Browsing by Author "Etminan, Aslan"
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Item Open Access Electromagnetic imaging of three-dimensional conducting objects using the Newton minimization approach(2013) Etminan, AslanThe main goal of shape reconstruction is to retrieve the location and shape of an unknown target. This approach is used in a wide range of areas, from detecting cancer tumors to finding buried objects. Various methods can be applied to detect objects in different applications. One of the important challenges in many of these methods is to solve the non-linearity and non-uniqueness of the solutions. Inverse scattering is one of the most efficient ways to retrieve shapes and locations of targets. By illuminating the objects with electromagnetic waves and collecting the scattering fields using appropriate methods, we try to obtain the shape of unknown object. To achieve this goal, we start with an initial guess of the unknown object, then by comparing the scattered far-field patterns of the guess and the real object, we evolve that object and update it iteratively such that we decrease the difference between the patterns and finally achieve the shape of the unknown object. In this thesis, we model the object by one of its parameters, such as the location of the nodes on the surface of the object, or by the conductivity, permittivity, and permeability of the discretized space in which the object is placed. Then, the model parameters are updated iteratively by minimizing the mismatch between the measured data of the target and the collected data from the modeled object. Using surface nodes to model a three-dimensional object is a good choice because we decrease the number of unknowns.Item Open Access Electromagnetic imaging of three-dimensional dielectric objects with Newton minimization(IEEE, 2014) Etminan, Aslan; Sadeghi, Alireza; Gürel, LeventWe present a general framework for detecting the shape and electrical properties of unknown objects by using the Newton minimization approach for solving inverse-scattering problems. This procedure is performed by evolving an initial-guess object iteratively until the cost function decreases to a desired value. Rapid convergence of this method is demonstrated by some numerical results.Item Open Access Shape reconstruction of three-dimensional conducting objects via near-field measurements(IEEE, 2014) Etminan, Aslan; Gürel, LeventA general framework for the shape reconstruction of conducting objects is presented with the Newton minimization approach. Using a fully numerical method, the initial-guess object is evolved to reconstruct the target. The object is modeled by triangles such that the vertices are the unknowns of the inverse-scattering problem. The cost function is minimized as the evolving object converges to the actual target in merely tens of iterations.