Hierarchical Cryptographic Signature Mapping for Ransomware Classification: A Structural Decomposition Approach

Encryption-based cyber threats continue to evolve, leveraging increasingly sophisticated cryptographic techniques to evade detection and persist within compromised systems. A hierarchical classification framework designed to analyze structural cryptographic properties provides a novel approach to distinguishing malicious encryption from legitimate cryptographic operations. By systematically decomposing encryption workflows into hierarchical layers, the classification method enhances the ability to recognize distinct patterns across diverse threat variants, reducing the dependence on predefined signatures that often fail against rapidly mutating threats. The study examines how cryptographic feature mapping facilitates improved classification accuracy, highlighting the role of entropy, key exchange mechanisms, and algorithmic dependencies in distinguishing harmful encryption activities. Through experimental validation, the framework demonstrated a high degree of precision across multiple attack families, outperforming conventional classification techniques while maintaining computational efficiency suitable for large-scale cybersecurity applications. The layered structural analysis further enhances forensic investigations, enabling security analysts to dissect encryption workflows to trace attack origins and identify commonalities across different campaigns. The methodology strengthens proactive threat mitigation efforts, offering a scalable and adaptable solution that accounts for both known and emerging encryption-based cyber threats. Comparative evaluations illustrate the advantages of structural decomposition in mitigating false positives and negatives, reinforcing the reliability of cryptographic signature classification in real-world security environments.