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研究生: 許書豪
Hsu, Shu-Hao
論文名稱: 以餘弦轉換相位展開硬體電路為基礎的自動對焦3D數位全像重建系統之研究
Autofocusing System for 3D Digital Holography Reconstruction Using DCT-Based Phase Unwrapping Architecture
指導教授: 黃文吉
Hwang, Wen-Jyi
學位類別: 碩士
Master
系所名稱: 資訊工程學系
Department of Computer Science and Information Engineering
論文出版年: 2016
畢業學年度: 104
語文別: 中文
論文頁數: 60
中文關鍵詞: FPGA自動對焦全像重建餘弦轉換
英文關鍵詞: FPGA, Autofocusing, Hologram reconstruction, Discrete cosine transform
DOI URL: https://doi.org/10.6345/NTNU202204427
論文種類: 學術論文
相關次數: 點閱:129下載:8
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  • 本論文旨在於FPGA ( Field Programmable Gate Array ) 平台設計實現可自動對焦3D數位全像重建系統之硬體。
    本論文之基礎建立於全像術的使用,記錄觀測樣本之相位與振幅資料,並利用本系統進行3D重建。在全像圖顯微鏡等…的應用中,可能於觀測過程中更換樣本,且需手動調整正確焦距並重建清晰影像,較耗費人力成本及時間,因而突顯出本系統自動對焦之重要性。
    本系統之全像重建流程主要使用菲涅耳轉換( Fresnel Transform )進行不連續相位重建,並使用DCT-based最小均方演算法( DCT-based minimum mean square algorithm )進行相位展開、還原物體之真實連續相位,再根據重建之影像進行數值評估( Normalized Variance ),以最高清晰度作為重建之焦距依據並進行正確焦距之重建。此外,本論文也使用諸多I/O技術,降低調整焦距時重複使用原始影像傳送的時間,提升本系統還原更大尺寸全像圖之能力,進而增加系統效能。
    本論文之實驗數據與效能分析顯示本系統還原大尺寸全像圖之能力與正確性。採用以餘弦轉換為基礎的相位展開法則提供更具競爭力的還原時間。
    透過本系統於FPGA上與運行於個人電腦之MATLAB軟體還原程式做兩者間之比較,可得知本系統於FPGA上之還原時間遠低於MATLAB軟體還原時間;另一方面,本系統之功率消耗運行於FPGA也遠低於軟體運作於CPU上。

    關鍵字:FPGA、自動對焦、全像重建、餘弦轉換

    This research aims to implement the design of “Autofocusing System for 3D Digital Holography Reconstruction” on FPGA ( Field Programmable Gate Array ).
    With the use of Holography to record the phase and amplitude of the samples, the system can execute the 3D reconstruction by the hologram. The change of the observed samples during the observation process caused by the application of holography microscope and the need to adjust the focal length manually for clear 3D reconstruction images were time and labour consuming. Therefore, the system highlights the importance of autofocusing.
    Autofocusing System for 3D Digital Holography Reconstruction includes diffraction computation (Fresnel transform), phase unwrapping (DCT-based minimum mean square algorithm) and numerical evaluation (Normalized Variance). Diffraction computation reconstructs the wrapped phase and phase unwrapping reconstructs the unwrapped phase. Processing numerical evaluation with unwrapped phase demonstrates whether the 3D reconstructed images are in of focus or not. This system uses multiple I/O technology to decrease the time when the system changes focal length and loads the original hologram.
    The experimental results and performance analysis indicates that the system has the ability to reconstruct large size hologram. And the DCT-based phase unwrapping algorithm provides competitive reconstructing time. Comparing this system implementation on FPGA, MATLAB, CPU and GPU, the system implementation on FPGA has less reconstructing time and lower power consumption.

    Keyword: FPGA, Autofocusing, Hologram reconstruction, Discrete cosine transform

    中文摘要 I 英文摘要 II 誌謝 III 目錄 IV 附表目錄 VI 附圖目錄 VII 第一章 緒論 1 第一節 研究背景 1 第二節 動機與目的 3 第三節 研究方法 5 第四節 全文架構 7 第二章 基礎理論及技術背景 8 第一節 相位重建之基礎理論 8 第二節 相位展開之基礎理論 12 第三節 自動對焦之基礎理論 15 第四節 FPGA與SoPC系統整合設計 18 第三章 系統架構 21 第一節 整體系統架構 21 第二節 相位展開電路 23 第一項 拉普拉斯運算單元 23 第二項 離散餘弦轉換單元 26 第三項 頻率域運算單元 29 第四項 離散餘弦反轉換單元 30 第五項 控制器與內建記憶體 32 第三節 繞射計算電路 36 第四節 評估運算電路 37 第五節 自動對焦資料流程 38 第四章 實驗數據與效能分析 40 第一節 開發平台與實驗環境設定 40 第二節 實驗數據呈現與討論 42 第五章 結論 58 參考文獻 59

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