Good approximate quantum LDPC codes from spacetime circuit Hamiltonians

Bohdanowicz, Thomas C.; Crosson, Elizabeth; Nirkhe, Chinmay; Yuen, Henry

doi:10.1145/3313276.3316384

Cited by 10 publications

(12 citation statements)

References 38 publications

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“…Therefore, it is worthwhile to explore whether such approaches can be used to generate codes that have special properties in encoding/decoding, error detection and correction. It is also interesting to establish connections with existing codes that are somewhat graphical in nature, such as low-density parity-check codes and variants [96][97][98].…”

Section: Code Properties and The Tensor Network Approachmentioning

confidence: 99%

Approximate Bacon-Shor code and holography

Cao

Lackey

2021

J. High Energ. Phys.

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We explicitly construct a class of holographic quantum error correction codes with non-trivial centers in the code subalgebra. Specifically, we use the Bacon-Shor codes and perfect tensors to construct a gauge code (or a stabilizer code with gauge-fixing), which we call the holographic hybrid code. This code admits a local log-depth encoding/decoding circuit, and can be represented as a holographic tensor network which satisfies an analog of the Ryu-Takayanagi formula and reproduces features of the sub-region duality. We then construct approximate versions of the holographic hybrid codes by “skewing” the code subspace, where the size of skewing is analogous to the size of the gravitational constant in holography. These approximate hybrid codes are not necessarily stabilizer codes, but they can be expressed as the superposition of holographic tensor networks that are stabilizer codes. For such constructions, different logical states, representing different bulk matter content, can “back-react” on the emergent geometry, resembling a key feature of gravity. The locality of the bulk degrees of freedom becomes subspace-dependent and approximate. Such subspace-dependence is manifest from the point of view of the “entanglement wedge” and bulk operator reconstruction from the boundary. Exact complementary error correction breaks down for certain bipartition of the boundary degrees of freedom; however, a limited, state-dependent form is preserved for particular subspaces. We also construct an example where the connected two-point correlation functions can have a power-law decay. Coupled with known constraints from holography, a weakly back-reacting bulk also forces these skewed tensor network models to the “large N limit” where they are built by concatenating a large N number of copies.

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Section: Code Properties and The Tensor Network Approachmentioning

confidence: 99%

Approximate Bacon-Shor code and holography

Cao

Lackey

2021

J. High Energ. Phys.

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“…where δS = {{u, v} ∈ X 1 | u ∈ S, v ∈ X 0 − S} is the set of edges connecting S with its complement. 4 When h(X) is small it means that we can disconnect a relatively large number of vertices (those in S) from the rest of the graph by removing a relatively small number of edges (those in δS).…”

Section: B Expander Graphsmentioning

confidence: 99%

“…Their codes are derived from fiber bundles over the torus T 2 . The fibers are hyperbolic surfaces twisted along geodesics, giving rise to a quantum code family with distance 4 √ log N √ N . Evra-Kaufman-Zémor [6] and Kaufman-Tessler [7] further improved this to √ log N √ N and log k (N ) √ N , respectively.…”

Section: Introductionmentioning

confidence: 99%

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Balanced Product Quantum Codes

Breuckmann

Eberhardt²

2021

IEEE Trans. Inform. Theory

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This work provides the first explicit and nonrandom family of [[N, K, D]] LDPC quantum codes which encode K ∈ Θ(N 4 5 ) logical qubits with distance D ∈ Ω(N 3 5 ). The family is constructed by amalgamating classical codes and Ramanujan graphs via an operation called balanced product.Recently, Hastings-Haah-O'Donnell and Panteleev-Kalachev were the first to show that there exist families of LDPC quantum codes which break the polylog(N ) √ N distance barrier. However, their constructions are based on probabilistic arguments which only guarantee the code parameters with high probability whereas our bounds hold unconditionally.Further, balanced products allow for non-abelian twisting of the check matrices, leading to a construction of LDPC quantum codes that can be shown to have K ∈ Θ(N ) and that we conjecture to have linear distance D ∈ Θ(N ).

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“…When the spatial dimension d ≥ 2, there are ground spaces that have topological order, e.g. Toric code, and even for higher dimensions good quantum LDPC codes are shown to exist in the ground space of frustration free Hamiltonians [76]. 6 A simple yet illustrative example of the excitation ansatz states is the following.…”

Section: Aqedc At Low Energies: the Excitation Ansatzmentioning

confidence: 99%

Quantum error-detection at low energies

Gschwendtner

Koenig

Şahinoğlu

et al. 2019

J. High Energ. Phys.

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Motivated by the close relationship between quantum error-correction, topological order, the holographic AdS/CFT duality, and tensor networks, we initiate the study of approximate quantum error-detecting codes in matrix product states (MPS). We first show that using open-boundary MPS to define boundary to bulk encoding maps yields at most constant distance error-detecting codes. These are degenerate ground spaces of gapped local Hamiltonians. To get around this no-go result, we consider excited states, i.e., we use the excitation ansatz to construct encoding maps: these yield error-detecting codes with distance Ω(n 1−ν ) for any ν ∈ (0, 1) and Ω(log n) encoded qubits. This shows that gapped systems contain -within isolated energy bands -error-detecting codes spanned by momentum eigenstates. We also consider the gapless Heisenberg-XXX model, whose energy eigenstates can be described via Bethe ansatz tensor networks. We show that it contains -within its low-energy eigenspace -an error-detecting code with the same parameter scaling. All these codes detect arbitrary d-local (not necessarily geometrically local) errors even though they are not permutation-invariant. This suggests that a wide range of naturally occurring many-body systems possess intrinsic errordetecting features.

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Good approximate quantum LDPC codes from spacetime circuit Hamiltonians

Cited by 10 publications

References 38 publications

Approximate Bacon-Shor code and holography

Approximate Bacon-Shor code and holography

Balanced Product Quantum Codes

Quantum error-detection at low energies

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