environment.

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Microstrip Antenna With Defected Ground Plane Structure as a Sensor for Landmines Detection

Zainud-Deen¹,

Badr²,

El-Deen³

et al. 2008

PIER B

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Abstract-A proposed sensor for landmines detection consists of two parallel microstrip antennas placed on the same ground plane and with defected ground structure between them has been investigated. The microstrip patch array with defected ground structure has the advantage of a low mutual coupling compared with the classic one. The Finite-Difference Time-Domain (FDTD) is used to simulate the sensor for landmines detection.

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A Single-Feed Cylindrical Superquadric Dielectric Resonator Antenna for Circular Polarization

Zainud-Deen¹,

Malhat²,

Awadalla³

2008

PIER

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Scattering from bodies coated with metamaterial using FDFD method

Zainud-Deen

Botros

Ibrahim

2008

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Abstract-The electromagnetic scattering from a conducting object coated with metamaterials, which have both negative permittivity and permeability is derived rigorously by using finite difference frequency domain (FDFD). A formulation for the FDFD method is presented. The scattering from circular and multilayers elliptic cylinder coated by metamaterial are investigated. Also, the scattering from dielectric and metamaterial sphere is depicted. Numerical results are compared with the available data in the literature.

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Electromagnetic Scattering Using Gpu-Based Finite Difference Frequency Domain Method

Zainud-Deen¹,

Hassan²,

Ibrahim³

et al. 2009

PIER B

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Abstract-This paper presents a graphics processing based implementation of the Finite-Difference Frequency-Domain (FDFD) method, which uses a central finite differencing scheme for solving Maxwell's equations for electromagnetics. The radar cross section for different structures in 2D and 3D has been calculated using the FDFD method. The FDFD code has been implemented for the CPU calculations and the same code is implemented for the GPU calculations using the Brook+ developed by AMD. The solution obtained by using the GPU based-code showed more than 40 times speed over the CPU code.Corresponding author: E. El-Deen (emadtork@yahoo.com). 352Zainud-Deen et al.

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Frequency tunable graphene metamaterial reflectarray for terahertz applications

Zainud-Deen

Mabrouk

Malhat

2018

J. eng.

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Circular Polarization Bandwidth Reconfigurable High Gain Planar Plasma Helical Antenna

Zainud-Deen

Malhat

El-Shalaby

et al. 2019

IEEE Trans. Plasma Sci.

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S.H. Zainud-Deen

A Comparison Between Circular and Hexagonal Array Geometries for Smart Antenna Systems Using Particle Swarm Optimization Algorithm

Analysis of uniform circular arrays for adaptive beamforming applications using particle swarm optimization algorithm

Microstrip Antenna With Defected Ground Plane Structure as a Sensor for Landmines Detection

A Single-Feed Cylindrical Superquadric Dielectric Resonator Antenna for Circular Polarization

Scattering from bodies coated with metamaterial using FDFD method

Electromagnetic Scattering Using Gpu-Based Finite Difference Frequency Domain Method

Frequency tunable graphene metamaterial reflectarray for terahertz applications

Circular Polarization Bandwidth Reconfigurable High Gain Planar Plasma Helical Antenna

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