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研究生: 秦勢翔
Chin, Shih-Hsiang
論文名稱: 針對工程變更命令電路利用布林可滿足性問題使邏輯差異最小化
A SAT-based Minimal Logic Difference Engine for Functional ECO
指導教授: 麥偉基
口試委員: 黃婷婷
王廷基
學位類別: 碩士
Master
系所名稱: 電機資訊學院 - 資訊工程學系
Computer Science
論文出版年: 2014
畢業學年度: 102
語文別: 英文
論文頁數: 23
中文關鍵詞: 邏輯差異最小化
外文關鍵詞: logic difference
相關次數: 點閱:2下載:0
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    • 在IC 設計工業中,隨著技術越來越進步,設計也越來越複雜,
    經常會在設計的後端才發現問題,功能性的工程變更命令(ECO)的技
    術的應用,可有效的減少設計的時間以及製造的成本。在這篇論文,
    我們提出一個三階段的演算法,找尋兩電路最少的相異部分,最後利
    用邏輯閘回收使用的方法減少相異的部分。第一階段,從輸出端找尋
    結構等價的部分,第二階段,使用可滿足性(SAT)檢測程式,找尋兩
    電路邏輯等價的輸入端邊界,第三階段,替換部分邏輯閘找尋邏輯等
    價的輸出端。利用這三階段找到的相異電路再進行減小。從實驗解果
    可以得知,在大部分的案例都有不錯的結果。

    In the IC industry, chip design cycles are becoming more compressed, while designs
    themselves are growing in complexity. Functional specifications are often modified late
    in the design cycle, after placement and routing are complete. These trends necessitate
    efficient methods to handle late-stage engineering change orders (ECOs) to the functional
    specification, often in response to errors discovered after much of the implementation is
    finished. In this thesis, we propose a three-stage algorithm for generating a minimal logic
    difference between an original circuit and a modified circuit. Our method has three different
    stages and we perform them in order to produce a better patch. In the first phase, we search
    from the primary outputs to find structural equivalence between the original circuit and
    the modified circuit. In the second phase, we modify DeltaSyn[1] to use a SAT solver
    to identify logic equivalence near the input-side boundary of the changes. In the third
    phase, we create levels in each gate. According to levels, we check logically equivalent and
    choose replaced gates. After the three different stages, a gate-recycle[2] process performs
    the patch minimization in the final step. Encouraging experimental results are obtained by
    our method.

    Acknowledgement Abstract 1 Introduction 1.1 ECO 1.2 Contribution 1.3 Organization 2 Previous Works 3 Algorithm 8 3.1 Structure Equivalence Matching 3.2 Logic Equivalence Checking 3.3 Replace and Check 3.4 Patch Creation and Patch Minimization 4 Experiment 18 4.1 Experimental Setup 4.2 Results and Analysis 5 Conclusion Reference

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