Related papers: Ultrahigh-fidelity spatial mode quantum gates in high-dimensional space by diffractive deep neural networks

Ultrahigh-fidelity spatial mode quantum gates in high-dimensional space by diffractive deep neural networks

URL: http://arxiv.org/abs/2411.16410v1
Date: Mon, 25 Nov 2024 14:16:55 GMT
Title: Ultrahigh-fidelity spatial mode quantum gates in high-dimensional space by diffractive deep neural networks
Authors: Qianke Wang, Jun Liu, Dawei Lyu, Jian Wang,
Abstract summary: We show the use of the multi-dimensional spatial mode of photons to construct a series of high-dimensional quantum gates. Our gates demonstrate high fidelity of up to 99.6(2)%, as characterized by quantum process tomography. Our work opens a door for designing specific quantum gates using deep learning, with the potential for reliable execution of quantum computation.
Score: 5.153557964788408
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Abstract: While the spatial mode of photons is widely used in quantum cryptography, its potential for quantum computation remains largely unexplored. Here, we showcase the use of the multi-dimensional spatial mode of photons to construct a series of high-dimensional quantum gates, achieved through the use of diffractive deep neural networks (D2NNs). Notably, our gates demonstrate high fidelity of up to 99.6(2)%, as characterized by quantum process tomography. Our experimental implementation of these gates involves a programmable array of phase layers in a compact and scalable device, capable of performing complex operations or even quantum circuits. We also demonstrate the efficacy of the D2NN gates by successfully implementing the Deutsch algorithm and propose an intelligent deployment protocol that involves self-configuration and self-optimization. Moreover, we conduct a comparative analysis of the D2NN gate's performance to the wave-front matching approach. Overall, our work opens a door for designing specific quantum gates using deep learning, with the potential for reliable execution of quantum computation.

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