With the ongoing advancements in quantum hardware, it is easy to envision a future where a major part of our global IT infrastructure relies on quantum information processing. In this situation, it is essential to think about how we will handle and protect quantum data. The security of quantum data will be of utmost importance in the future. This paper presents a framework that effectively combines attacks from the Quantum Random Oracle Model (QROM) with a specialized Quantum Encryption Evaluation Framework created in our previous work. This constitutes an extensive assessment framework that exhaustively examines quantum encryption algorithms from both theoretical and practical viewpoints. By doing so, it ensures these algorithms are equipped to withstand sophisticated cryptographic threats, paving the way for secure quantum systems in an increasingly quantum-driven world. Since our framework is comprehensive in both theoretical and practical considerations, this work will be the pioneering step toward standardizing quantum encryption algorithms.

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An Ameliorated Evaluation Framework for Standardizing Quantum Encryption Algorithms

  • S. Soumya,
  • T. Chithralekha

摘要

With the ongoing advancements in quantum hardware, it is easy to envision a future where a major part of our global IT infrastructure relies on quantum information processing. In this situation, it is essential to think about how we will handle and protect quantum data. The security of quantum data will be of utmost importance in the future. This paper presents a framework that effectively combines attacks from the Quantum Random Oracle Model (QROM) with a specialized Quantum Encryption Evaluation Framework created in our previous work. This constitutes an extensive assessment framework that exhaustively examines quantum encryption algorithms from both theoretical and practical viewpoints. By doing so, it ensures these algorithms are equipped to withstand sophisticated cryptographic threats, paving the way for secure quantum systems in an increasingly quantum-driven world. Since our framework is comprehensive in both theoretical and practical considerations, this work will be the pioneering step toward standardizing quantum encryption algorithms.