Related papers: Dynamical Logical Qubits in the Bacon-Shor Code

Dynamical Logical Qubits in the Bacon-Shor Code

URL: http://arxiv.org/abs/2403.03291v2
Date: Mon, 02 Dec 2024 21:22:15 GMT
Title: Dynamical Logical Qubits in the Bacon-Shor Code
Authors: M. Sohaib Alam, Eleanor Rieffel,
Abstract summary: Bacon-Shor code is a quantum error correcting subsystem code composed of weight 2 check operators. We show that when viewed as a Floquet code, it can additionally host several dynamical logical qubits.
Score: 0.0
License:
Abstract: The Bacon-Shor code is a quantum error correcting subsystem code composed of weight 2 check operators that admits a single logical qubit, and has distance $d$ on a $d \times d$ square lattice. We show that when viewed as a Floquet code, by choosing an appropriate measurement schedule of the check operators, it can additionally host several dynamical logical qubits. Specifically, we identify a period 4 measurement schedule of the check operators that preserves logical information between the instantaneous stabilizer groups. Such a schedule measures not only the usual stabilizers of the Bacon-Shor code, but also additional stabilizers that protect the dynamical logical qubits against errors. We show that the code distance of these Floquet-Bacon-Shor codes scales as $\Theta(d/\sqrt{k})$ on an $n = d \times d$ lattice with $k$ dynamical logical qubits, along with the logical qubit of the parent subsystem code. Unlike the usual Bacon-Shor code, the Floquet-Bacon-Shor code family introduced here can therefore saturate the subsystem bound $kd = O(n)$. Moreover, several errors are shown to be self-corrected purely by the measurement schedule itself. This work provides insights into the design space for dynamical codes and expands the known approaches for constructing Floquet codes.

Related papers

Demonstrating dynamic surface codes [138.1740645504286]
We experimentally demonstrate three time-dynamic implementations of the surface code. First, we embed the surface code on a hexagonal lattice, reducing the necessary couplings per qubit from four to three. Second, we walk a surface code, swapping the role of data and measure qubits each round, achieving error correction with built-in removal of accumulated non-computational errors. Third, we realize the surface code using iSWAP gates instead of the traditional CNOT, extending the set of viable gates for error correction without additional overhead.
arXiv Detail & Related papers (2024-12-18T21:56:50Z)
Quantum error correction below the surface code threshold [107.92016014248976]
Quantum error correction provides a path to reach practical quantum computing by combining multiple physical qubits into a logical qubit. We present two surface code memories operating below a critical threshold: a distance-7 code and a distance-5 code integrated with a real-time decoder. Our results present device performance that, if scaled, could realize the operational requirements of large scale fault-tolerant quantum algorithms.
arXiv Detail & Related papers (2024-08-24T23:08:50Z)
High-threshold, low-overhead and single-shot decodable fault-tolerant quantum memory [0.6144680854063939]
We present a new family of quantum low-density parity-check codes, which we call radial codes. In simulations of circuit-level noise, we observe comparable error suppression to surface codes of similar distance. Their error correction capabilities, tunable parameters and small size make them promising candidates for implementation on near-term quantum devices.
arXiv Detail & Related papers (2024-06-20T16:08:06Z)
GNarsil: Splitting Stabilizers into Gauges [2.1485350418225244]
We present two algorithms that produce new subsystem codes from a "seed" CSS code. They replace some stabilizers of a given CSS code with smaller-weight gauge operators that split the remaining stabilizers, while being compatible with the logical Pauli operators of the code.
arXiv Detail & Related papers (2024-04-28T20:08:01Z)
Creating entangled logical qubits in the heavy-hex lattice with topological codes [0.0]
In this work we show how this bug can be turned into a feature. We demonstrate entanglement between logical qubits with code distance up to $d = 4$. We verify the violation of Bell's inequality for both the $d=2$ case with post selection featuring a fidelity of $94%$.
arXiv Detail & Related papers (2024-04-24T17:02:35Z)
Fault-tolerant hyperbolic Floquet quantum error correcting codes [0.0]
We introduce a family of dynamically generated quantum error correcting codes that we call "hyperbolic Floquet codes" One of our hyperbolic Floquet codes uses 400 physical qubits to encode 52 logical qubits with a code distance of 8, i.e., it is a $[[400,52,8]]$ code. At small error rates, comparable logical error suppression to this code requires 5x as many physical qubits (1924) when using the honeycomb Floquet code with the same noise model and decoder.
arXiv Detail & Related papers (2023-09-18T18:00:02Z)
Fault-Tolerant Computing with Single Qudit Encoding [49.89725935672549]
We discuss stabilizer quantum-error correction codes implemented in a single multi-level qudit. These codes can be customized to the specific physical errors on the qudit, effectively suppressing them. We demonstrate a Fault-Tolerant implementation on molecular spin qudits, showcasing nearly exponential error suppression with only linear qudit size growth.
arXiv Detail & Related papers (2023-07-20T10:51:23Z)
Homological Quantum Rotor Codes: Logical Qubits from Torsion [47.52324012811181]
homological quantum rotor codes allow one to encode both logical rotors and logical qudits in the same block of code. We show that the $0$-$pi$-qubit as well as Kitaev's current-mirror qubit are indeed small examples of such codes.
arXiv Detail & Related papers (2023-03-24T00:29:15Z)
Suppressing quantum errors by scaling a surface code logical qubit [147.2624260358795]
We report the measurement of logical qubit performance scaling across multiple code sizes. Our system of superconducting qubits has sufficient performance to overcome the additional errors from increasing qubit number. Results mark the first experimental demonstration where quantum error correction begins to improve performance with increasing qubit number.
arXiv Detail & Related papers (2022-07-13T18:00:02Z)
Planar Floquet Codes [0.0]
The honeycomb code is a subsystem code based on the honeycomb lattice with zero logical qubits. In this work we show a way to introduce boundaries to the system which curiously presents a rotating dynamics but has constant distance and is therefore not fault-tolerant.
arXiv Detail & Related papers (2021-10-11T15:21:35Z)
Relaxation times do not capture logical qubit dynamics [50.04886706729045]
We show that spatial noise correlations can give rise to rich and counter-intuitive dynamical behavior of logical qubits. This work will help to guide and benchmark experimental implementations of logical qubits.
arXiv Detail & Related papers (2020-12-14T19:51:19Z)

This list is automatically generated from the titles and abstracts of the papers in this site.