Litcius/Paper detail

Gradient-Descent Quantum Process Tomography by Learning Kraus Operators

Shahnawaz Ahmed, Fernando Quijandría, Anton Frisk Kockum

2023Physical Review Letters27 citationsDOIOpen Access PDF

Abstract

We perform quantum process tomography (QPT) for both discrete- and continuous-variable quantum systems by learning a process representation using Kraus operators. The Kraus form ensures that the reconstructed process is completely positive. To make the process trace preserving, we use a constrained gradient-descent (GD) approach on the so-called Stiefel manifold during optimization to obtain the Kraus operators. Our ansatz uses a few Kraus operators to avoid direct estimation of large process matrices, e.g., the Choi matrix, for low-rank quantum processes. The GD-QPT matches the performance of both compressed-sensing (CS) and projected least-squares (PLS) QPT in benchmarks with two-qubit random processes, but shines by combining the best features of these two methods. Similar to CS (but unlike PLS), GD-QPT can reconstruct a process from just a small number of random measurements, and similar to PLS (but unlike CS) it also works for larger system sizes, up to at least five qubits. We envisage that the data-driven approach of GD-QPT can become a practical tool that greatly reduces the cost and computational effort for QPT in intermediate-scale quantum systems.

Topics & Concepts

Quantum processAnsatzQuantumQuantum tomographyStatistical physicsQubitQuantum algorithmProcess (computing)Computer scienceApplied mathematicsPhysicsQuantum mechanicsAlgorithmMathematicsQuantum stateQuantum dynamicsOperating systemQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographySparse and Compressive Sensing Techniques