Comparative Study of Quantum-Circuit Scalability in a Financial Problem

Abstract

Quantum computer is extensively used in solving financial problems. Quantum amplitude estimation, an algorithm that aims to estimate the amplitude of a given quantum state, can be utilized to determine the expectation value of bonds as the logic introduced in quantum risk analysis. As the number of the evaluation qubit increases, the more accurate the precise the outcome expectation value is. This augmentation in qubits, however, also leads to a varied escalation in circuit complexity, contingent upon the type of quantum computing device. By analyzing the number of two-qubit gates in the superconducting circuit and ion-trap quantum system, this study examines that the native gates and connectivity nature of the ion-trap system lead to less complicated quantum circuits. Across a range of experiments conducted with one to nineteen qubits, the examination reveals that the ion-trap system exhibits a two to three factor reduction in the number of required two-qubit gates when compared to the superconducting circuit system.