This paper introduces a novel approach to smart intelligence cyber security, addressing vulnerabilities inherent in traditional methods that often succumb to authentication and key policy failures, leading to cyber-attacks. Our proposed system leverages Hash Coded Stegno-Lattice Block Policy (HCS-LBP) to enhance data protection by creating pixel blocks interconnected through star link convective points, generating unique hash IDs for block-level security and sequence integrity. To further fortify the system, the Edwards-curve Digital Signature Algorithm (ECDSA) generates lattice block folding encryption, effectively encrypting the content within each block. A Master Key Authentication Policy (MKAP) is then implemented to establish a robust key policy with granular access control mechanisms. Finally, Merkle Tree Block Level Integrity Verification (MTBLIV) integrated with Proof of Stake (PoS) is utilized to verify key integrity and ensure secure data handover at the peer end. This multi-layered approach aims to provide a resilient and secure framework for smart intelligence systems against evolving cyber threats.

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Smart Intelligence Cyber Security Based on Hash Coded Stegno-Lattice Block Policy Steganography Using Edwards-Curve Digital Signature Algorithm

  • Sreena G. Nair,
  • K. Rohini

摘要

This paper introduces a novel approach to smart intelligence cyber security, addressing vulnerabilities inherent in traditional methods that often succumb to authentication and key policy failures, leading to cyber-attacks. Our proposed system leverages Hash Coded Stegno-Lattice Block Policy (HCS-LBP) to enhance data protection by creating pixel blocks interconnected through star link convective points, generating unique hash IDs for block-level security and sequence integrity. To further fortify the system, the Edwards-curve Digital Signature Algorithm (ECDSA) generates lattice block folding encryption, effectively encrypting the content within each block. A Master Key Authentication Policy (MKAP) is then implemented to establish a robust key policy with granular access control mechanisms. Finally, Merkle Tree Block Level Integrity Verification (MTBLIV) integrated with Proof of Stake (PoS) is utilized to verify key integrity and ensure secure data handover at the peer end. This multi-layered approach aims to provide a resilient and secure framework for smart intelligence systems against evolving cyber threats.