A compiler for universal photonic quantum computers

• URL: http://arxiv.org/abs/2210.09251v1
• Date: Mon, 17 Oct 2022 16:47:45 GMT
• Title: A compiler for universal photonic quantum computers
• Authors: Felix Zilk (1) and Korbinian Staudacher (2) and Tobias Guggemos (1) and Karl F\"urlinger (2) and Dieter Kranzlm\"uller (3) and Philip Walther (1) ((1) Christian Doppler Laboratory for Photonic Quantum Computer, Faculty of Physics, University of Vienna, Vienna, Austria (2) MNM-Team, Ludwig-Maximilians-Universit\"at (LMU), Munich, Germany (3) MNM-Team, Leibniz Supercomputing Centre (LRZ), Garching, Germany)
• Abstract summary: In one-way computing, the input state is not an initial product state, but a so-called cluster state. We propose a pipeline to convert a QASM circuit into a graph representation named measurement-graph (m-graph) We optimize the graph using ZX-Calculus before evaluating the execution on an experimental discrete variable photonic platform.
• Score: 0.0
• License: http://creativecommons.org/licenses/by-sa/4.0/
• Abstract: Photons are a natural resource in quantum information, and the last decade showed significant progress in high-quality single photon generation and detection. Furthermore, photonic qubits are easy to manipulate and do not require particularly strongly sealed environments, making them an appealing platform for quantum computing. With the one-way model, the vision of a universal and large-scale quantum computer based on photonics becomes feasible. In one-way computing, the input state is not an initial product state, but a so-called cluster state. A series of measurements on the cluster state's individual qubits and their temporal order, together with a feed-forward procedure, determine the quantum circuit to be executed. We propose a pipeline to convert a QASM circuit into a graph representation named measurement-graph (m-graph), that can be directly translated to hardware instructions on an optical one-way quantum computer. In addition, we optimize the graph using ZX-Calculus before evaluating the execution on an experimental discrete variable photonic platform.

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