Quantum serial turbo-codes

Poulin, David; Tillich, Jean–Pierre; Ollivier, H

doi:10.1109/isit.2008.4594998

Cited by 19 publications

(74 citation statements)

References 38 publications

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“…The techniques developed in this article represent a useful way for encoding quantum information. The next step should be to combine the theory in this article with Poulin et al's recent theory of quantum serial-turbo coding [20].…”

Section: Conclusion and Current Workmentioning

confidence: 99%

“…Quantum convolutional coding theory combined with other coding techniques may be one step along the way to finding quantum error-correcting codes that approach the capacity of a noisy quantum communication channel for sending quantum information [13,14,15,16,17,18,19]. Poulin et al have recently incorporated some of this well-developed theory of quantum convolutional coding into a theory of quantum serial-turbo coding [20] with the goal of designing quantum codes that come close to achieving capacity.…”

Section: Introductionmentioning

confidence: 99%

“…An important practical issue in the design of entanglement-assisted quantum convolutional codes is the characterization of performance in terms of some parameter like code distance or distance spectrum [20]. The focus of this paper is on the construction and design of encoding and decoding circuits for non-CSS entanglement-assisted quantum convolutional codes-not on the performance of these codes.…”

Section: Introductionmentioning

confidence: 99%

“…We take this approach because entanglement-assisted codes produced from classical codes inherit distance and error-correcting properties from the parent classical codes. If the entanglement-assisted code does not come from a classical code, then one can analyze distance of the code in the standard way as the minimum weight element of the normalizer modulo the stabilizer [22] or with the distance spectrum parameter of Poulin et al [20], but an analysis of this sort is beyond the scope of the present paper.…”

Section: Introductionmentioning

confidence: 99%

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Quantum convolutional coding with shared entanglement: general structure

Wilde

Brun

2010

Quantum Inf Process

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We present a general theory of entanglement-assisted quantum convolutional coding. The codes have a convolutional or memory structure, they assume that the sender and receiver share noiseless entanglement prior to quantum communication, and they are not restricted to possess the CalderbankShor-Steane structure as in previous work. We provide two significant advances for quantum convolutional coding theory. We first show how to "expand" a given set of quantum convolutional generators. This expansion step acts as a preprocessor for a polynomial symplectic Gram-Schmidt orthogonalization procedure that simplifies the commutation relations of the expanded generators to be the same as those of entangled Bell states (ebits) and ancilla qubits. The above two steps produce a set of generators with equivalent error-correcting properties to those of the original generators. We then demonstrate how to perform online encoding and decoding for a stream of information qubits, halves of ebits, and ancilla qubits. The upshot of our theory is that the quantum code designer can engineer quantum convolutional codes with desirable error-correcting properties without having to worry about the commutation relations of these generators.

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Section: Conclusion and Current Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Quantum convolutional coding with shared entanglement: general structure

Wilde

Brun

2010

Quantum Inf Process

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“…Quantum error-correcting codes (QECCs) have become the most efficient way to combat decoherence [4]. However, QECCs are rather costly in quantum computing resources [5]. To protect a single quantum bit (qubit) of information from suffering general singlequbit errors, at least five qubits are needed [6].…”

Section: Introductionmentioning

confidence: 99%

New construction of quantum error-avoiding codes via group representation of quantum stabilizer codes

2017

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In quantum computing, nice error bases as generalization of the Pauli basis were introduced by Knill. These bases are known to be projective representations of finite groups. In this paper, we propose a group representation approach to the study of quantum stabilizer codes. We utilize this approach to define decoherence-free subspaces (DFSs). Unlike previous studies of DFSs, this type of DFSs does not involve any spatial symmetry assumptions on the systemenvironment interaction. Thus, it can be used to construct quantum error-avoiding codes (QEACs) that are fault tolerant automatically. We also propose a new simple construction of QEACs and subsequently develop several classes of QEACs. Finally, we present numerical simulation results encoding the logical error rate over physical error rate on the fidelity performance of these QEACs. Our study demonstrates that DFSs-based QEACs are capable of providing a generalized and unified framework for error-avoiding methods.

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The XZZX surface code

et al. 2021

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Performing large calculations with a quantum computer will likely require a fault-tolerant architecture based on quantum error-correcting codes. The challenge is to design practical quantum error-correcting codes that perform well against realistic noise using modest resources. Here we show that a variant of the surface code—the XZZX code—offers remarkable performance for fault-tolerant quantum computation. The error threshold of this code matches what can be achieved with random codes (hashing) for every single-qubit Pauli noise channel; it is the first explicit code shown to have this universal property. We present numerical evidence that the threshold even exceeds this hashing bound for an experimentally relevant range of noise parameters. Focusing on the common situation where qubit dephasing is the dominant noise, we show that this code has a practical, high-performance decoder and surpasses all previously known thresholds in the realistic setting where syndrome measurements are unreliable. We go on to demonstrate the favourable sub-threshold resource scaling that can be obtained by specialising a code to exploit structure in the noise. We show that it is possible to maintain all of these advantages when we perform fault-tolerant quantum computation.

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Quantum serial turbo-codes

Cited by 19 publications

References 38 publications

Quantum convolutional coding with shared entanglement: general structure

Quantum convolutional coding with shared entanglement: general structure

New construction of quantum error-avoiding codes via group representation of quantum stabilizer codes

The XZZX surface code

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