English

K-sparse Pure State Tomography with Phase Estimation

Quantum Physics 2021-11-16 v2 Computational Complexity Optics

Abstract

Quantum state tomography (QST) for reconstructing pure states requires exponentially increasing resources and measurements with the number of qubits by using state-of-the-art quantum compressive sensing (CS) methods. In this article, QST reconstruction for any pure state composed of the superposition of KK different computational basis states of nn qubits in a specific measurement set-up, i.e., denoted as KK-sparse, is achieved without any initial knowledge and with quantum polynomial-time complexity of resources based on the assumption of the existence of polynomial size quantum circuits for implementing exponentially large powers of a specially designed unitary operator. The algorithm includes O(2/ck2)\mathcal{O}(2 \, / \, \vert c_{k}\vert^2) repetitions of conventional phase estimation algorithm depending on the probability ck2\vert c_{k}\vert^2 of the least possible basis state in the superposition and O(dK(logK)c)\mathcal{O}(d \, K \,(log K)^c) measurement settings with conventional quantum CS algorithms independent from the number of qubits while dependent on KK for constant cc and dd. Quantum phase estimation algorithm is exploited based on the favorable eigenstructure of the designed operator to represent any pure state as a superposition of eigenvectors. Linear optical set-up is presented for realizing the special unitary operator which includes beam splitters and phase shifters where propagation paths of single photon are tracked with which-path-detectors. Quantum circuit implementation is provided by using only CNOT, phase shifter and π/2- \pi \, / \, 2 rotation gates around X-axis in Bloch sphere, i.e., RX(π/2)R_{X}(- \pi \, / \, 2), allowing to be realized in NISQ devices. Open problems are discussed regarding the existence of the unitary operator and its practical circuit implementation.

Keywords

Cite

@article{arxiv.2111.04359,
  title  = {K-sparse Pure State Tomography with Phase Estimation},
  author = {Burhan Gulbahar},
  journal= {arXiv preprint arXiv:2111.04359},
  year   = {2021}
}

Comments

19 pages, 5 figures, edited v2

R2 v1 2026-06-24T07:30:09.943Z