A Novel Single-Layer Quantum Neural Network for Approximate SRBB-Based Unitary Synthesis

TL;DR

This paper introduces a single-layer quantum neural network that efficiently approximates unitary operations using SRBB, significantly reducing CNOT gates and demonstrating effectiveness on various unitaries up to 6 qubits.

Contribution

It presents a novel single-layer quantum neural network for unitary synthesis that reduces CNOT count exponentially and reformulates SRBB for practical implementation.

Findings

Achieved exponential reduction in CNOT gates for unitary synthesis.

Successfully implemented and tested on unitaries up to 6 qubits.

Outperformed existing methods in hardware experiments.

Abstract

In this work, a novel quantum neural network is introduced as a means to approximate any unitary evolution through the Standard Recursive Block Basis (SRBB) and is subsequently redesigned with the number of CNOTs asymptotically reduced by an exponential contribution. This algebraic approach to the problem of unitary synthesis exploits Lie algebras and their topological features to obtain scalable parameterizations of unitary operators. First, the original SRBB-based scalability scheme, already known in the literature only from a theoretical point of view, is reformulated for efficient algorithm implementation and complexity management. Remarkably, 2-qubit operators emerge as a special case of the original scaling scheme. Furthermore, an algorithm is proposed to reduce the number of CNOT gates in the scalable variational quantum circuit, thus deriving a new implementable scaling scheme that requires only one layer of approximation. The single layer CNOT-reduced quantum neural network is implemented, and its performance is assessed with a variety of different unitary matrices, both sparse and dense, up to 6 qubits via the PennyLane library. The effectiveness of the approximation is measured with different metrics in relation to two optimizers: a gradient-based method and the Nelder-Mead method. The approximate CNOT-reduced SRBB-based synthesis algorithm is also tested on real hardware and compared with other valid approximation and decomposition methods available in the literature.