Towards practical secure delegated quantum computing with semi-classical light
- URL: http://arxiv.org/abs/2409.12103v1
- Date: Wed, 18 Sep 2024 16:24:07 GMT
- Title: Towards practical secure delegated quantum computing with semi-classical light
- Authors: Boris Bourdoncle, Pierre-Emmanuel Emeriau, Paul Hilaire, Shane Mansfield, Luka Music, Stephen Wein,
- Abstract summary: We present an SDQC protocol which drastically reduces the technological requirements of both the client and the server.
More precisely, the client only manipulates an attenuated laser pulse, while the server only handles interacting quantum emitters with a structure capable of generating spin-photon entanglement.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Secure Delegated Quantum Computation (SDQC) protocols are a vital piece of the future quantum information processing global architecture since they allow end-users to perform their valuable computations on remote quantum servers without fear that a malicious quantum service provider or an eavesdropper might acquire some information about their data or algorithm. They also allow end-users to check that their computation has been performed as they have specified it. However, existing protocols all have drawbacks that limit their usage in the real world. Most require the client to either operate a single-qubit source or perform single-qubit measurements, thus requiring them to still have some quantum technological capabilities albeit restricted, or require the server to perform operations which are hard to implement on real hardware (e.g isolate single photons from laser pulses and polarisation-preserving photon-number quantum non-demolition measurements). Others remove the need for quantum communications entirely but this comes at a cost in terms of security guarantees and memory overhead on the server's side. We present an SDQC protocol which drastically reduces the technological requirements of both the client and the server while providing information-theoretic composable security. More precisely, the client only manipulates an attenuated laser pulse, while the server only handles interacting quantum emitters with a structure capable of generating spin-photon entanglement. The quantum emitter acts as both a converter from coherent laser pulses to polarisation-encoded qubits and an entanglement generator. Such devices have recently been used to demonstrate the largest entangled photonic state to date, thus hinting at the readiness of our protocol for experimental implementations.
Related papers
- On-Chip Verified Quantum Computation with an Ion-Trap Quantum Processing Unit [0.5497663232622965]
We present and experimentally demonstrate a novel approach to verification and benchmarking of quantum computing.
Unlike previous information-theoretically secure verification protocols, our approach is implemented entirely on-chip.
Our results pave the way for more accessible and efficient verification and benchmarking strategies in near-term quantum devices.
arXiv Detail & Related papers (2024-10-31T16:54:41Z) - Hardware requirements for trapped-ion based verifiable blind quantum computing with a measurement-only client [0.0]
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.
arXiv Detail & Related papers (2024-03-05T05:03:38Z) - Quantum Optical Memory for Entanglement Distribution [52.77024349608834]
Entanglement of quantum states over long distances can empower quantum computing, quantum communications, and quantum sensing.
Over the past two decades, quantum optical memories with high fidelity, high efficiencies, long storage times, and promising multiplexing capabilities have been developed.
arXiv Detail & Related papers (2023-04-19T03:18:51Z) - Delegated variational quantum algorithms based on quantum homomorphic
encryption [69.50567607858659]
Variational quantum algorithms (VQAs) are one of the most promising candidates for achieving quantum advantages on quantum devices.
The private data of clients may be leaked to quantum servers in such a quantum cloud model.
A novel quantum homomorphic encryption (QHE) scheme is constructed for quantum servers to calculate encrypted data.
arXiv Detail & Related papers (2023-01-25T07:00:13Z) - Single-photon-memory measurement-device-independent quantum secure
direct communication [63.75763893884079]
Quantum secure direct communication (QSDC) uses the quantum channel to transmit information reliably and securely.
In order to eliminate the security loopholes resulting from practical detectors, the measurement-device-independent (MDI) QSDC protocol has been proposed.
We propose a single-photon-memory MDI QSDC protocol (SPMQC) for dispensing with high-performance quantum memory.
arXiv Detail & Related papers (2022-12-12T02:23:57Z) - Field-deployable Quantum Memory for Quantum Networking [62.72060057360206]
We present a quantum memory engineered to meet real-world deployment and scaling challenges.
The memory technology utilizes a warm rubidium vapor as the storage medium, and operates at room temperature.
We demonstrate performance specifications of high-fidelity retrieval (95%) and low operation error $(10-2)$ at a storage time of 160 $mu s$ for single-photon level quantum memory operations.
arXiv Detail & Related papers (2022-05-26T00:33:13Z) - Equivalence of Single-server and Multiple-servers Blind Quantum
Computation Protocols [0.0]
The protocol of delegating a calculation while hiding information about the calculation from the server is called sl blind quantum computation protocol.
There are no known single-server blind quantum computation protocols with a classical user and multiple-servers blind quantum computation protocols that allows servers to communicate freely with each other.
arXiv Detail & Related papers (2021-06-10T07:20:05Z) - Hardware-Efficient, Fault-Tolerant Quantum Computation with Rydberg
Atoms [55.41644538483948]
We provide the first complete characterization of sources of error in a neutral-atom quantum computer.
We develop a novel and distinctly efficient method to address the most important errors associated with the decay of atomic qubits to states outside of the computational subspace.
Our protocols can be implemented in the near-term using state-of-the-art neutral atom platforms with qubits encoded in both alkali and alkaline-earth atoms.
arXiv Detail & Related papers (2021-05-27T23:29:53Z) - Interleaving: Modular architectures for fault-tolerant photonic quantum
computing [50.591267188664666]
Photonic fusion-based quantum computing (FBQC) uses low-loss photonic delays.
We present a modular architecture for FBQC in which these components are combined to form "interleaving modules"
Exploiting the multiplicative power of delays, each module can add thousands of physical qubits to the computational Hilbert space.
arXiv Detail & Related papers (2021-03-15T18:00:06Z) - Delegating Multi-Party Quantum Computations vs. Dishonest Majority in
Two Quantum Rounds [0.0]
Multi-Party Quantum Computation (MPQC) has attracted a lot of attention as a potential killer-app for quantum networks.
We present a composable protocol achieving blindness and verifiability even in the case of a single honest client.
arXiv Detail & Related papers (2021-02-25T15:58:09Z) - Anti-Forging Quantum Data: Cryptographic Verification of Quantum
Computational Power [1.9737117321211988]
Quantum cloud computing is emerging as a popular model for users to experience the power of quantum computing through the internet.
How can users be sure that the output strings sent by the server are really from a quantum hardware?
arXiv Detail & Related papers (2020-05-04T14:28:14Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.