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Main Authors: Candelori, Luca, Abanov, Alexander G., Berger, Jeffrey, Hogan, Cameron J., Kirakosyan, Vahagn, Musaelian, Kharen, Samson, Ryan, Smith, James E. T., Villani, Dario, Wells, Martin T., Xu, Mengjia
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2409.12805
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author Candelori, Luca
Abanov, Alexander G.
Berger, Jeffrey
Hogan, Cameron J.
Kirakosyan, Vahagn
Musaelian, Kharen
Samson, Ryan
Smith, James E. T.
Villani, Dario
Wells, Martin T.
Xu, Mengjia
author_facet Candelori, Luca
Abanov, Alexander G.
Berger, Jeffrey
Hogan, Cameron J.
Kirakosyan, Vahagn
Musaelian, Kharen
Samson, Ryan
Smith, James E. T.
Villani, Dario
Wells, Martin T.
Xu, Mengjia
contents We propose a new data representation method based on Quantum Cognition Machine Learning and apply it to manifold learning, specifically to the estimation of intrinsic dimension of data sets. The idea is to learn a representation of each data point as a quantum state, encoding both local properties of the point as well as its relation with the entire data. Inspired by ideas from quantum geometry, we then construct from the quantum states a point cloud equipped with a quantum metric. The metric exhibits a spectral gap whose location corresponds to the intrinsic dimension of the data. The proposed estimator is based on the detection of this spectral gap. When tested on synthetic manifold benchmarks, our estimates are shown to be robust with respect to the introduction of point-wise Gaussian noise. This is in contrast to current state-of-the-art estimators, which tend to attribute artificial ``shadow dimensions'' to noise artifacts, leading to overestimates. This is a significant advantage when dealing with real data sets, which are inevitably affected by unknown levels of noise. We show the applicability and robustness of our method on real data, by testing it on the ISOMAP face database, MNIST, and the Wisconsin Breast Cancer Dataset.
format Preprint
id arxiv_https___arxiv_org_abs_2409_12805
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Robust estimation of the intrinsic dimension of data sets with quantum cognition machine learning
Candelori, Luca
Abanov, Alexander G.
Berger, Jeffrey
Hogan, Cameron J.
Kirakosyan, Vahagn
Musaelian, Kharen
Samson, Ryan
Smith, James E. T.
Villani, Dario
Wells, Martin T.
Xu, Mengjia
Machine Learning
Quantum Physics
We propose a new data representation method based on Quantum Cognition Machine Learning and apply it to manifold learning, specifically to the estimation of intrinsic dimension of data sets. The idea is to learn a representation of each data point as a quantum state, encoding both local properties of the point as well as its relation with the entire data. Inspired by ideas from quantum geometry, we then construct from the quantum states a point cloud equipped with a quantum metric. The metric exhibits a spectral gap whose location corresponds to the intrinsic dimension of the data. The proposed estimator is based on the detection of this spectral gap. When tested on synthetic manifold benchmarks, our estimates are shown to be robust with respect to the introduction of point-wise Gaussian noise. This is in contrast to current state-of-the-art estimators, which tend to attribute artificial ``shadow dimensions'' to noise artifacts, leading to overestimates. This is a significant advantage when dealing with real data sets, which are inevitably affected by unknown levels of noise. We show the applicability and robustness of our method on real data, by testing it on the ISOMAP face database, MNIST, and the Wisconsin Breast Cancer Dataset.
title Robust estimation of the intrinsic dimension of data sets with quantum cognition machine learning
topic Machine Learning
Quantum Physics
url https://arxiv.org/abs/2409.12805