Rotated surface code

Rotated surface code[1–4]

Alternative names: Checkerboard code, Medial surface code, Rectified surface code.

Description

Variant of the surface code defined on a square lattice that has been rotated 45 degrees such that qubits are on vertices, and both \(X\)- and \(Z\)-type check operators occupy plaquettes in an alternating checkerboard pattern.

Stabilizer generators for this code are shown in Fig. I.

Figure I: Stabilizer generators of a 2D rotated surface code with open boundaries. The generators are weight-four (four-body) operators on the corners of squares in the bulk and weight-two (two-body) operators on the boundaries. Red regions correspond to \(X\) operators while blue regions correspond to \(Z\) operators.

Protection

The \([[L^2,1,L]]\) planar rotated surface code variant [1] includes the \([[9,1,3]]\) surface-17 code, named as such because 8 ancilla qubits are used for check operator measurements alongside the 9 physical qubits. The \([[L^2,2,L]]\) periodic variant is a rotated toric or checkerboard code, whose smallest example is the \([[4,2,2]]\) code. Non-bipartite rotated toric codes with odd distance include the family \([[t^2+(t+1)^2,1,2t+1]]\) [3; Exam. 4].

Encoding

Unitary encoder based on code conversion between rotated and regular surface codes [5].

Transversal Gates

Fold-transversal \(S\) gate [6,7].

Gates

Injection of the \(|Y\rangle\) state [8].

Decoding

Only certain syndrome extraction schedules are distance-preserving [4].Local neural-network using 3D convolutions, combined with a separate global decoder [9].Iterative CNOT decoder [10].Fault-tolerant BP (FTBP) decoder [11].

Fault Tolerance

A particular choice of CNOT gates during syndrome extraction is required to avoid hook errors and be fault-tolerant to syndrome qubit errors [4,12,13].

Threshold

Thresholds for various amounts of erasure, Pauli, correlated, and measurement noise are known [14,15].

Realizations

Teleportation transition of distance-seven rotated surface-code states on a 125-qubit superconducting processor [16].

Cousins

Hypergraph product (HGP) code— Periodic checkerboard or rotated-toric codes on the same lattice can be obtained from hypergraph products of two cyclic linear binary codes with palindromic check polynomials [3; Sec. IV.D].
Cyclic linear binary code— Periodic checkerboard or rotated-toric codes on the same lattice can be obtained from hypergraph products of two cyclic linear binary codes with palindromic check polynomials [3; Sec. IV.D].
Heavy-hexagon code— A rotated surface code can be mapped onto a heavy square lattice, resulting in a code similar to the heavy-hexagon code [17].
Hierarchical code— Hierarchical codes are concatenations of constant-rate QLDPC codes with rotated surface codes.
Yoked surface code— Yoked surface codes are concatenations of QMDPC codes with rotated surface codes.
Plaquette Ising code— The 2D plaquette Ising model can be thought of as the rotated surface code whose \(X\)-type stabilizer generators have been converted to \(Z\)-type stabilizer generators.
Concatenated cat code— Cat codes have been concatenated with rotated surface codes [18].
GKP-surface code— GKP codes have been concatenated with rotated surface codes [19–22].
Tensor-network code— A tensor-network based modification of the rotated surface code improves performance against depolarizing noise by \(\approx 2\%\) [23].
Ball-Verstraete-Cirac (BVC) code— An appropriately chosen stabilizer generator set for the BVC code contains the stabilizers of the rotated surface code [24].
Toric code— Rotating the square lattice by \(\pi/4\) and choosing periodicity vectors on the rotated checkerboard lattice yields periodic checkerboard or rotated-toric variants with the same \([[L^2,2,L]]\) scaling, as well as non-bipartite odd-distance families with parameters \([[t^2+(t+1)^2,1,2t+1]]\) [3; Sec. III].
3D surface code— There exists a rotated version of the 3D surface code, akin to the (2D) rotated surface code [25].
XZZX surface code— The XZZX code is obtained from the rotated surface code by applying Hadamard gates on a subset of qubits such that \(XXXX\) and \(ZZZZ\) generators are both mapped to \(XZXZ\). Both rotated and XZZX codes offer improved performance over the original surface code for biased noise [26].
Compass code— The surface-density compass code family interpolates between Bacon-Shor codes and rotated surface codes.
Subsystem rotated surface code— Subsystem rotated surface codes are subsystem versions of rotated surface codes.

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 codeQLDPC Qubit Generalized homological-product CSS Stabilizer Hamiltonian-based QECC Quantum

Homological code

Kitaev surface codeCDSC Twist-defect surface QLDPC Qubit CSS Generalized homological-product Lattice stabilizer Stabilizer Abelian topological Topological Hamiltonian-based QECC Quantum

Parents

Kitaev surface code

The lattice of the rotated surface code can be obtained by taking the medial graph of the surface code lattice (treated as a graph) and applying a similar procedure to construct the check operators [1,27][28; Fig. 8]. Applying the quantum Tanner transformation to the surface code yields the rotated surface code [29,30]. The rotated surface code presents certain savings over the original surface code [31].

Quantum Tanner codeQLDPC Qubit Generalized homological-product CSS Stabilizer Hamiltonian-based QECC Quantum

Applying the quantum Tanner transformation to the surface code yields the rotated surface code [29,30].

Rotated surface code

Children

\([[4,1,2]]\) Leung-Nielsen-Chuang-Yamamoto (LNCY) code

The \([[4,1,2]]\) LNCY code is a small planar rotated surface code [32–35].

\([[4,2,2]]\) Four-qubit code

The \([[4,2,2]]\) code is the smallest rotated toric code [36].

\([[5,1,2]]\) rotated surface code

\([[9,1,3]]\) Surface-17 code

References

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Page edit log

Eric Huang (2024-03-14) — most recent
Marcus P da Silva (2023-03-20)
Victor V. Albert (2022-07-30)

Cite as:

“Rotated surface code”, The Error Correction Zoo (V. V. Albert & P. Faist, eds.), 2024. https://errorcorrectionzoo.org/c/rotated_surface

Github: https://github.com/errorcorrectionzoo/eczoo_data/edit/main/codes/quantum/qubits/stabilizer/topological/surface/rotated_surface/rotated_surface/rotated_surface.yml.