Related papers: Hardware requirements for trapped-ion based verifiable blind quantum computing with a measurement-only client

Hardware requirements for trapped-ion based verifiable blind quantum computing with a measurement-only client

URL: http://arxiv.org/abs/2403.02656v2
Date: Fri, 13 Sep 2024 10:57:00 GMT
Title: Hardware requirements for trapped-ion based verifiable blind quantum computing with a measurement-only client
Authors: Janice van Dam, Guus Avis, Tzula B Propp, Francisco Ferreira da Silva, Joshua A Slater, Tracy E Northup, Stephanie Wehner,
Abstract summary: In blind quantum computing, a user with a simple client device can perform a quantum computation on a remote quantum server. We numerically investigate hardware requirements for verifiable blind quantum computing using an ion trap as server and a distant measurement-only client.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In blind quantum computing, a user with a simple client device can perform a quantum computation on a remote quantum server such that the server cannot gain knowledge about the computation. Here, we numerically investigate hardware requirements for verifiable blind quantum computing using an ion trap as server and a distant measurement-only client. While the client has no direct access to quantum-computing resources, it can remotely execute quantum programs on the server by measuring photons emitted by the trapped ion. We introduce a numerical model for trapped-ion quantum devices in NetSquid, a discrete-event simulator for quantum networks. Using this, we determine the minimal hardware requirements on a per-parameter basis to perform the verifiable blind quantum computing protocol. We benchmark these for a five-qubit linear graph state, with which any single-qubit rotation can be performed, where client and server are separated by 50 km. Current state-of-the-art ion traps satisfy the minimal requirements on a per-parameter basis, but all current imperfections combined make it impossible to perform the blind computation securely over 50 km using existing technology. Using a genetic algorithm, we determine the set of hardware parameters that minimises the total improvements required, finding directions along which to improve hardware to reach our threshold error probability that would enable experimental demonstration. In this way, we lay a path for the near-term experimental progress required to realise the implementation of verifiable blind quantum computing over a 50 km distance.

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