Exponential suppression of bit or phase errors with cyclic error correction

Chen, Zijun; Satzinger, Kevin J.; Atalaya, Juan; Korotkov, Alexander N.; Dunsworth, A.; Sank, D.; Quintana, Chris; McEwen, Matt; Barends, R.; Klimov, Paul V.; Hong, Sabrina; Jones, Cody; Petukhov, A.; Kafri, Dvir; Demura, Sean; Burkett, Brian; Gidney, Craig; Fowler, Austin G.; Paler, Alexandru; Putterman, Harald; Aleǐner, I. L.; Arute, Frank; Arya, Kunal; Babbush, Ryan; Bardin, Joseph C.; Bengtsson, Andreas; Bourassa, Alexandre; Broughton, Michael; Buckley, Bob B.; Buell, David A.; Bushnell, Nicholas; Chiaro, Benjamin; Collins, Roberto; Courtney, William; Derk, Alan R.; Eppens, Daniel; Erickson, Catherine; Farhi, Edward; Foxen, Brooks; Giustina, Marissa; Greene, Amy; Gross, Jonathan A.; Harrigan, Matthew P.; Harrington, Sean D.; Hilton, Jeremy; Ho, Alan; Huang, Trent; Huggins, William J.; Ioffe, L. B.; Isakov, Sergei V.; Jeffrey, E.; Zhang, Jiang; Kechedzhi, Kostyantyn; Kim, Seon; Kitaev, Alexei; Kostritsa, Fedor; Landhuis, David; Laptev, Pavel; Lucero, Erik; Martin, Orion; McClean, Jarrod R.; McCourt, Trevor; Mi, Xiao; Miao, Kevin C.; Mohseni, Masoud; Montazeri, Shirin; Mruczkiewicz, Wojciech; Mutus, J.; Naaman, Ofer; Neeley, M.; Neill, C.; Newman, Michael; Niu, Murphy Yuezhen; O’Brien, Thomas E.; Opremcak, Alex; Ostby, Eric; Pató, Bálint; Redd, Nicholas; Roushan, P.; Rubin, Nicholas C.; Shvarts, Vladimir; Strain, Doug; Szalay, Marco; Trevithick, Matthew D.; Villalonga, Benjamin; White, Theodore C.; Yao, Z. Jamie; Yeh, P.; Yoo, Juhwan; Zalcman, Adam; Neven, Hartmut; Boixo, Sergio; Smelyanskiy, Vadim; Chen, Yu; Megrant, A.; Kelly, J.

doi:10.1038/s41586-021-03588-y

Cited by 222 publications

(119 citation statements)

References 36 publications

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“…First, p and q both are typically dominated by similar error processes that for many qubit platforms are of comparable error rates, hence we set p = q for simplicity, and additionally, we dial up the strength of r. The known case r = 0 reduces to the phenomenological case without correlated errors, which would correspond to perfect two-qubit gates (p 2 = 0). Increasing r to r = p/2 = q/2 corresponds to p 2 = 5p 1 + O(p 2 1 ), which is roughly compatible with the two-qubit gate being an order of magnitude worse than single-qubit operations (error rate or infidelity) as observed in many experimental realizations [36,40,55,63]. Considering r = p = q corresponds to p 2 being dominant and all other error sources negligible (p sp = p id = p 1 = p m = 0).…”

Section: Discussionsupporting

confidence: 71%

“…Interestingly, in a recent experimental realization of the phase-flip code [55] circuit errors are reported to be well described by Pauli errors. Casting the experimentally obtained error rates into Eq.…”

Section: Discussionmentioning

confidence: 99%

“…We illustrate the mapping of circuit-level QEC codes to statistical mechanics models for a 1D quantum repetition code with faulty circuitry described by a multi-parameter microscopic noise model accounting for a number of single-and two-qubit gate noise processes. Whereas this code does not enable correction of arbitrary errors, current experimental efforts focus on achieving repetitive QEC with this code in the regime of beneficial error suppression for increasing code sizes [52][53][54][55]. We show that in contrast to oversimplified phenomenological noise models, new effective correlated noise processes arise, which we systematically derive and quantitatively relate to error rates of the underlying microscopic noise model.…”

mentioning

confidence: 93%

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Fundamental thresholds of realistic quantum error correction circuits from classical spin models

Vodola

Rispler

Kim³

et al. 2022

Quantum

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Mapping the decoding of quantum error correcting (QEC) codes to classical disordered statistical mechanics models allows one to determine critical error thresholds of QEC codes under phenomenological noise models. Here, we extend this mapping to admit realistic, multi-parameter noise models of faulty QEC circuits, derive the associated strongly correlated classical spin models, and illustrate this approach for a quantum repetition code with faulty stabilizer readout circuits. We use Monte-Carlo simulations to study the resulting phase diagram and benchmark our results against a minimum-weight perfect matching decoder. The presented method provides an avenue to assess fundamental thresholds of QEC circuits, independent of specific decoding strategies, and can thereby help guiding the development of near-term QEC hardware.

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Section: Discussionsupporting

confidence: 71%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 93%

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Fundamental thresholds of realistic quantum error correction circuits from classical spin models

Vodola

Rispler

Kim³

et al. 2022

Quantum

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“…Then it has been clarified that nonlinear errors give serious degradations of the capability of quantum computer, by the recurrence effect due to quantum correlation and also by collective decoherence . In order to cope with the quantum errors described in this paper, or to avoid this situation, one method is to further develop the conventional quantum error correction theory based on quantum noise analysis, or to establish a new way to physically suppress such errors [ 32 , 33 , 34 ]. Recently, a number of previously unknown and extremely difficult challenges in the development of an error correctable quantum computer have been reported [ 35 , 36 , 37 , 38 ].…”

Section: Discussionmentioning

confidence: 99%

Introduction to Semi-Classical Analysis for Digital Errors of Qubit in Quantum Processor

Hirota

2021

Entropy

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In recent years, remarkable progress has been achieved in the development of quantum computers. For further development, it is important to clarify properties of errors by quantum noise and environment noise. However, when the system scale of quantum processors is expanded, it has been pointed out that a new type of quantum error, such as nonlinear error, appears. It is not clear how to handle such new effects in information theory. First of all, one should make the characteristics of the error probability of qubits clear as communication channel error models in information theory. The purpose of this paper is to survey the progress for modeling the quantum noise effects that information theorists are likely to face in the future, to cope with such nontrivial errors mentioned above. This paper explains a channel error model to represent strange properties of error probability due to new quantum noise. By this model, specific examples on the features of error probability caused by, for example, quantum recurrence effects, collective relaxation, and external force, are given. As a result, it is possible to understand the meaning of strange features of error probability that do not exist in classical information theory without going through complex physical phenomena.

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“…In recent years, several preliminary QEC experiments involving repetition codes and Bacon-Shor codes have been successfully demonstrated [6,17,18,27,48,51,65,68,70,84,86,87,89]. However, reaching low logical error rates requires implementation of more Figure 1: (a) In QEC, a logical qubit is encoded using a set of data and parity qubits.…”

Section: Introductionmentioning

confidence: 99%

LILLIPUT: a lightweight low-latency lookup-table decoder for near-term Quantum error correction

Das

Locharla

Jones

2022

Proceedings of the 27th ACM International Conference on Architectural Support for Programming Languages and Operating Systems

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The error rates of quantum devices are orders of magnitude higher than what is needed to run most quantum applications. To close this gap, Quantum Error Correction (QEC) encodes logical qubits and distributes information using several physical qubits. By periodically executing a syndrome extraction circuit on the logical qubits, information about errors (called syndrome) is extracted while running programs. A decoder uses these syndromes to identify and correct errors in real time, which is necessary to prevent accumulation of errors. Unfortunately, software decoders are slow and hardware decoders are fast but less accurate. Thus, almost all QEC studies so far have relied on offline decoding.To enable real-time decoding in near-term QEC, we propose LILLIPUT-a Lightweight Low Latency Look-Up Table decoder. LILLIPUT consists of two parts-First, it translates syndromes into error detection events that index into a Look-Up Table (LUT) whose entry provides the error information in real-time. Second, it programs the LUTs with error assignments for all possible error events by running a software decoder offline. LILLIPUT tolerates an error on any operation in the quantum hardware, including gates and measurements, and the number of tolerated errors grows with the size of the code. LILLIPUT utilizes less than 7% logic on off-the-shelf FPGAs enabling practical adoption, as FPGAs are already used to design the control and readout circuits in existing systems. LIL-LIPUT incurs a latency of a few nanoseconds and enables real-time decoding. We also propose Compressed LUTs (CLUTs) to reduce the memory required by LILLIPUT. By exploiting the fact that not all error events are equally likely and only storing data for the most probable error events, CLUTs reduce the memory needed by up-to 107x (from 148 MB to 1.38 MB) without degrading the accuracy. CCS CONCEPTS• Hardware → Quantum technologies; • Computer systems organization → Quantum computing.

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Exponential suppression of bit or phase errors with cyclic error correction

Cited by 222 publications

References 36 publications

Fundamental thresholds of realistic quantum error correction circuits from classical spin models

Fundamental thresholds of realistic quantum error correction circuits from classical spin models

Introduction to Semi-Classical Analysis for Digital Errors of Qubit in Quantum Processor

LILLIPUT: a lightweight low-latency lookup-table decoder for near-term Quantum error correction

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