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Main Authors: Kedziora, David Jacob, Musiał, Anna, Rudno-Rudziński, Wojciech, Gabrys, Bogdan
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2306.15683
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author Kedziora, David Jacob
Musiał, Anna
Rudno-Rudziński, Wojciech
Gabrys, Bogdan
author_facet Kedziora, David Jacob
Musiał, Anna
Rudno-Rudziński, Wojciech
Gabrys, Bogdan
contents Novel methods for rapidly estimating single-photon source (SPS) quality have been promoted in recent literature to address the expensive and time-consuming nature of experimental validation via intensity interferometry. However, the frequent lack of uncertainty discussions and reproducible details raises concerns about their reliability. This study investigates the use of data augmentation, a machine learning technique, to supplement experimental data with bootstrapped samples and quantify the uncertainty of such estimates. Eight datasets obtained from measurements involving a single InGaAs/GaAs epitaxial quantum dot serve as a proof-of-principle example. Analysis of one of the SPS quality metrics derived from efficient histogram fitting of the synthetic samples, i.e. the probability of multi-photon emission events, reveals significant uncertainty contributed by stochastic variability in the Poisson processes that describe detection rates. Ignoring this source of error risks severe overconfidence in both early quality estimates and claims for state-of-the-art SPS devices. Additionally, this study finds that standard least-squares fitting is comparable to using a Poisson likelihood, and expanding averages show some promise for early estimation. Also, reducing background counts improves fitting accuracy but does not address the Poisson-process variability. Ultimately, data augmentation demonstrates its value in supplementing physical experiments; its benefit here is to emphasise the need for a cautious assessment of SPS quality.
format Preprint
id arxiv_https___arxiv_org_abs_2306_15683
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Harnessing Data Augmentation to Quantify Uncertainty in the Early Estimation of Single-Photon Source Quality
Kedziora, David Jacob
Musiał, Anna
Rudno-Rudziński, Wojciech
Gabrys, Bogdan
Optics
Mesoscale and Nanoscale Physics
Machine Learning
Novel methods for rapidly estimating single-photon source (SPS) quality have been promoted in recent literature to address the expensive and time-consuming nature of experimental validation via intensity interferometry. However, the frequent lack of uncertainty discussions and reproducible details raises concerns about their reliability. This study investigates the use of data augmentation, a machine learning technique, to supplement experimental data with bootstrapped samples and quantify the uncertainty of such estimates. Eight datasets obtained from measurements involving a single InGaAs/GaAs epitaxial quantum dot serve as a proof-of-principle example. Analysis of one of the SPS quality metrics derived from efficient histogram fitting of the synthetic samples, i.e. the probability of multi-photon emission events, reveals significant uncertainty contributed by stochastic variability in the Poisson processes that describe detection rates. Ignoring this source of error risks severe overconfidence in both early quality estimates and claims for state-of-the-art SPS devices. Additionally, this study finds that standard least-squares fitting is comparable to using a Poisson likelihood, and expanding averages show some promise for early estimation. Also, reducing background counts improves fitting accuracy but does not address the Poisson-process variability. Ultimately, data augmentation demonstrates its value in supplementing physical experiments; its benefit here is to emphasise the need for a cautious assessment of SPS quality.
title Harnessing Data Augmentation to Quantify Uncertainty in the Early Estimation of Single-Photon Source Quality
topic Optics
Mesoscale and Nanoscale Physics
Machine Learning
url https://arxiv.org/abs/2306.15683