Noise classification in three-level quantum networks by Machine Learning

Shreyasi Mukherjee, Dario Penna, Fabio Cirinnà, Mauro Paternostro, Elisabetta Paladino, Giuseppe Falci, Luigi Giannelli*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

We investigate a machine learning based classification of noise acting on a small quantum network with the aim of detecting spatial or multilevel correlations, and the interplay with Markovianity. We control a three-level system by inducing coherent population transfer exploiting different pulse amplitude combinations as inputs to train a feedforward neural network. We show that supervised learning can classify different types of classical dephasing noise affecting the system. Three non-Markovian (quasi-static correlated, anti-correlated and uncorrelated) and Markovian noises are classified with more than 99% accuracy. On the contrary, correlations of Markovian noise cannot be discriminated with our method. Our approach is robust to statistical measurement errors and retains its effectiveness for physical measurements where only a limited number of samples is available making it very experimental-friendly. Our result paves the way for classifying spatial correlations of noise in quantum architectures.
Original languageEnglish
Article number045049
JournalMachine Learning: Science and Technology
Volume5
Issue number4
Early online date26 Nov 2024
DOIs
Publication statusPublished - 01 Dec 2024

Keywords

  • quantum network
  • three-level system
  • noise correlations
  • noise classification
  • (non-)Markovianity
  • machine learning for quantum

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