Details
| Original language | English |
|---|---|
| Journal | Physica scripta |
| Early online date | 26 Jun 2025 |
| Publication status | E-pub ahead of print - 26 Jun 2025 |
Abstract
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In: Physica scripta, 26.06.2025.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Fast generation of Pauli transfer matrices utilizing tensor product structure
AU - Hantzko, Lukas
AU - Binkowski, Lennart
AU - Gupta, Sabhyata
PY - 2025/6/26
Y1 - 2025/6/26
N2 - Analysis of quantum processes, especially in the context of noise, errors, and decoherence is essential for the improvement of quantum devices. An intuitive representation of those processes modeled by quantum channels are Pauli transfer matrices. They display the action of a linear map in the n-qubit Pauli basis in a way, that is more intuitive, since Pauli strings are more tangible objects than the standard basis matrices. We set out to investigate classical algorithms that convert the various representations into Pauli transfer matrices. We propose new algorithms that make explicit use of the tensor product structure of the Pauli basis. They convert a quantum channel in a given representation (Chi or process matrix, Choi matrix, superoperator, or Kraus operators) to the corresponding Pauli transfer matrix. Moreover, the underlying principle can also be used to calculate the Pauli transfer matrix of other linear operations over n-qubit matrices such as left-, right-, and sandwich multiplication as well as forming the (anti-)commutator with a given operator. Finally, we investigate the runtime of these algorithms, derive their asymptotic scaling and demonstrate improved performance using instances with up to seven qubits.
AB - Analysis of quantum processes, especially in the context of noise, errors, and decoherence is essential for the improvement of quantum devices. An intuitive representation of those processes modeled by quantum channels are Pauli transfer matrices. They display the action of a linear map in the n-qubit Pauli basis in a way, that is more intuitive, since Pauli strings are more tangible objects than the standard basis matrices. We set out to investigate classical algorithms that convert the various representations into Pauli transfer matrices. We propose new algorithms that make explicit use of the tensor product structure of the Pauli basis. They convert a quantum channel in a given representation (Chi or process matrix, Choi matrix, superoperator, or Kraus operators) to the corresponding Pauli transfer matrix. Moreover, the underlying principle can also be used to calculate the Pauli transfer matrix of other linear operations over n-qubit matrices such as left-, right-, and sandwich multiplication as well as forming the (anti-)commutator with a given operator. Finally, we investigate the runtime of these algorithms, derive their asymptotic scaling and demonstrate improved performance using instances with up to seven qubits.
UR - http://dx.doi.org/10.1088/1402-4896/ade8b3
U2 - 10.1088/1402-4896/ade8b3
DO - 10.1088/1402-4896/ade8b3
M3 - Article
JO - Physica scripta
JF - Physica scripta
SN - 0031-8949
ER -