Quantum-Accelerated Gowers U2 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 U2 norm as the evolutionary fitness function. Our central contribution is a complexity-theoretic separation: the quantum evaluation circuit requires only 3n qubits and (n2) two-qubit gates per function query, whereas the classical computation of the exact Gowers U2 norm demands (22n) arithmetic operations an exponential overhead that renders it infeasible for n 25. We validate the framework on n=6 and n=8 variable systems. For n=8, our classical GA run extended to 1000 generations achieves best fitness = 0.250000 exactly the theoretical bent threshold 2-n/4 with average fitness 0.257267, confirming that the Gowers U2 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 > 25 the quantum evaluator provides a decisive computational advantage on fault-tolerant hardware.