2019
DOI: 10.1088/1367-2630/ab0199
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Code deformation and lattice surgery are gauge fixing

Abstract: The large-scale execution of quantum algorithms requires basic quantum operations to be implemented fault-tolerantly. The most popular technique for accomplishing this, using the devices that can be realized in the near term, uses stabilizer codes which can be embedded in a planar layout. The set of fault-tolerant operations which can be executed in these systems using unitary gates is typically very limited. This has driven the development of measurement-based schemes for performing logical operations in thes… Show more

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Cited by 50 publications
(55 citation statements)
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“…We also show how to choose the cluster state and the measurement pattern such that we implement logical operations on the encoded stabilizer code. We accomplish logical operations using a specially chosen quantum measurements to perform code deformations [44,47,[53][54][55][56][57]. We show that we can encode code deformations within a resource state such that after we measure most of its qubits, the remaining unmeasured qubits of the resource state lie in the state of the deformed stabilizer code, thereby completing a fault-tolerant operation.…”
Section: Introductionmentioning
confidence: 99%
“…We also show how to choose the cluster state and the measurement pattern such that we implement logical operations on the encoded stabilizer code. We accomplish logical operations using a specially chosen quantum measurements to perform code deformations [44,47,[53][54][55][56][57]. We show that we can encode code deformations within a resource state such that after we measure most of its qubits, the remaining unmeasured qubits of the resource state lie in the state of the deformed stabilizer code, thereby completing a fault-tolerant operation.…”
Section: Introductionmentioning
confidence: 99%
“…5 and 7 (the w-flag circuits described in [23] could also be used for higher distance color codes), encoded magic states with logical failure rates of O(p 2 ) and O(p 3 ) can be produced. Lattice surgery techniques could then be performed to further distill the input magic states [40,41]. We note that the state injec-tion scheme in [29] produces encoded magic states with logical failure rate O(p) and thus for low enough physical error rates, our approach could achieve lower logical failure rates.…”
Section: Resultsmentioning
confidence: 99%
“…In this case the matrices G and H have 2N columns each, where N is the number of circuit locations, and their ranks are given by Eqs. (12) and (14). Just as any circuit error can be pushed all the way to the right, row-reduction can also be done starting with the bits at the beginning of the circuit and pushing toward its output.…”
Section: Marginal Distribution For Output Errors In a Good Measurementioning
confidence: 99%
“…However, such a scheme is limited to codes and measurement circuits where MWPM can be done efficiently, e.g., surface codes with single-ancilla measurement circuits [9], and certain other classes or topological codes [10,11]. Further, there is necessarily a decoding accuracy loss when measurement circuit is not simply repeated, e.g., with code deformation or lattice surgery [12].…”
Section: Introductionmentioning
confidence: 99%
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