Asymmetric Linear-Combination-of-Unitaries Realization of Quantum Convolution via Modular Adders

Abstract

Discrete circular convolution over Z/NZ is a linear operator and can be implemented on quantum hardware within the linear-combination-of-unitaries (LCU) framework. In this work, we make this connection explicit through an asymmetric-LCU formulation: circular convolution is the postselected block of a circuit whose controlled-shift unitary is modular addition on computational-basis states. The asymmetry is essential: fixing the postselection state to the uniform state |u while supplying the kernel state |b as the input ancilla naturally preserves the complex coefficients bi within the block, whereas a symmetric overlap would yield |bi|2 weights and erase their phases. Accordingly, when |a and |b are supplied by upstream quantum routines, the convolution subroutine requires only the fixed uncompute PREPu, completely avoiding the need for a kernel-dependent inverse preparation PREPb. We then introduce a reversal matrix Jn=X n and define reflected shifts Li,n=Li,nJn. This symmetrization yields a recursive operator algebra for convolution that is natively compatible with LCU/block-encoding workflows. The resulting symmetrized operator differs from circular convolution only by one known input-side Jn layer. Crucially, for real-valued kernels, the resulting operator Hn(b)=Σi biLi,n is Hermitian, providing a direct Hermitian interface for quantum singular value transformation (QSVT) and related spectral transformations. Based on this framework, we present a transparent recursive construction, paired with an exactly equivalent optimized bitwise compilation of the same SELECT block. Finally, we evaluate implementation trade-offs and resource scaling under explicit cost-model conventions.

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