Quantum Phase Estimation with Time-Frequency Qudits in a Single Photon
Abstract
The Phase Estimation Algorithm (PEA) is an important quantum algorithm used independently or as a key subroutine in other quantum algorithms. Currently most implementations of the PEA are based on qubits, where the computational units in the quantum circuits are two-dimensional states. Performing quantum computing tasks with higher dimensional states -- qudits -- has been proposed, yet a qudit-based PEA has not been realized. Using qudits can reduce the resources needed for achieving a given precision or success probability. Compared to other quantum computing hardware, photonic systems have the advantage of being resilient to noise, but the probabilistic nature of photon-photon interaction makes it difficult to realize two-photon controlled gates that are necessary components in many quantum algorithms. In this work, we report an experimental realization of a qudit-based PEA on a photonic platform, utilizing the high dimensionality in time and frequency degrees of freedom (DoFs) in a single photon. The controlled-unitary gates can be realized in a deterministic fashion, as the control and target registers are now represented by two DoFs in a single photon. This first implementation of a qudit PEA, on any platform, successfully retrieves any arbitrary phase with one ternary digit of precision.
Cite
@article{arxiv.1906.11401,
title = {Quantum Phase Estimation with Time-Frequency Qudits in a Single Photon},
author = {Hsuan-Hao Lu and Zixuan Hu and Mohammed S. Alshaykh and Alexandria J. Moore and Yuchen Wang and Poolad Imany and Andrew M. Weiner and Sabre Kais},
journal= {arXiv preprint arXiv:1906.11401},
year = {2019}
}
Comments
7 pages, 4 figures