Direct measurement of Bacon-Shor code stabilizers

Li, Muyuan; Miller, Daniel; Brown, Kenneth R.

doi:10.1103/physreva.98.050301

Cited by 20 publications

(19 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To detect a single phase-flip error, we measure the X stabilizers X 1 X 2 X 3 X 4 X 5 X 6 and X 4 X 5 X 6 X 7 X 8 X 9 . These error detection measurements can be done in a non-destructive way by projecting the parity onto an ancilla qubit and measuring it without disturbing the code qubits [35]. In our experiment we directly perform the projective measurement on the physical qubits and perform the error detection or correction procedure in post-processing.…”

Section: The Shor Codementioning

confidence: 99%

Demonstration of Shor encoding on a trapped-ion quantum computer

Nguyen,

Li,

Green

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Fault-tolerant quantum error correction (QEC) is crucial for unlocking the true power of quantum computers. QEC codes use multiple physical qubits to encode a logical qubit, which is protected against errors at the physical qubit level. Here we use a trapped ion system to experimentally prepare m-qubit GHZ states and sample the measurement results to construct m × m logical states of the [[m 2 , 1, m]] Shor code, up to m = 7. The synthetic logical fidelity shows how deeper encoding can compensate for additional gate errors in state preparation for larger logical states. However, the optimal code size depends on the physical error rate and we find that m = 5 has the best performance in our system. We further realize the direct logical encoding of the [[9, 1, 3]] Shor code on nine qubits in a thirteen-ion chain for comparison, with 98.8(1)% and 98.5(1)% fidelity for state |± L , respectively.

show abstract

Section: The Shor Codementioning

confidence: 99%

Demonstration of Shor encoding on a trapped-ion quantum computer

Nguyen,

Li,

Green

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…We observe that combining unverified two-qubit cat state extraction with minimal leakage reduction yields an orders-of-magnitude improvement over existing fault-tolerant proposals [38], and also begins to relatively outperform non-fault-tolerant strategies in the 10 3 -⪅ error Figure 1. Syndrome extraction in a vertical distance 3 X-type Bacon-Shor stabilizer (shaded) using a single ancilla [65], with horizontal XX and vertical ZZ gauge operators. Implicit in the diagram is a Pauli X-error on the ancilla in (a), and a leaked ancilla in (b), both occurring after the third gate during extraction.…”

Section: Contributionsmentioning

confidence: 99%

Handling leakage with subsystem codes

2019

View full text Add to dashboard Cite

Leakage is a particularly damaging error that occurs when a qubit state falls out of its two-level computational subspace. Compared to independent depolarizing noise, leaked qubits may produce many more configurations of harmful correlated errors during error-correction. In this work, we investigate different local codes in the low-error regime of a leakage gate error model. When restricting to bare-ancilla extraction, we observe that subsystem codes are good candidates for handling leakage, as their locality can limit damaging correlated errors. As a case study, we compare subspace surface codes to the subsystem surface codes introduced by Bravyi et al. In contrast to depolarizing noise, subsystem surface codes outperform same-distance subspace surface codes below error rates as high as 7.5×10 −4 while offering better per-qubit distance protection. Furthermore, we show that at low to intermediate distances, Bacon-Shor codes offer better per-qubit error protection against leakage in an ion-trap motivated error model below error rates as high as 1.2×10 −3 . For restricted leakage models, this advantage can be extended to higher distances by relaxing to unverified two-qubit cat state extraction in the surface code. These results highlight an intrinsic benefit of subsystem code locality to error-corrective performance.

show abstract

“…The relaxed criterion, allowing errors to act on the gauge subsystem in the codespace, makes subsystem codes more powerful in some cases. Subsystem codes such as the Bacon-Shor code [16,17] require simpler syndrome measurements, leading to surprisingly good error correction performances [18][19][20]. Furthermore, it has been shown that under the locality constraint, subsystem codes can encode more information comparing to subspace codes [21].…”

Section: Introductionmentioning

confidence: 99%

Robust universal Hamiltonian quantum computing using two-body interactions

Marvian,

Lloyd

2019

Preprint

View full text Add to dashboard Cite

We present a new scheme to perform noise resilient universal adiabatic quantum computation using two-body interactions. To achieve this, we introduce a new family of error detecting subsystem codes whose gauge generators and a set of their logical operators -capable of encoding universal Hamiltonian computations -can be implemented using two-body interactions. Logical operators of the code are used to encode any given computational Hamiltonian, and the gauge operators are used to construct a penalty Hamiltonian whose ground subspace is protected against local-errors. In contrast to previous approaches, the constructed penalty Hamiltonian does not necessarily commute with the encoded computational Hamiltonians, but for our construction the undesirable effect of the penalty Hamiltonian on the computation can be compensated by a simple modification of the implemented Hamiltonians.We also investigate whether a similar scheme can be constructed by encoding the computational Hamiltonian using only bare-logical operators of subsystem codes, to guarantee that computational Hamiltonian commutes with the penalty Hamiltonian. We prove a no-go theorem showing that restricting to two-body interactions and using any general CSS-type subsystem codes, such a construction cannot encode systems beyond an Ising chain in a transverse field. We point out that such a chain is universal for Hamiltonian-based quantum computation, but it is not universal for ground-state quantum computation.

show abstract

Direct measurement of Bacon-Shor code stabilizers

Cited by 20 publications

References 40 publications

Demonstration of Shor encoding on a trapped-ion quantum computer

Demonstration of Shor encoding on a trapped-ion quantum computer

Handling leakage with subsystem codes

Robust universal Hamiltonian quantum computing using two-body interactions

Contact Info

Product

Resources

About