An Ancilla Based Quantum Simulation Framework for Non-Unitary Matrices

TL;DR

This paper introduces a quantum simulation framework using ancilla qubits and oblivious amplitude amplification to efficiently simulate non-unitary matrices, achieving high fidelity and success probabilities.

Contribution

It extends non-unitary matrices to near-unitary forms and demonstrates sequential circuit composition for simulating complex matrix functions on quantum computers.

Findings

Final amplified probabilities around 0.75

Fidelity of final states approximately 0.95

Sequential circuit composition enables matrix product implementation

Abstract

The success probability in an ancilla based circuit generally decreases exponentially in the number of qubits consisted in the ancilla. Although the probability can be amplified through the amplitude amplification process, the input dependence of the amplitude amplification makes difficult to sequentially combine two or more ancilla based circuits. A new version of the amplitude amplification known as the oblivious amplitude amplification runs independently of the input to the system register. This allow us to to sequentially combine two or more ancilla based circuits. However, this type of the amplification only works when the considered system is unitary or non-unitary but somehow close to a unitary. In this paper, we present a general framework to simulate non-unitary matrices on ancilla based quantum circuits in which the success probability is maximized by using the oblivious amplitude amplification. In particular, we show how to extend a non-unitary matrix to an almost unitary matrix. We then simulate the extended matrix by using an ancilla based circuit design along with the oblivious amplitude amplification. Measuring the distance of the produced matrix to the closest unitary unitary matrix, a lower bound for the fidelity of the final state obtained from the oblivious amplitude amplification process is presented. Numerical simulations for random matrices of different sizes show that independent of the system size, the final amplified probabilities are generally around 0.75 and the fidelity of the final state is mostly high and around 0.95. Furthermore, we discuss the complexity analysis and show that combining two such ancilla based circuits, a matrix product can be implemented. This may lead us to efficiently implement matrix functions represented as infinite matrix products on quantum computers.