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Modular-qudit code

Alternative names: \(\mathbb{Z}_q\)-qudit code, Modular-qudit subspace code.
Root code for the Modular-qudit Kingdom

Description

Encodes \(K\)-dimensional Hilbert space into a \(q^n\)-dimensional (\(n\)-qudit) Hilbert space, with canonical qudit states \(|k\rangle\) labeled by elements \(k\) of the group \(\mathbb{Z}_q\) of integers modulo \(q\). Usually denoted as \(((n,K))_{\mathbb{Z}_q}\) or \(((n,K,d))_{\mathbb{Z}_q}\), whenever the code's distance \(d\) is defined, and with \(q=p\) when the dimension is prime.

Protection

Modular-qudit Pauli-string error basis

A convenient and often considered error set is the modular-qudit analogue [1,2] of the Pauli string basis for qubit codes.

Modular-qudit Pauli strings: For a single qudit, this set consists of products of powers of the modular-qudit Pauli matrices \(X\) and \(Z\), which act on computational basis states \(|k\rangle\) for \(k\in\mathbb{Z}_q\) as \begin{align} X\left|k\right\rangle =\left|k+1\right\rangle \,\,\text{ and }\,\,Z\left|k\right\rangle =e^{i\frac{2\pi}{q}k}\left|k\right\rangle ~, \tag*{(1)}\end{align} with addition performed modulo \(q\). For multiple qudits, error set elements are tensor products of elements of the single-qudit error set. Tensor products of \(X\) (\(Z\)) modular-qudit Paulis acting on different qudits are called \(X\)-type (\(Z\)-type) modular-qudit Pauli strings. Combining the \(X\)-type and \(Z\)-type strings with a primitive \(2q\)th root of unity forms a group called the modular-qudit Pauli group [3].

Modular-qudit Pauli matrices [4,5] are also known as Weyl operators [6], Sylvester-t'Hooft generators [7,8], shift and boost operators [9], or clock and shift matrices [10]; they are special cases of Manin's quantum plane [1114].

The Pauli error set is a unitary basis for linear operators on the multi-qudit Hilbert space that is orthonormal under the Hilbert-Schmidt inner product; it is a nice error basis. The distance associated with this set is often the minimum weight of a qudit Pauli string that implements a nontrivial logical operation in the code.

Rate

Non-stabilizer states yield higher quantum capacity of the discrete beamsplitter channel [15].

Gates

The normalizer of the modular-qudit Pauli group is the modular-qudit Clifford group [1,3,1620]. There is a standard form for modular-qudit Clifford-group operators [3; Lemma 4], and any modular-qudit gate can be constructed phase-shift and quantum Fourier transform gates [21]. Universal computing can be achieved using qudit Clifford gates and a single type of non-Clifford gate, such as the \(T\) gate [22]. Non-Clifford gates are typically more difficult to implement than Clifford gates and so are treated as a resource. There is a normal form for Clifford+\(T\) operators for odd prime qudits [23]. Optimizing non-Clifford-gate count can be done using various procedures; see Refs. [2427] for qutrit codes.

Qudit Clifford hierarchy: The modular-qudit Clifford hierarchy [2831] is a tower of gate sets which includes modular-qudit Pauli and modular-qudit Clifford gates at its first two levels, and non-Clifford qudit gates at higher levels. The \(k\)th level is defined recursively by \begin{align} C_k = \{ U | U P U^{\dagger} \in C_{k-1} \}~, \tag*{(2)}\end{align} where \(P\) is any modular-qudit Pauli matrix, and \(C_1\) is the modular-qudit Pauli group. Gates for one prime-dimensional qudit have been classified [32].

Decoding

For few-qudit codes (\(n\) is small), decoding can be based on a lookup table. For infinite code families, the size of such a table scales exponentially with \(n\), so approximate decoding algorithms scaling polynomially with \(n\) have to be used. The decoder determining the most likely error given a noise channel is called the maximum-likelihood (ML) decoder.

Threshold

There is a threshold against depolarizing noise for any modular-qudit gate that determines if the gate is non-Clifford [33].

Notes

Review of qudit quantum computation [20].Weight distribution of a code depends on the average entanglement of codewords [34,35].Qudit Cirq library [36].

Cousins

  • Bosonic \(q\)-ary expansion— The bosonic \(q\)-ary expansion allows one to map between prime-dimensional qudit states and a Fock subspace of a single mode.
  • Subsystem modular-qudit code— Subsystem modular-qudit codes reduce to (subspace) modular-qudit codes when there is no gauge subsystem.
  • Galois-qudit code— A Galois qudit for \(q=p^m\) can be decomposed into a Kronecker product of \(m\) modular qudits; see [37,3941][38; Sec. 5.3]. The two coincide when \(q\) is prime, and reduce to qubits when \(q=2\). However, Pauli matrices for the two types of qudits are defined differently.

Member of code lists

Primary Hierarchy

Quantum Domain
Modular-qudit Kingdom
Parents
Block quantum codeQECC Quantum
Group-based quantum codeQECC Quantum
Group quantum codes whose physical spaces are constructed using modular-integer groups \(\mathbb{Z}_q\) are modular-qudit codes.
Category-based quantum codeQECC Quantum
Category quantum codes whose physical spaces are constructed using the group \(\mathbb{Z}_q\) as the category are modular-qudit codes.
Modular-qudit code
Children
Qubit codeHastings-Haah Floquet Fermion Self-complementary qubit BB Homological Fermion-into-qubit Quantum RM code Color Twist-defect color CDSC Twist-defect surface Kitaev surface
Modular-qudit quantum codes for \(q=2\) correspond to qubit codes. Modular-qudit codes [42], circuits [43], and magic-state distillation schemes [44,45] can have advantages over their qubit counterparts. There are several ways to embed one or more qubits into a single modular qudit, yielding efficient qubit gate decompositions [46].
Modular-qudit dynamical codeHastings-Haah Floquet
\(((3,6,2))_{\mathbb{Z}_6}\) Euler code
Modular-qudit USt codeFermion-into-qubit Twist-defect color Twist-defect surface Fracton stabilizer Color BB Homological Quantum RM code CDSC Kitaev surface

References

[1]
“Full length article”, Chaos, Solitons & Fractals 10, 1749 (1999) arXiv:quant-ph/9802007 DOI
[2]
R. Sarkar and T. J. Yoder, “The qudit Pauli group: non-commuting pairs, non-commuting sets, and structure theorems”, Quantum 8, 1307 (2024) arXiv:2302.07966 DOI
[3]
D. M. Appleby, “Symmetric informationally complete–positive operator valued measures and the extended Clifford group”, Journal of Mathematical Physics 46, (2005) arXiv:quant-ph/0412001 DOI
[4]
J. v. Neumann, “Die Eindeutigkeit der Schrödingerschen Operatoren”, Mathematische Annalen 104, 570 (1931) DOI
[5]
J. Schwinger, Quantum Kinematics and Dynamics (CRC Press, 2018) DOI
[6]
Weyl, Hermann. The theory of groups and quantum mechanics. Courier Corporation, 1950.
[7]
Sylvester, James Joseph. The Collected Mathematical Papers of James Joseph Sylvester. Vol. 3. University Press, 1909.
[8]
G. ’t Hooft, “On the phase transition towards permanent quark confinement”, Nuclear Physics B 138, 1 (1978) DOI
[9]
D. Gross, “Hudson’s theorem for finite-dimensional quantum systems”, Journal of Mathematical Physics 47, (2006) arXiv:quant-ph/0602001 DOI
[10]
C. Zachos, “Hamiltonian Flows, SU(∞), SO(∞), USp(∞), and Strings”, NATO ASI Series 423 (1990) DOI
[11]
Yu. I. Manin, “Some remarks on Koszul algebras and quantum groups”, Annales de l’institut Fourier 37, 191 (1987) DOI
[12]
Y. I. Manin, “Quantized Theta-Functions”, Progress of Theoretical Physics Supplement 102, 219 (2013) DOI
[13]
Yu. I. Manin, “Functional equations for quantum theta functions”, (2003) arXiv:math/0307393
[14]
E. Chang-Young and H. Kim, “Theta vectors and quantum theta functions”, Journal of Physics A: Mathematical and General 38, 4255 (2005) arXiv:math/0402401 DOI
[15]
K. Bu and A. Jaffe, “Magic Resource Can Enhance the Quantum Capacity of Channels”, Physical Review Letters 134, (2025) arXiv:2401.12105 DOI
[16]
E. Hostens, J. Dehaene, and B. De Moor, “Stabilizer states and Clifford operations for systems of arbitrary dimensions and modular arithmetic”, Physical Review A 71, (2005) arXiv:quant-ph/0408190 DOI
[17]
S. Clark, “Valence bond solid formalism ford-level one-way quantum computation”, Journal of Physics A: Mathematical and General 39, 2701 (2006) arXiv:quant-ph/0512155 DOI
[18]
H. Bombin and M. A. Martin-Delgado, “Homological error correction: Classical and quantum codes”, Journal of Mathematical Physics 48, (2007) arXiv:quant-ph/0605094 DOI
[19]
V. Gheorghiu, “Standard form of qudit stabilizer groups”, Physics Letters A 378, 505 (2014) arXiv:1101.1519 DOI
[20]
Y. Wang, Z. Hu, B. C. Sanders, and S. Kais, “Qudits and High-Dimensional Quantum Computing”, Frontiers in Physics 8, (2020) arXiv:2008.00959 DOI
[21]
J. M. Farinholt, “An ideal characterization of the Clifford operators”, Journal of Physics A: Mathematical and Theoretical 47, 305303 (2014) arXiv:1307.5087 DOI
[22]
F. H. E. Watson, E. T. Campbell, H. Anwar, and D. E. Browne, “Qudit color codes and gauge color codes in all spatial dimensions”, Physical Review A 92, (2015) arXiv:1503.08800 DOI
[23]
A. Jain, A. R. Kalra, and S. Prakash, “A Normal Form for Single-Qudit Clifford+\(T\) Operators”, (2020) arXiv:2011.07970
[24]
A. Bocharov, X. Cui, V. Kliuchnikov, and Z. Wang, “Efficient topological compilation for a weakly integral anyonic model”, Physical Review A 93, (2016) arXiv:1504.03383 DOI
[25]
A. R. Kalra, M. Mosca, and D. Valluri, “Synthesis and Arithmetic of Single Qutrit Circuits”, Quantum 9, 1647 (2025) arXiv:2311.08696 DOI
[26]
S. Evra and O. Parzanchevski, “Arithmeticity, thinness and efficiency of qutrit Clifford+T gates”, (2024) arXiv:2401.16120
[27]
A. R. Kalra, M. Saikia, D. Valluri, S. Winnick, and J. Yard, “Multi-qutrit exact synthesis”, (2024) arXiv:2405.08147
[28]
D. Gottesman and I. L. Chuang, “Demonstrating the viability of universal quantum computation using teleportation and single-qubit operations”, Nature 402, 390 (1999) arXiv:quant-ph/9908010 DOI
[29]
M. Howard and J. Vala, “Qudit versions of the qubitπ/8gate”, Physical Review A 86, (2012) arXiv:1206.1598 DOI
[30]
F. Pastawski and B. Yoshida, “Fault-tolerant logical gates in quantum error-correcting codes”, Physical Review A 91, (2015) arXiv:1408.1720 DOI
[31]
S. X. Cui, D. Gottesman, and A. Krishna, “Diagonal gates in the Clifford hierarchy”, Physical Review A 95, (2017) arXiv:1608.06596 DOI
[32]
N. de Silva and O. Lautsch, “The Clifford hierarchy for one qubit or qudit”, (2025) arXiv:2501.07939
[33]
W. van Dam and M. Howard, “Noise thresholds for higher-dimensional systems using the discrete Wigner function”, Physical Review A 83, (2011) arXiv:1011.2497 DOI
[34]
A. J. Scott, “Multipartite entanglement, quantum-error-correcting codes, and entangling power of quantum evolutions”, Physical Review A 69, (2004) arXiv:quant-ph/0310137 DOI
[35]
L. Schatzki, G. Liu, M. Cerezo, and E. Chitambar, “Hierarchy of multipartite correlations based on concentratable entanglement”, Physical Review Research 6, (2024) arXiv:2209.07607 DOI
[36]
S. Kushnarev and H. J. Asghar, “The Qudit Cirq Library: An Extension of Google’s Cirq Library for Qudits”, (2025) arXiv:2501.07812
[37]
A. Ashikhmin and E. Knill, “Nonbinary quantum stabilizer codes”, IEEE Transactions on Information Theory 47, 3065 (2001) DOI
[38]
A. Niehage, “Quantum Goppa Codes over Hyperelliptic Curves”, (2005) arXiv:quant-ph/0501074
[39]
D. Gottesman. Surviving as a quantum computer in a classical world (2024) URL
[40]
Q. T. Nguyen, “Good binary quantum codes with transversal CCZ gate”, (2024) arXiv:2408.10140
[41]
L. Golowich and V. Guruswami, “Asymptotically Good Quantum Codes with Transversal Non-Clifford Gates”, (2024) arXiv:2408.09254
[42]
J. Keppens, Q. Eggerickx, V. Levajac, G. Simion, and B. Sorée, “Qudit vs. Qubit: Simulated performance of error correction codes in higher dimensions”, (2025) arXiv:2502.05992
[43]
P. Gokhale, J. M. Baker, C. Duckering, N. C. Brown, K. R. Brown, and F. T. Chong, “Asymptotic improvements to quantum circuits via qutrits”, Proceedings of the 46th International Symposium on Computer Architecture 554 (2019) arXiv:1905.10481 DOI
[44]
E. T. Campbell, H. Anwar, and D. E. Browne, “Magic-State Distillation in All Prime Dimensions Using Quantum Reed-Muller Codes”, Physical Review X 2, (2012) arXiv:1205.3104 DOI
[45]
E. T. Campbell, “Enhanced Fault-Tolerant Quantum Computing ind-Level Systems”, Physical Review Letters 113, (2014) arXiv:1406.3055 DOI
[46]
E. O. Kiktenko, A. S. Nikolaeva, and A. K. Fedorov, “Colloquium : Qudits for decomposing multiqubit gates and realizing quantum algorithms”, Reviews of Modern Physics 97, (2025) arXiv:2311.12003 DOI
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Zoo Code ID: qudits_into_qudits

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“Modular-qudit code”, The Error Correction Zoo (V. V. Albert & P. Faist, eds.), 2022. https://errorcorrectionzoo.org/c/qudits_into_qudits
BibTeX:
@incollection{eczoo_qudits_into_qudits, title={Modular-qudit code}, booktitle={The Error Correction Zoo}, year={2022}, editor={Albert, Victor V. and Faist, Philippe}, url={https://errorcorrectionzoo.org/c/qudits_into_qudits} }
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“Modular-qudit code”, The Error Correction Zoo (V. V. Albert & P. Faist, eds.), 2022. https://errorcorrectionzoo.org/c/qudits_into_qudits

Github: https://github.com/errorcorrectionzoo/eczoo_data/edit/main/codes/quantum/qudits/qudits_into_qudits.yml.