中文

QUBO Modeling of Module Learning With Errors: Stability and Scaling in Post-Quantum Cryptography

量子物理 2026-07-07 v1 数学物理

摘要

Lattice-based post-quantum cryptography relies on the hardness of the Learning With Errors (LWE) and Module Learning With Errors (MLWE) problems. This work introduces a constructive framework for encoding small MLWE instances as Quadratic Unconstrained Binary Optimization (QUBO) models suitable for quantum annealing. The formulation jointly represents secret coefficients and explicit error variables within a unified binary optimization structure, enabling their simultaneous recovery from the ground-state solution. Beyond the encoding, we develop a stability analysis of the resulting optimization landscape under additive perturbations. We show that the admissible noise region forms a convex polytope defined by competing candidate secrets, and establish an equivalent characterization in terms of the QUBO energy gap between the optimal and second-best solutions. Numerical experiments on low-dimensional benchmark instances using exact simulation demonstrate correct recovery of both secret and discretized error vectors, and confirm consistency between geometric stability regions and energy-gap behavior. We further quantify the scaling of logical variables and embedding overhead with increasing MLWE dimensions to assess feasibility on quantum annealing architectures. The results establish a systematic connection between MLWE problems and quantum optimization while providing a framework for analyzing robustness properties of QUBO formulations. Although current quantum annealing hardware remains insufficient for cryptographically relevant parameters, the proposed methodology offers a structured basis for studying lattice-based problems in quantum optimization settings without implying a practical threat to standardized post-quantum schemes.

引用

@article{arxiv.2607.05973,
  title  = {QUBO Modeling of Module Learning With Errors: Stability and Scaling in Post-Quantum Cryptography},
  author = {Ruturaj Khamitkar and Durga Pritam Suggisetti and Soujanya Chatti and Varsha Sambhaje and Durga Dasari},
  journal= {arXiv preprint arXiv:2607.05973},
  year   = {2026}
}

备注

14 pages, 7 figures