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Quantum-Accelerated Gowers $U_2$ Norm for Bent Boolean Functions

Quantum Physics 2026-05-26 v3

Abstract

Bent Boolean functions extremal objects that maximally resist affine approximation are notoriously hard to construct for large numbers of variables. We propose a hybrid quantum-classical genetic algorithm (GA) that uses a quantum circuit to evaluate the Gowers U2U_2 norm as the evolutionary fitness function. Our central contribution is a complexity-theoretic separation: the quantum evaluation circuit requires only 3n3n qubits and \bigO(n2)\bigO(n^2) two-qubit gates per function query, whereas the classical computation of the exact Gowers U2U_2 norm demands \bigO(22n)\bigO(2^{2n}) arithmetic operations an exponential overhead that renders it infeasible for n25n \gtrsim 25. We validate the framework on n=6n=6 and n=8n=8 variable systems. For n=8n=8, our classical GA run extended to 1000 generations achieves best fitness \Utwof=0.250000\Utwof = 0.250000 \emph{exactly} the theoretical bent threshold 2n/42^{-n/4} with average fitness 0.2572670.257267, confirming that the Gowers U2U_2 norm is a superior fitness criterion over Walsh-Hadamard spectral flatness. Quantum-assisted evaluation faithfully reproduces the classical trajectory up to finite-sampling noise, and our complexity analysis demonstrates that for n>25n > 25 the quantum evaluator provides a decisive computational advantage on fault-tolerant hardware.

Keywords

Cite

@article{arxiv.2604.25503,
  title  = {Quantum-Accelerated Gowers $U_2$ Norm for Bent Boolean Functions},
  author = {Rajdeep Dwivedi and C. A. Jothiwashran and Sugata Gangopadhyay and Vishvendra Singh Poonia},
  journal= {arXiv preprint arXiv:2604.25503},
  year   = {2026}
}
R2 v1 2026-07-01T12:39:00.934Z