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研究生: 郭紹偉
論文名稱: 多模式AES之小面積超大型積體電路設計
VLSI Design for Modes of Operation of Low-area AES
指導教授: 黃奇武
Huang, Chi-Wu
張吉正
Chang, Chi-Jeng
學位類別: 碩士
Master
系所名稱: 電機工程學系
Department of Electrical Engineering
論文出版年: 2013
畢業學年度: 101
語文別: 中文
論文頁數: 63
中文關鍵詞: 進階加密標準現場可程式邏輯閘陣列超大型積體電路標準元件設計流程
英文關鍵詞: AES, FPGA, VLSI, cell-based design flow
論文種類: 學術論文
相關次數: 點閱:153下載:0
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  • 進階加密標準(Advanced Encryption Standard, AES)在現場可程式邏輯閘陣列(field-programmable gate array,FPGA)與特殊用途積體電路(application-specific integrated circuit,ASIC) 的硬體實作已經被廣泛地討論,近幾年則朝向小面積硬體架構的議題做研究。
    本實驗室在FPGA板子上所做的研究已經有相當豐碩的成果,但尚未實現成超大型積體電路(Very-large-scale integration,VLSI)。因此,本論文目標將改善本實驗室開發的AES硬體架構後,並架設工作站透過cell-based數位積體電路設計流程實現AES加解密晶片。
    首先,本研究提出不使用記憶體的8-bit資料線完成128-bit AES硬體電路,進而發展出一個多模式小面積的架構。接著,本實驗室利用國家晶片研究中心(CIC)提供的工具,建立一套完整的數位積體電路設計環境。最後,透過標準元件設計流程(Cell-based design flow)來完成晶片製作,使其下線。

    Advance Encryption Standard (AES) hardware implementation in FPGA and ASIC has been intensely discussed . In recent years , many researchers start to study low-area hardware architecture of AES . However, our team had many designs and scored great successes in FPGA , but we did not implement in very-large-scale integration(VLSI) yet before this paper was finished . Therefore, this paper dedicated to improve the hardware architecture of AES and set up IC design server , then through cell-based design flow to implement the AES chip.
    First, this paper presents an 8-bit data bus architecture of 128-bit AES without memory cells and propose a muti-mode low-area architecture of AES . Second, we use the EDA tools provided by the National Chip Implementation Center(CIC) to set up the development environment for VLSI design. Finally, we completed our first chip by following cell-based design flow , and taped out .

    摘  要 i ABSTRACT ii 誌  謝 iii 目  錄 iv 圖 目 錄 vi 表 目 錄 viii 第一章  緒論 1 1.1  研究背景 1 1.2  研究動機 3 1.3  研究目的 4 1.4  研究步驟 5 第二章  AES 6 2.1  AES(Advanced Encryption Standard)介紹 6 2.1.1 AES演算法 6 2.1.2 數學背景 8 2.1.3 位元組替換與反位元組替換(SubBytes / InvSubBytes) 10 2.1.4 移列運算與反移列運算(ShiftRows / InvShiftRows) 12 2.1.5 混行運算與反混行運算(MixColumns / InvMixColumns) 13 2.1.6 回合金鑰加法運算(AddRoundKey) 15 2.1.7 金鑰擴展 (KeyExpansion) 15 2.2  AES之五種工作模式(Modes of Operation) 20 2.2.1 Electronic Codebook(ECB) 20 2.2.2 Cipher Block Chaining(CBC) 22 2.2.3 Cipher Feedback(CFB) 24 2.2.4 Output Feedback(OFB) 25 2.2.5 Counter Mode(CTR) 26 第三章  文獻探討 27 3.1  Akashi Satoh架構 27 3.2  Johannes Wolkerstorfer架構 30 3.3  Pawel Chodowiec架構 33 3.4  Xinmiao Zang架構 34 第四章  小面積AES硬體電路設計 37 4.1  8位元架構的128位元AES硬體電路 37 4.2 多模式8位元架構的128位元AES硬體電路 39 第五章  Cell-Based Design模擬分析與實現 44 5.1  工作站環境介紹 44 5.2  設計流程 44 5.3  AES晶片設計 47 5.3.1 邏輯合成 (Logic Synthesis) 47 5.3.2 自動佈局與繞線 (Auto Place & Route) 49 5.3.3 8位元AES 之晶片實現 55 5.4  晶片分析比較 57 第六章  結論與未來展望 58 參考文獻 59 學術成就 63

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