Quantum-Accelerated Gowers $U_2$ Norm for Bent Boolean Functions
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 norm as the evolutionary fitness function. Our central contribution is a complexity-theoretic separation: the quantum evaluation circuit requires only qubits and two-qubit gates per function query, whereas the classical computation of the exact Gowers norm demands arithmetic operations an exponential overhead that renders it infeasible for . We validate the framework on and variable systems. For , our classical GA run extended to 1000 generations achieves best fitness \emph{exactly} the theoretical bent threshold with average fitness , confirming that the Gowers 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 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}
}