Daniel Miller scite author profile

The compass model on a square lattice provides a natural template for building subsystem stabilizer codes. The surface code and the Bacon-Shor code represent two extremes of possible codes depending on how many gauge qubits are fixed. We explore threshold behavior in this broad class of local codes by trading locality for asymmetry and gauge degrees of freedom for stabilizer syndrome information. We analyze these codes with asymmetric and spatially inhomogeneous Pauli noise in the code capacity and phenomenological models. In these idealized settings, we observe considerably higher thresholds against asymmetric noise. At the circuit level, these codes inherit the bare-ancilla fault-tolerance of the Bacon-Shor code. arXiv:1809.01193v2 [quant-ph]

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Propagation of generalized Pauli errors in qudit Clifford circuits

Miller

Holz

Kampermann

et al. 2018

Phys. Rev. A

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It is important for performance studies in quantum technologies to analyze quantum circuits in the presence of noise. We introduce an error probability tensor, a tool to track generalized Pauli error statistics of qudits within quantum circuits composed of qudit Clifford gates. Our framework is compatible with qudit stabilizer quantum error-correcting codes. We show how the error probability tensor can be applied in the most general case, and we demonstrate an error analysis of bipartite qudit repeaters with quantum error correction. We provide an exact analytical solution of the error statistics of the state distributed by such a repeater. For a fixed number of degrees of freedom, we observe that higher-dimensional qudits can outperform qubits in terms of distributed entanglement. arXiv:1807.06030v1 [quant-ph]

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Direct measurement of Bacon-Shor code stabilizers

Miller

Brown

2018

Phys. Rev. A

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A Bacon-Shor code is a subsystem quantum error-correcting code on an L × L lattice where the 2(L − 1) weight-2L stabilizers are usually inferred from the measurements of (L − 1) 2 weight-2 gauge operators. Here we show that the stabilizers can be measured directly and fault tolerantly with bare ancillary qubits by constructing circuits that follow the pattern of gauge operators. We then examine the implications of this method for small quantum error-correcting codes by comparing distance 3 versions of the rotated surface code and the Bacon-Shor code with the standard depolarizing model and in the context of a trapped ion quantum computer. We find that for a simple circuit of prepare, error correct and measure the Bacon-Shor code outperforms the surface code by requiring fewer qubits, taking less time, and having a lower error rate.Quantum information experiments are approaching the number of qubits and operational fidelity necessary for quantum error correction to improve performance [1][2][3]. Classical error correction on quantum devices have already shown the ability to suppress introduced errors and increase memory times [4][5][6][7][8]. Two promising quantum error-correcting codes for data qubits arranged on an L × L lattice are the surface code [9-11] and the Bacon-Shor code [12][13][14]. Numerical simulation of the surface code shows a high memory threshold of 1% error per operation for increasing L and for distance 3 codes a pseudothreshold of 0.3% error per operation for a depolarizing error model [11]. The Bacon-Shor code is a subsystem code and has no threshold as L grows [15] but promising performance for small distance codes with a pseudothreshold of 0.2% for a depolarizing error model [14] and a fault-tolerant protocol for implementing universal gates without distillation [16]. The rotated surface code has L 2 − 1 check operators of weight 4 in the bulk and weight 2 on the boundary [10]. The advantage of the Bacon-Shor code comes from using weight-2 gauge operators to determine the weight 2L check operators and the lack of threshold is a result of having only 2(L−1) checks [12,14,15].For the [[9,1,3]] surface code, Tomita and Svore [11] pointed out that in the circuit model, the order in which the weight 4 check operators are measured prevents unwanted error propagation and allows for parallelization of operations. For Bacon-Shor, the idea has always been to measure gauge operators because direct measurements of the stabilizers would require long-range interaction between qubits and higher-weight stabilizers usually require more complicated ancillary qubit preparation [17][18][19][20]. Inspired by Tomita and Svore and the fact that both the surface code and the Bacon-Shor code can be thought as gauge choices on the compass model, we found that * ken.brown@duke.edu Bacon-Shor codes can be measured with bare ancillary qubits.In condensed matter physics the compass model is used to describe a family of lattice models involving interacting quantum degrees of freedom [21]. The relationship between compas...

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Comment on “Fully device-independent conference key agreement”

et al. 2019

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GraphStateVis: Interactive Visual Analysis of Qubit Graph States and their Stabilizer Groups

Miller

2021

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Daniel Miller

2D Compass Codes

Propagation of generalized Pauli errors in qudit Clifford circuits

Direct measurement of Bacon-Shor code stabilizers

Comment on “Fully device-independent conference key agreement”

GraphStateVis: Interactive Visual Analysis of Qubit Graph States and their Stabilizer Groups

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