Nearly Optimal Circuit Size for Sparse Quantum State Preparation

Abstract

Quantum state preparation is a fundamental and significant subroutine in quantum computing. In this paper, we conduct a systematic investigation on the circuit size (the total count of elementary gates in the circuit) for sparse quantum state preparation. A quantum state is said to be d-sparse if it has only d non-zero amplitudes. For the task of preparing an n-qubit d-sparse quantum state, we obtain the following results: Without ancillary qubits: Any n-qubit d-sparse quantum state can be prepared by a quantum circuit of size O(nd n + n) without using ancillary qubits, which improves the previous best results. It is asymptotically optimal when d = poly(n), and this optimality holds for a broader scope under some reasonable assumptions. With limited ancillary qubits: (i) Based on the first result, we prove for the first time a trade-off between the number of ancillary qubits and the circuit size: any n-qubit d-sparse quantum state can be prepared by a quantum circuit of size O(nd (n + m) + n) using m ancillary qubits for any m ∈ O(nd nd + n). (ii) We establish a matching lower bound (nd (n + m) + n) under some reasonable assumptions, and obtain a slightly weaker lower bound (nd (n + m) + d + n) without any assumptions. With unlimited ancillary qubits: Given arbitrary amount of ancillary qubits available, the circuit size for preparing n-qubit d-sparse quantum states is (nd nd + n).