Elissa Mollakuqe, Shasivar Rexhepi, Ridvan Bunjaku, Hasan Dag, Ikechukwu John Chukwu
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引用次数: 0
Abstract
Background: Cryptography plays a crucial role in securing digital communications and data storage. This study evaluates the Transparent Key Management Algorithm utilizing Merkle trees, focusing on its performance and security effectiveness in cryptographic key handling.
Methods: The research employs simulated experiments to systematically measure and analyze key operational metrics such as insertion and verification times. Synthetic datasets are used to mimic diverse operational conditions, ensuring rigorous evaluation under varying workloads and security threats. Implementation is carried out using R programming, integrating cryptographic functions and Merkle tree structures for integrity verification.
Results: Performance analysis reveals efficient insertion and verification times under normal conditions, essential for operational workflows. Security evaluations demonstrate the algorithm's robustness against tampering, with approximately 95% of keys verified successfully and effective detection of unauthorized modifications. Simulated attack scenarios underscore its resilience in mitigating security threats.
Conclusions: The Transparent Key Management Algorithm, enhanced by Merkle trees and cryptographic hashing techniques, proves effective in ensuring data integrity, security, and operational efficiency. Recommendations include continuous monitoring and adaptive algorithms to bolster resilience against evolving cybersecurity challenges, promoting trust and reliability in cryptographic operations.
背景:密码学在确保数字通信和数据存储安全方面发挥着至关重要的作用。本研究评估了利用梅克尔树的透明密钥管理算法,重点关注其在加密密钥处理方面的性能和安全有效性:研究采用模拟实验系统地测量和分析插入和验证时间等关键运行指标。合成数据集用于模拟不同的运行条件,确保在不同的工作负载和安全威胁下进行严格的评估。使用 R 编程进行实施,集成了加密函数和用于完整性验证的梅克尔树结构:结果:性能分析表明,在正常条件下,插入和验证时间很短,这对业务工作流程至关重要。安全性评估证明了该算法对篡改的稳健性,约 95% 的密钥验证成功,并能有效检测未经授权的修改。模拟的攻击场景强调了该算法在减轻安全威胁方面的弹性:通过梅克尔树和加密哈希技术增强的透明密钥管理算法在确保数据完整性、安全性和运行效率方面证明是有效的。建议包括持续监控和自适应算法,以增强应对不断变化的网络安全挑战的能力,提高密码操作的信任度和可靠性。
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