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Autori principali: Zhukas, Liudmila A., Zhang, Vivian Ni, Miao, Qiang, Wang, Qingfeng, Cetina, Marko, Kim, Jungsang, Carin, Lawrence, Monroe, Christopher
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.13497
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author Zhukas, Liudmila A.
Zhang, Vivian Ni
Miao, Qiang
Wang, Qingfeng
Cetina, Marko
Kim, Jungsang
Carin, Lawrence
Monroe, Christopher
author_facet Zhukas, Liudmila A.
Zhang, Vivian Ni
Miao, Qiang
Wang, Qingfeng
Cetina, Marko
Kim, Jungsang
Carin, Lawrence
Monroe, Christopher
contents Quantum machine learning (QML) has attracted growing interest with the rapid parallel advances in large-scale classical machine learning and quantum technologies. Similar to classical machine learning, QML models also face challenges arising from the scarcity of labeled data, particularly as their scale and complexity increase. Here, we introduce self-supervised pretraining of quantum representations that reduces reliance on labeled data by learning invariances from unlabeled examples. We implement this paradigm on a programmable trapped-ion quantum computer, encoding images as quantum states. In situ contrastive pretraining on hardware yields a representation that, when fine-tuned, classifies image families with higher mean test accuracy and lower run-to-run variability than models trained from random initialization. Performance improvement is especially significant in regimes with limited labeled training data. We show that the learned invariances generalize beyond the pretraining image samples. Unlike prior work, our pipeline derives similarity from measured quantum overlaps and executes all training and classification stages on hardware. These results establish a label-efficient route to quantum representation learning, with direct relevance to quantum-native datasets and a clear path to larger classical inputs.
format Preprint
id arxiv_https___arxiv_org_abs_2511_13497
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum Machine Learning via Contrastive Training
Zhukas, Liudmila A.
Zhang, Vivian Ni
Miao, Qiang
Wang, Qingfeng
Cetina, Marko
Kim, Jungsang
Carin, Lawrence
Monroe, Christopher
Machine Learning
Quantum Physics
Quantum machine learning (QML) has attracted growing interest with the rapid parallel advances in large-scale classical machine learning and quantum technologies. Similar to classical machine learning, QML models also face challenges arising from the scarcity of labeled data, particularly as their scale and complexity increase. Here, we introduce self-supervised pretraining of quantum representations that reduces reliance on labeled data by learning invariances from unlabeled examples. We implement this paradigm on a programmable trapped-ion quantum computer, encoding images as quantum states. In situ contrastive pretraining on hardware yields a representation that, when fine-tuned, classifies image families with higher mean test accuracy and lower run-to-run variability than models trained from random initialization. Performance improvement is especially significant in regimes with limited labeled training data. We show that the learned invariances generalize beyond the pretraining image samples. Unlike prior work, our pipeline derives similarity from measured quantum overlaps and executes all training and classification stages on hardware. These results establish a label-efficient route to quantum representation learning, with direct relevance to quantum-native datasets and a clear path to larger classical inputs.
title Quantum Machine Learning via Contrastive Training
topic Machine Learning
Quantum Physics
url https://arxiv.org/abs/2511.13497