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Boosting the Diversity of a Similarity-Aware Genetic Algorithm Using a Siamese Network for Optimized S-Box

Ishfaq Ahmad Khaja1, Musheer Ahmad1, Louai A Maghrabi2

  • 1Department of Computer Engineering, Jamia Millia Islamia, New Delhi 110025, India.

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Summary
This summary is machine-generated.

This study introduces a novel similarity-aware genetic algorithm (GA) to optimize substitution-boxes (S-boxes) for cryptography. The enhanced GA improves parental diversity, leading to faster convergence and more robust S-box designs.

Keywords:
Siamese networkcrossoverdiversitygenetic algorithmloss functionsimilarity learningsubstitution-box

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Area of Science:

  • Cryptography
  • Optimization Algorithms
  • Machine Learning

Background:

  • Designing cryptographically robust substitution-boxes (S-boxes) is an NP-hard problem.
  • Genetic Algorithms (GAs) are commonly used but suffer from premature convergence and lack of diversity.
  • Limited a priori knowledge in traditional GAs hinders performance in S-box optimization.

Purpose of the Study:

  • To propose a similarity-aware crossover strategy integrated with a Siamese learning framework for improved S-box optimization.
  • To enhance parental diversity within the GA to ensure propagation of diverse traits.
  • To achieve faster convergence and generate S-boxes with superior cryptographic properties.

Main Methods:

  • A Siamese learning framework is integrated with a genetic algorithm.
  • A similarity-aware crossover strategy is introduced, employing 'regressive' crossover when parents are too similar.
  • The model is evaluated using contrastive loss, KL divergence loss, and a hybrid loss function.

Main Results:

  • The proposed similarity-aware GA effectively optimizes S-boxes, demonstrating improved diversity and faster convergence.
  • The strategy ensures propagation of parental diversity, leading to superior offspring.
  • Generated S-boxes exhibit strong cryptographic properties, validated through rigorous testing.

Conclusions:

  • The similarity-aware GA with Siamese learning offers a significant advancement in S-box design.
  • This approach addresses the limitations of traditional GAs by incorporating local parental information.
  • The method successfully generates high-quality S-boxes with enhanced cryptographic robustness.