Trade-Offs on Number and Phase Shift Resilience in Bosonic Quantum Codes
- Creators
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Ouyang, Yingkai
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Campbell, Earl T.
Abstract
Quantum codes typically rely on large numbers of degrees of freedom to achieve low error rates. However each additional degree of freedom introduces a new set of error mechanisms. Hence minimizing the degrees of freedom that a quantum code utilizes is helpful. One quantum error correction solution is to encode quantum information into one or more bosonic modes. We revisit rotation-invariant bosonic codes, which are supported on Fock states that are gapped by an integer g apart, and the gap g imparts number shift resilience to these codes. Intuitively, since phase operators and number shift operators do not commute, one expects a trade-off between resilience to number-shift and rotation errors. Here, we obtain results pertaining to the non-existence of approximate quantum error correcting g-gapped single-mode bosonic codes with respect to Gaussian dephasing errors. We show that by using arbitrarily many modes, g-gapped multi-mode codes can yield good approximate quantum error correction codes for any finite magnitude of Gaussian dephasing and amplitude damping errors.
Additional Information
© 2021 IEEE. Manuscript received December 15, 2020; revised July 16, 2021; accepted July 23, 2021. Date of publication August 6, 2021; date of current version September 15, 2021. This work was supported by the QuantERA ERANET Cofund in Quantum Technologies through the European Union's Horizon 2020 Programme by the projects Engineering and Physical Sciences Research Council (EPSRC) and Quantum Code Design and Architectures (QCDA) under Grant EP/M024261/1 and Grant EP/R043825/1. The work of Yingkai Ouyang was supported in part by the National University of Singapore (NUS) startup under Grant R-263-000-E32-133 and Grant R-263-000-E32-731; in part by the National Research Foundation, Prime Minister's Office, Singapore; and in part by the Ministry of Education, Singapore, through the Research Centres of Excellence Programme. The authors are grateful to Robert Koenig, Lisa Hänggli, Margret Heinze, and Barbara Terhal for fruitful discussions. This work was completed while ETC was at the University of Sheffield.Attached Files
Accepted Version - 2008.12576.pdf
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Additional details
- Eprint ID
- 111583
- Resolver ID
- CaltechAUTHORS:20211021-200109590
- Engineering and Physical Sciences Research Council (EPSRC)
- EP/M024261/1
- Engineering and Physical Sciences Research Council (EPSRC)
- EP/R043825/1
- National University of Singapore
- R-263-000-E32-133
- National University of Singapore
- R-263-000-E32-731
- National Research Foundation (Singapore)
- Ministry of Education (Singapore)
- Created
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2021-10-22Created from EPrint's datestamp field
- Updated
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2021-10-26Created from EPrint's last_modified field
- Caltech groups
- AWS Center for Quantum Computing