淡江大學機構典藏:Item 987654321/74722
English  |  正體中文  |  简体中文  |  Items with full text/Total items : 62830/95882 (66%)
Visitors : 4046063      Online Users : 982
RC Version 7.0 © Powered By DSPACE, MIT. Enhanced by NTU Library & TKU Library IR team.
Scope Tips:
  • please add "double quotation mark" for query phrases to get precise results
  • please goto advance search for comprehansive author search
    •  Adv. Search
    HomeLoginUploadHelpAboutAdminister Goto mobile version


    Please use this identifier to cite or link to this item: https://tkuir.lib.tku.edu.tw/dspace/handle/987654321/74722


    Title: 部分掩埋導體之逆散射問題研究
    Other Titles: Imaging reconstruction for a partial embedded conductor
    Authors: 蕭為均;Hsiao, Wei-Chun
    Contributors: 淡江大學電機工程學系碩士班
    丘建青;Chiu, Chien-Ching
    Keywords: 部分掩埋導體;動態差異演算法;粒子群聚法;particle swarm optimization;Dynamic Differential Evolution;Partial Embedded Conductor;Moment Method;Imaging Reconstruction
    Date: 2011
    Issue Date: 2011-12-28 19:23:22 (UTC+8)
    Abstract: 本論文是在研究粒子群聚法(Particle Swarm Optimization)及動態
    差異演算法(Dynamic Differential Evolution)應用在二維物體之電磁成像問題。我們針對在TE (Transverse Electric)及TM (TransverseMagnetic) 極化波入射的情況下且分別於近場及遠場下於半空間中完全導體的逆散射進行探討。
    對於完全導體而言,電磁波在完全導體表面之總電場的切線分量為零。因此我們利用完全導體表面電流的觀念,可導出非線性積分方
    程式,繼而利用動差法求得正散射公式。利用正散射公式,我們可以得到散射場的相關資料。對於逆散射部分,我們引進了粒子群聚法及動態差異演算法。利用兩種演算法時,我們適當地選取參數形式,同時結合所求的散射公式,由此即可求出散射場的相關資料,藉以求得柱體的形狀函數。
    不論初始的猜測值如何,粒子群聚法及動態差異演算法總會收歛到整體的極值(Global Extreme),因此,在數值模擬顯示中,即使最初的猜測值與實際值相距甚遠,我們仍可求得準確的數值解,成功的重建出物體形狀函數。而且在數值模擬顯示中,量測的散射場即使加入高斯分佈的雜訊存在,依然可以得到良好的重建結果,研究證實其有良好的抗雜訊能力。
    所以我選擇粒子群聚法及動態差異演算法,利用散射體形狀越
    相近則其散射場越相近的關係,來重建未知的形狀。
    The application of two techniques for the of shape reconstruction of a perfectly two-dimensional partial embedded conducting cylinder from mimic the measurement data is studied in the present paper. After an integral formulation, the microwave imaging is recast as a nonlinear
    optimization problem; an objective function is defined by the norm of a difference between the measured scattered electric fields and the calculated scattered fields for an estimated shape of a conductor. In order to solve this inverse scattering problem, transverse electric (TE) and
    transverse magnetic (TM) waves are incident upon the objects and two techniques are employed to solve these problems. The first is based on a particle swarm optimization (PSO) and the second is a dynamic differential evolution (DDE). Both techniques have been tested in the case of simulated data contaminated by additive white Gaussian noise. Numerical results indicate that the DDE algorithm and the PSO have almost the same reconstructed accuracy. However, the accuracy of TM wave is better than TE wave in conducting cylinder cases and near-field is better than far-field.
    Appears in Collections:[Graduate Institute & Department of Electrical Engineering] Thesis

    Files in This Item:

    File SizeFormat
    index.html0KbHTML196View/Open

    All items in 機構典藏 are protected by copyright, with all rights reserved.

    DSpace Software Copyright © 2002-2004  MIT &  Hewlett-Packard  /   Enhanced by   NTU Library & TKU Library IR teams. Copyright ©   - Feedback