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研究生: 黃鯤義
Huang, Kun-Yih
論文名稱: 使用定位摩克樹作資料存證的應用研究
Applications of Transaction Positioned Merkle Tree for Data Attestation
指導教授: 黃冠寰
Hwang, Gwan-Hwan
口試委員: 許建榮
Hsu, Chien-Jung
毛敬豪
Mao, Ching-Hao
張道顧
Chang, Tao-Ku
林哲生
Lin, Che-Sheng
賀耀華
Ho, Yao-Hua
黃冠寰
Hwang, Gwan-Hwan
口試日期: 2024/01/05
學位類別: 博士
Doctor
系所名稱: 資訊工程學系
Department of Computer Science and Information Engineering
論文出版年: 2024
畢業學年度: 112
語文別: 中文
論文頁數: 117
英文關鍵詞: public blockchain, smart contract, decentralized data attestation, tp-Merkle tree, cloud computing, cloud auditing, decentralized auditing, blockchain based automatic reward
研究方法: 實驗法
DOI URL: http://doi.org/10.6345/NTNU202400077
論文種類: 學術論文
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  • 在大數據(big data)的網路時代,由於各種原因,無論是人為造成的或意外發生的情況,都可能導致有價值的資訊遭受損壞、竄改或竊取等危害。因此,確認各種活動或資訊交易的身份正確性,以及保障其內容、結果的安全性、以及日後追查稽核或即時稽核與驗證的相互不可否認性與可歸責性,成為大數據網路時代資訊安全的核心工作。公有區塊鏈(public blockchains)憑藉其去中心化的分散式架構,具有不可竄改性與透明性,透過共識協定使得網路節點能夠相互監督,進而達到資料的可信任性。
    然而,受限於區塊鏈高額礦工費與每秒交易筆數(TPS)的低限制,大量的資訊難以儲存於區塊鏈中。因此,本論文採用了Hwang等人提出的定位摩克樹(transaction positioned Merkle tree)[ 83, 97, 98, 100]作為存證的基礎技術。在對定位摩克樹的效能進行一般性測試之後,筆者選擇了兩個代表性的情境進行深入研究。
    第一項研究提出了雲端服務執行環境完整性即時稽核的架構,這不僅可以避免執行環境因遭攻擊、竄改或損壞所造成的意外,同時也能夠在系統運作時即時發現是否有遭受攻擊、竄改、遺失檔案或惡意軟體的植入,例如電腦病毒或木馬程式。
    第二項研究模擬了如何在真實人類情境中,利用定位摩克樹與公有區塊鏈,實現基於公有區塊鏈的自動給付與申訴賠償機制。結果證明了利用定位摩克樹的證據存證技術可以完全解決情境中的信任問題,且不受限於公有區塊鏈效能瓶頸。
    總結而言,本研究提供了一個具體而有效的方法,結合定位摩克樹與公有區塊鏈,以應對大數據網路時代資訊安全的挑戰。這些方法不僅具有實用性,同時突破了公有區塊鏈效能的桎梏。

    In the era of big data in the Internet, various factors, whether intentional or accidental, have led to valuable information being damaged, altered, or stolen. Therefore, ensuring the correctness of identities in various activities or information transactions, the security of their content and results, as well as the mutual non-repudiation and accountability of tracing or real-time auditing in the future, are the primary tasks of information security in the big data network era. Due to the decentralized and distributed architecture of public blockchains, which possess immutability and transparency, the network nodes can supervise each other through consensus protocols, thereby achieving data trustworthiness.
    However, due to the high transaction fees (miner fees) and the low transaction per second (TPS) of blockchains, a large amount of information cannot be attested on the blockchain. Therefore, this dissertation adopts the transaction positioned Merkle tree (tp-Merkle tree) [ 83, 97, 98, 100] proposed by Hwang et al. as the foundational technology for evidence preservation. After conducting general performance tests on the tp-Merkle Tree, the author chose two representative scenarios for in-depth research.
    The first study proposes an architecture for real-time auditing of the integrity of cloud service runtime environments. This can not only prevent accidents caused by attacks, tampering, or damage to the execution environment but also detect in real-time whether the system is under attack, being tampered with, has lost files, or has been implanted with malicious software, such as computer viruses or Trojan horses.
    The second study simulates how to implement an automatic payment and complaint compensation mechanism based on public blockchains and tp-Merkle trees in real human scenarios. The results demonstrate that the evidence preservation technology using tp-Merkle tree can completely solve trust issues in the scenario and is not limited by the performance bottleneck of public blockchains.
    In conclusion, these researches provide a concrete and effective method that combines tp-Merkle trees with public blockchains to manage and deal with the challenges of information security in the big data network era. These methods are not only practical but they also overcome the limitations of public blockchain.

    謝誌 i 中文摘要 ii 英文摘要 iv 目錄 vi 附表目錄 viii 附圖目錄 ix 第一章 簡介 1 第一節 由Web 2.0到Web 3.0 3 第二節 可信任的第三方的問題 5 第三節 去中心化技術:區塊鏈 7 1.3.1 Bitcoin 9 1.3.2 Ethereum 11 1.3.3 公有區塊鏈的問題 12 1.3.4 目前已有的解決方案與其問題 17 第四節 研究動機與目的 22 1.4.1 需要有安全的資料存證空間與快速稽核機制 23 第五節 研究成果 25 1.5.1 雲端服務平台的稽核應用 26 1.5.2 利用公有區塊鏈提供自動給付與賠償機制的應用 29 第六節 論文架構 30 第二章 資料的採證與存證 31 第一節 資料存證 31 第二節 傳統的資料採證方法 31 2.2.1 雜湊 31 2.2.2 數位簽章 32 2.2.2.1 雜湊鏈 32 2.2.3 以雜湊樹存證 32 第三章 研究的資料採證與存證方法 36 第一節 C & L scheme 36 第二節 Proof of Violation 38 第三節 定位摩克樹 41 3.3.1 密碼學證據:Merkle proof 44 3.3.2 增加或更新一筆資料到定位摩克樹 47 3.3.3 在定位摩克樹中驗證一筆資料 48 3.3.4 定位摩克樹的效能 49 第四節 定位摩克樹的相關研究 56 3.4.1 雲端儲存空間檔案的存證與稽核 56 3.4.2 區塊鏈的擴容與分散式稽核:InfinteChain 58 3.4.3 雲端儲存空間使用的自動賠償機制 60 3.4.4 公共金鑰基礎建設的應用 62 第四章 研究成果與實驗結果 65 第一節 雲端執行環境的即時稽核 65 4.1.1 系統架構 67 4.1.1.1 直覺式方案一:檔案的雜湊值以PB pair存放在HVA 72 4.1.1.2 直覺式方案二:檔案的雜湊值以m元雜湊樹存放在HVA 72 4.1.2 實驗結果 74 4.1.3 相關研究 79 第二節 利用公有區塊鏈的自動給付系統 83 4.2.1 系統架構 85 4.2.2 實驗結果 91 4.2.3 相關研究 96 第五章 結論與未來探討 98 第一節 研究結果與討論 99 第二節 未來探討 103 參考文獻 104

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