Sparse Phase Ansatzes for Resource-Efficient Qudit State Preparation via the SNAP-Displacement Protocol

TL;DR

This paper introduces sparse ansatzes for resource-efficient bosonic qudit state preparation using the SNAP-displacement protocol, optimizing phases to balance fidelity, duration, and complexity in noisy quantum devices.

Contribution

It proposes optimized sparse ansatzes with multi-objective control to improve efficiency and fidelity in bosonic qudit state preparation, especially under realistic noise conditions.

Findings

Sparse ansatzes outperform fully parameterized protocols in ideal and noisy settings.

Optimizing fewer phases yields the strongest advantage in resource reduction.

Trade-offs depend on target states and noise levels, guiding practical implementation.

Abstract

Efficient preparation of nonclassical bosonic states is a central requirement for quantum computing, simulation, and precision metrology. We study resource-efficient quantum state preparation in bosonic qudit systems using the SNAP-displacement (SD) protocol. Existing SD-based approaches typically require a large number of gates and SNAP phases, resulting in complex control pulses with longer ansatz durations and amplified impact of photon-loss and control errors. In this work, we focus on the near- to medium-term regime, in which noisy quantum devices impose trade-offs on the fidelity that can be achieved, which must be taken into account. Specifically, we propose to optimize only a subset of the SNAP phases and introduce three progressively more general sparse ansatzes. To provide fine-grained control and identify the most suitable ansatz for a given target fidelity, we further employ a scalarized multi-objective optimization that trades off fidelity against either the number of phases or the duration of the ansatz. Numerical results for several target states and qudit dimensions up to $d=64$, evaluated through the hypervolume of the Pareto frontiers, show that these sparse ansatzes achieve favorable trade-offs over the fully parameterized SD protocol in both ideal and noisy settings. The advantage is strongest and most consistent when minimizing the number of phases, while improvements in ansatz duration are smaller and more dependent on the target-state family and noise level, suggesting a practical route to more efficient near- and medium-term bosonic state preparation.