Related papers: Fault-tolerant Coding for Quantum Communication

Fault-tolerant Coding for Quantum Communication

URL: http://arxiv.org/abs/2009.07161v2
Date: Tue, 22 Feb 2022 08:52:48 GMT
Title: Fault-tolerant Coding for Quantum Communication
Authors: Matthias Christandl, Alexander M\"uller-Hermes
Abstract summary: encode and decode circuits to reliably send messages over many uses of a noisy channel. For every quantum channel $T$ and every $eps>0$ there exists a threshold $p(epsilon,T)$ for the gate error probability below which rates larger than $C-epsilon$ are fault-tolerantly achievable. Our results are relevant in communication over large distances, and also on-chip, where distant parts of a quantum computer might need to communicate under higher levels of noise.
Score: 71.206200318454
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Designing encoding and decoding circuits to reliably send messages over many uses of a noisy channel is a central problem in communication theory. When studying the optimal transmission rates achievable with asymptotically vanishing error it is usually assumed that these circuits can be implemented using noise-free gates. While this assumption is satisfied for classical machines in many scenarios, it is not expected to be satisfied in the near term future for quantum machines where decoherence leads to faults in the quantum gates. As a result, fundamental questions regarding the practical relevance of quantum channel coding remain open. By combining techniques from fault-tolerant quantum computation with techniques from quantum communication, we initiate the study of these questions. We introduce fault-tolerant versions of quantum capacities quantifying the optimal communication rates achievable with asymptotically vanishing total error when the encoding and decoding circuits are affected by gate errors with small probability. Our main results are threshold theorems for the classical and quantum capacity: For every quantum channel $T$ and every $\epsilon>0$ there exists a threshold $p(\epsilon,T)$ for the gate error probability below which rates larger than $C-\epsilon$ are fault-tolerantly achievable with vanishing overall communication error, where $C$ denotes the usual capacity. Our results are not only relevant in communication over large distances, but also on-chip, where distant parts of a quantum computer might need to communicate under higher levels of noise than affecting the local gates.

Related papers

Fault-tolerant quantum input/output [6.787248655856051]
We show that any quantum circuit with quantum input and output can be transformed into a fault-tolerant circuit. The framework allows the direct composition of the statements, enabling versatile future applications.
arXiv Detail & Related papers (2024-08-09T12:26:38Z)
Quantum process tomography of continuous-variable gates using coherent states [49.299443295581064]
We demonstrate the use of coherent-state quantum process tomography (csQPT) for a bosonic-mode superconducting circuit. We show results for this method by characterizing a logical quantum gate constructed using displacement and SNAP operations on an encoded qubit.
arXiv Detail & Related papers (2023-03-02T18:08:08Z)
Deep Quantum Error Correction [73.54643419792453]
Quantum error correction codes (QECC) are a key component for realizing the potential of quantum computing. In this work, we efficiently train novel emphend-to-end deep quantum error decoders. The proposed method demonstrates the power of neural decoders for QECC by achieving state-of-the-art accuracy.
arXiv Detail & Related papers (2023-01-27T08:16:26Z)
Averaging gate approximation error and performance of Unitary Coupled Cluster ansatz in Pre-FTQC Era [0.0]
Fault-tolerant quantum computation (FTQC) is essential to implement quantum algorithms in a noise-resilient way. In FTQC, a quantum circuit is decomposed into universal gates that can be fault-tolerantly implemented. In this paper, we propose that the Clifford+$T$ decomposition error for a given quantum circuit can be modeled as the depolarizing noise.
arXiv Detail & Related papers (2023-01-10T19:00:01Z)
Fault-tolerant Coding for Entanglement-Assisted Communication [46.0607942851373]
This paper studies the study of fault-tolerant channel coding for quantum channels. We use techniques from fault-tolerant quantum computing to establish coding theorems for sending classical and quantum information in this scenario. We extend these methods to the case of entanglement-assisted communication, in particular proving that the fault-tolerant capacity approaches the usual capacity when the gate error approaches zero.
arXiv Detail & Related papers (2022-10-06T14:09:16Z)
Fault-tolerant circuit synthesis for universal fault-tolerant quantum computing [0.0]
We present a quantum circuit synthesis algorithm for implementing universal fault-tolerant quantum computing based on geometricd codes. We show how to synthesize the set of universal fault-tolerant protocols for $[[7,1,3]]$ Steane code and the syndrome measurement protocol of $[[23, 1, 7]]$ Golay code.
arXiv Detail & Related papers (2022-06-06T15:43:36Z)
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)
Direct Quantum Communications in the Presence of Realistic Noisy Entanglement [69.25543534545538]
We propose a novel quantum communication scheme relying on realistic noisy pre-shared entanglement. Our performance analysis shows that the proposed scheme offers competitive QBER, yield, and goodput.
arXiv Detail & Related papers (2020-12-22T13:06:12Z)
Two-way covert quantum communication in the microwave regime [0.0]
Quantum communication addresses the problem of exchanging information across macroscopic distances. We advance a new paradigm for secure quantum communication by combining backscattering concepts with covert communication in the microwave regime. This work makes a decisive step toward implementing secure quantum communication concepts in the previously uncharted $1$-$10$ GHz frequency range.
arXiv Detail & Related papers (2020-04-15T16:36:59Z)

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.