51 research outputs found
Tailoring fusion-based error correction for high thresholds to biased fusion failures
We introduce fault-tolerant (FT) architectures for error correction with the
XZZX cluster state based on performing measurements of two-qubit Pauli
operators and , or fusions, on a collection of
few-body entangled resource states. Our construction is tailored to be
effective against noise that predominantly causes faulty
measurements during fusions. This feature offers practical advantage in linear
optical quantum computing with dual-rail photonic qubits, where failed fusions
only erase measurement outcomes. By applying our construction to
this platform, we find a record high FT threshold to fusion failures exceeding
in the experimentally relevant regime of non-zero loss rate per photon,
considerably simplifying hardware requirements.Comment: 7+6 pages, 4+6 figures, comments welcom
Study of noise in virtual distillation circuits for quantum error mitigation
Virtual distillation has been proposed as an error mitigation protocol for
estimating the expectation values of observables in quantum algorithms. It
proceeds by creating a cyclic permutation of noisy copies of a quantum
state using a sequence of controlled-swap gates. If the noise does not shift
the dominant eigenvector of the density operator away from the ideal state,
then the error in expectation-value estimation can be exponentially reduced
with . In practice, subsequent error-mitigation techniques are required to
suppress the effect of noise in the cyclic permutation circuit itself, leading
to increased experimental complexity. Here, we perform a careful analysis of
noise in the cyclic permutation circuit and find that the estimation of
expectation value of observables diagonal in the computational basis is robust
against dephasing noise. We support the analytical result with numerical
simulations and find that of errors are reduced for , with physical
dephasing error probabilities as high as . Our results imply that a broad
class of quantum algorithms can be implemented with higher accuracy in the
near-term with qubit platforms where non-dephasing errors are suppressed, such
as superconducting bosonic qubits and Rydberg atoms.Comment: 12 pages, 5 figure
Mitigating Temporal Fragility in the XY Surface Code
An important outstanding challenge that must be overcome in order to fully
utilize the XY surface code for correcting biased Pauli noise is the phenomena
of fragile temporal boundaries that arise during the standard logical state
preparation and measurement protocols. To address this challenge we propose a
new logical state preparation protocol based on locally entangling qubits into
small Greenberger-Horne-Zeilinger-like states prior to making the stabilizer
measurements that place them in the XY-code state. We prove that in this new
procedure high-rate errors along a single lattice boundary can
cause a logical failure, leading to an almost quadratic reduction in the number
of fault-configurations compared to the standard state-preparation approach.
Moreover, the code becomes equivalent to a repetition code for high-rate
errors, guaranteeing a 50% code-capacity threshold during state preparation for
infinitely biased noise. With a simple matching decoder we confirm that our
preparation protocol outperforms the standard one in terms of both threshold
and logical error rate in the fault-tolerant regime where measurements are
unreliable and at experimentally realistic biases. We also discuss how our
state-preparation protocol can be inverted for similar
fragile-boundary-mitigated logical-state measurement.Comment: 9 pages, 9 figure
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