Hypergraph product (HGP) code

Hypergraph product (HGP) code[1–3]

Alternative names: Quantum hypergraph (QHG) code, Tillich-Zemor product code.

Description

A member of a family of CSS codes whose stabilizer generator matrix is obtained from a hypergraph product of two classical linear binary codes. Codes from hypergraph products in higher dimension are called higher-dimensional HGP codes [3].

More technically, the \(X\)- and \(Z\)-type stabilizer generator matrices of a hypergraph product code are, respectively, the boundary and coboundary operators of the 2-complex obtained from the tensor product of a chain complex and cochain complex corresponding to two classical linear binary seed codes. Let the two seed codes be \(C_i\) for \(i\in\{1,2\}\) with parameters \([n_i, k_i, d_i]\), defined as the kernel of \(r_i \times n_i\) check matrices \(H_i\) of rank \(n_i - k_i\). The hypergraph product yields two classical codes \(C_{X,Z}\) with parity-check matrices \begin{align} H_{X}&=\begin{pmatrix}H_{1}\otimes I_{n_{2}} & \,\,I_{r_{1}}\otimes H_{2}^{T}\end{pmatrix}\tag*{(1)}\\ H_{Z}&=\begin{pmatrix}I_{n_{1}}\otimes H_{2} & \,\,H_{1}^{T}\otimes I_{r_{2}}\end{pmatrix}~, \tag*{(2)}\end{align} where \(I_m\) is the \(m\)-dimensional identity matrix. These two codes then yield a hypergraph product code via the CSS construction.

In general, the stabilizer generator matrices of an \(m\)-dimensional hypergraph product code are the boundary and co-boundary operators of a 2-dimensional chain complex contained within an \(m\)-complex that is recursively constructed by taking the tensor product of an \((m-1)\)-complex and a 1-complex, with the 1-complex corresponding to some classical linear binary code.

Protection

If \([n_i, k_i, d_i]\) (\([r_i, k^T_i, d^T_i]\)) are the parameters of the codes \(\mathrm{ker}H_i\) (\(\mathrm{ker}H_i^T\), taking (\(d=\infty\) if \(k=0\)), the hypergraph product has parameters \([[n_1 n_2 + r_1 r_2, k_1 k_2 + k_1^T k_2^T, \min(d_1, d_2, d_1^T, d_2^T)]]\)

Encoding

Fault-tolerant state preparation via dimension jump [4].

Transversal Gates

Hadamard (up to logical SWAP gates) and control-\(Z\) on all logical qubits [5].Patch-transversal gates inherited from the automorphism group of the underlying classical codes [6; Appx. D].

Gates

Code deformation techniques yield Clifford gates [7].Targeted logical gates [8].Logical gates via Dehn twists for hypergraph products of cyclic codes [9].

Decoding

Single-ancilla syndrome extraction circuits do not admit hook errors [10].ReShape decoder that uses minimum weight decoders for the classical codes used in the hypergraph construction [11].2D geometrically local syndrome extraction circuits with depth order \(O(\sqrt{n})\) using order \(O(n)\) ancilla qubits [12].Improved BP-OSD decoder [13].Erasure correction can be implemented approximately with \(O(n^2)\) operations with quantum generalizations [14] of the peeling and pruned peeling decoders [15], with a probabilistic version running in \(O(n^{1.5})\) operations. Other nearly optimal erasure decoders exist [16,17]. Initial hypergraph product codes can be further optimized against the erasure channel using reinforcement learning [18].Syndrome measurements are distance-preserving because syndrome extraction circuits can be designed to avoid hook errors [19].Generalization [20] of Viderman's algorithm for expander codes [21].Linear time iterative decoder [22].

Fault Tolerance

Single-ancilla syndrome extraction circuits do not admit hook errors [10].There is a fault-tolerant universal computation scheme for hypergraph-product codes concatenated with the \([[4,2,2]]\) code [23].

Code Capacity Threshold

Some thresholds were determined in Ref. [24].Bounds on code capacity thresholds using ML decoding can be obtained by mapping the effect of noise on the code to a statistical mechanical model [25]. For example, a threshold of \(7\%\) was obtained under independent \(X\) and \(Z\) noise for codes obtained from random \((3,4)\)-regular Gallager codes.

Threshold

Circuit-level noise: \(0.1\%\) with all-to-all connected syndrome extraction circuits [12] and DiVincenzo-Aliferis syndrome extraction circuits [26] combined with non-local gates [27]. No threshold observed above physical noise rates at or above \(10^{-6}\) using 2D geometrically local syndrome extraction circuits.

Cousins

Locally testable code (LTC)— Applying the hypergraph product to an LTC yields a code which provides an explicit example of No Low-Error Trivial States (NLETS) [28].
XYZ product code— Hypergraph (XYZ) product codes are constructed out of hypergraph products of two (three) classical linear codes.
Linear binary code— Hypergraph product codes are constructed out of two linear binary codes.
Neural network quantum code— Using reinforcement learning, hypergraph product codes can be further optimized against the erasure channel [18] and can be weight reduced while maintaining distance [29].
\([[4,2,2]]\) Four-qubit code— There is a fault-tolerant universal computation scheme for hypergraph-product codes concatenated with the \([[4,2,2]]\) code [23].
Concatenated qubit code— There is a fault-tolerant universal computation scheme for hypergraph-product codes concatenated with the \([[4,2,2]]\) code [23].
Tiger surface code— The tiger surface code is constructed from a hypergraph product of two repetition codes over the integers.
Quantum locally recoverable code (QLRC)— A variant of the hypergraph product can be used to define QLRCs with intersecting recovery sets [30].
Single-shot code— Two-fold application of the hypergraph product to a pair of binary linear codes yields single-shot QLDPC codes that exploit redundancy in their stabilizer generators [31].
Self-correcting quantum code— There are bounds on the energy barrier of hypergraph product codes [32].
Quantum rainbow code— Hypergraph products of color codes yield quantum rainbow codes with growing distance and transversal gates in the Clifford hierarchy. In particular, utilizing this construction for quasi-hyperbolic color codes yields an \([[n,O(n),O(\log n)]]\) triorthogonal code family with magic-state yield parameter \(\gamma\to 0\) [33].
High-dimensional expander (HDX) code— Ramanujan codes utilize the hypergraph product with a twist, which is an automorphism on one of the complexes in the tensor product, in order to increase distance [34].
Fractal surface code— The fractal product code is a hypergraph product of two classical codes defined on a Sierpinski carpet graph [35].
Rotated surface code— The rotated code can be obtained from hypergraph product of two cyclic linear binary codes with palindromic generator polynomial [2; Exam. 7].
Subsystem homological product code— SP codes are projected higher-dimensional HGP codes [36].
Subsystem hypergraph product (SHP) code— Two SHP codes can be gauge-fixed to yield an HGP code [37; Sec. III]. The SHP and HGP code constructions yield the same dimension and minimum distance, but the former does not yield QLDPC codes; see [1; pg. 18].
Generalized bicycle (GB) code— An arbitrary qubit GB code of length \(2\ell\) is equivalent [38] to a rotated quantum hypergraph-product code with periodicity vectors \(\vec{L}_{1}\) and \(\vec{L}_{2}\) such that \(\lvert{\vec{L}_{1}\times\vec{L}_{2}\rvert=\ell}\).

Member of code lists

Primary Hierarchy

Quantum Domain

Qubit Kingdom

Qubit codeQECC Quantum

Union stabilizer (USt) codeQECC Quantum

Qubit stabilizer codeStabilizer Hamiltonian-based Qubit QECC Quantum

Coherent-parity-check (CPC) code

Qubit CSS codeCSS Stabilizer Hamiltonian-based QECC Quantum

Generalized homological-product qubit CSS codeGeneralized homological-product QLDPC CSS Stabilizer Hamiltonian-based QECC Quantum

Fiber-bundle codeGeneralized homological-product QLDPC CSS Stabilizer Hamiltonian-based QECC Quantum

Homological product code

Parents

Homological product code

A homological product of chain complexes corresponding to two linear binary codes is a hypergraph product code [39]. Homological product codes constructed with diagonal boundary operators admit very different properties than those with rectangular boundary operators.

Quantum spatially coupled (SC-QLDPC) codeLattice stabilizer QLDPC Stabilizer Hamiltonian-based Qubit QECC Quantum

Hypergraph-product stabilizer generator matrices can be used as sub-matrices to define a 2D SC-QLDPC code [40].

Galois-qudit HGP codeGeneralized homological-product QLDPC CSS Stabilizer Hamiltonian-based QECC Quantum

Hypergraph product codes are Galois-qudit hypergraph-product codes for qudit dimension \(q=2\).

Hypergraph product (HGP) code

Children

Fibonacci fractal spin-liquid code

The Fibonacci fractal spin-liquid code is a hypergraph product of the repetition code and the Fibonacci code [41], and can be formulated directly as a BP code [42].

Sierpinski prism model code

The Sierpinski prism model code is a hypergraph product of the repetition code and the Newman-Moore code [43], and can be formulated directly as an LP code [42].

Two-foliated fracton code

The two-foliated fracton code is a hypergraph product of the repetition code and the plaquette Ising code on a square lattice with periodic boundary conditions [44].

La-cross code

La-cross codes are constructed using a hypergraph product a cyclic LDPC code with itself.

Long-range enhanced surface code (LRESC)

LRESCs are constructed using a hypergraph product a concatenated LDPC-repetition code with itself.

Quantum expander code

Toric code

The toric code can be obtained from a hypergraph product of two repetition codes [2; Exam. 6]. Other hypergraph products of two repetition codes yield the related \([[2d^2-2d+1,1,d]]\) CSS code family [2; Exam. 5].

References

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Victor V. Albert (2024-08-19) — most recent
Shi Jie Samuel Tan (2024-08-19)
Christopher A. Pattison (2023-10-25)
Victor V. Albert (2022-08-02)
Victor V. Albert (2022-01-20)
Joschka Roffe (2021-11-04)

Cite as:

“Hypergraph product (HGP) code”, The Error Correction Zoo (V. V. Albert & P. Faist, eds.), 2024. https://errorcorrectionzoo.org/c/hypergraph_product

Github: https://github.com/errorcorrectionzoo/eczoo_data/edit/main/codes/quantum/qubits/stabilizer/qldpc/homological/balanced_product/hypergraph_product.yml.