在本篇文章中，我們提出以序優化(OO)為基礎的演算法解決網格運算系統的資源配置最佳化問題，使服務可靠度達到最大化。首先提出一個近似模型在一個合理的時間內計算出資源配置的服務可靠度。接著利用所提出的演算法來解決資源配置最佳化問題。以序優化為基礎的演算法分為兩階段，在第一階段使用基因演算法(GA)搭配近似模型來評估適應值並且選擇足夠好的解之子集合。然後在第二階段使用更精緻的近似模型進行目標搜索找出一個足夠好的解。本研究以一個16節點為架構的網格運算系統作為模擬與測試範例，包含二個資源管理節點以及25條連結，所獲得足夠好的解在品質以及計算效能方面都有出色的表現。而利用Pentium IV電腦進行模擬，所提出的演算法僅花費2.35分鐘就可獲得足夠好的資源配置。

In this paper, we propose an ordinal optimization (OO) based algorithm for solving the resource allocation optimization problem of grid computing system to maximize the service reliability. An approximate model is firstly proposed to estimate the service reliability of a resource allocation design within a tolerable computation time. Next, we employ the proposed algorithm to solve the resource allocation optimization problem. The OO based algorithm consists of two stages. Genetic algorithm (GA) is employed in the first stage using the approximate model for fitness evaluation and selects a subset of good enough solutions. Then, we proceed with the goal softening searching procedure in the second stage using more refined approximate models to search for a good enough solution. We have demonstrated the test results by simulating on an 16-node and 25-link grid computing system including one resource-managing node. The good enough solution obtained by the proposed algorithm is promising in the aspects of solution quality and computational efficiency. In addition, the proposed algorithm spends only 2.35 minutes in a Pentium IV PC to obtain the good enough resource allocation design.

索引目錄
中文摘要 I
Abstract II
致謝 III
索引目錄 IV
表目錄 VI
圖目錄 VIII
符號說明 IX
第一章　緒論 1
1.1 網格運算系統 1
1.2 研究方法與論文架構 5
第二章　擴大服務能力以及提高服務可靠度 6
2.1 服務可靠度 6
2.2 最小化預算以及最大化可靠度問題 8
2.3 最小資源生成樹(MRST) 10
2.3.1 MRST範例說明 13
2.4 基因演算法 22
2.4.1 選擇與適應函數 24
2.4.2 參數設定 25
第三章　序優化演算法 28
3.1 使用近似模型評估服務可靠度 28
3.2 探索階段 29
3.2.1 基因演算法固定資源配置 30
3.2.2 基因演算法增加資源配置 34
3.3 開發階段 38
3.4 二分法修正最小化預算問題 40
第四章　測試結果 42
4.1 16節點範例 42
4.1.1 16節點以二分法修正預算成本 44
4.2 8節點範例 47
第五章　結論 51
參考文獻 52

表目錄
表1. 每個連結的速度與故障率 19
表2. 執行程式所需的資料與時間 19
表3. 節點故障率 19
表4. 網格系統可靠度的估算 19
表5. Pr(E1∩E2)取工作時間最大表 20
表6. Pr(E1∩E2∩E3)取工作時間最大表 21
表7. 16個節點之故障率 (s-1). 43
表8. 25條連結的故障率 (s-1)以及頻寬S(i,j) (Kbps) 43
表9. 16節點範例資源總處理時間. 43
表10. 6種類型資源資訊交換量以及花費成本. 44
表11. 16節點範例預算成本為 時的節點最佳資源配置. 44
表12. 二分法求解預算成本以及服務可靠度. 45
表13. 16節點範例預算成本 節點最佳資源配置結果. 46
表14. 8個節點之故障率 (s-1). 49
表15. 11條連結的故障率 (s-1)以及頻寬S(i,j) (Kbps). 49
表16. 8節點範例資源總處理時間. 49
表17. 4種類型資源資訊交換量以及花費成本. 49
表18. 8節點範例執行結果. 50
表19. 8節點範例預算成本 節點最佳資源配置結果. 50

圖目錄
圖1. 網格運算系統架構 3
圖2. 範例網路架構 17
圖3. E1∩E2示意圖 20
圖4. E1∩E2∩E3示意圖 21
圖5. 基因演算法之演化流程圖 23
圖6. 三種交配運算圖 26
圖7. 基因演算法固定資源配置流程圖 33
圖8. 基因演算法增加資源配置流程圖 37
圖9. 16節點與25連結網格運算系統架構 43
圖10. 二分法8次修正範圍 46
圖11. 基因演算法耗費CPU時間 47
圖12. 8節點與11連結網格運算系統架構 48

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