Graph-based models require aggregating information in the graph from neighbourhoods of different sizes. In particular, when the data exhibit varying levels of smoothness on the graph, a multi-scale approach is required to capture the relevant information. In this work, we propose a Gaussian process model using spectral graph wavelets, which can naturally aggregate neighbourhood information at different scales. Through maximum likelihood optimisation of the model hyperparameters, the wavelets automatically adapt to the different frequencies in the data, and as a result our model goes beyond capturing low frequency information. We achieve scalability to larger graphs by using a spectrum-adaptive polynomial approximation of the filter function, which is designed to yield a low approximation error in dense areas of the graph spectrum. Synthetic and real-world experiments demonstrate the ability of our model to infer scales accurately and produce competitive performances against state-of-the-art models in graph-based learning tasks.

Adaptive Gaussian Processes on Graphs via Spectral Graph Wavelets / Opolka, F. L.; Zhi, Y. -C.; Lio, P.; Dong, X.. - 151:(2022), pp. 4818-4834. (Intervento presentato al convegno International Conference on Artificial Intelligence and Statistics tenutosi a esp).

Adaptive Gaussian Processes on Graphs via Spectral Graph Wavelets

Lio P.
;
2022

Abstract

Graph-based models require aggregating information in the graph from neighbourhoods of different sizes. In particular, when the data exhibit varying levels of smoothness on the graph, a multi-scale approach is required to capture the relevant information. In this work, we propose a Gaussian process model using spectral graph wavelets, which can naturally aggregate neighbourhood information at different scales. Through maximum likelihood optimisation of the model hyperparameters, the wavelets automatically adapt to the different frequencies in the data, and as a result our model goes beyond capturing low frequency information. We achieve scalability to larger graphs by using a spectrum-adaptive polynomial approximation of the filter function, which is designed to yield a low approximation error in dense areas of the graph spectrum. Synthetic and real-world experiments demonstrate the ability of our model to infer scales accurately and produce competitive performances against state-of-the-art models in graph-based learning tasks.
2022
International Conference on Artificial Intelligence and Statistics
Gaussian distribution; Gaussian noise (electronic); Graphic methods; Maximum likelihood
04 Pubblicazione in atti di convegno::04b Atto di convegno in volume
Adaptive Gaussian Processes on Graphs via Spectral Graph Wavelets / Opolka, F. L.; Zhi, Y. -C.; Lio, P.; Dong, X.. - 151:(2022), pp. 4818-4834. (Intervento presentato al convegno International Conference on Artificial Intelligence and Statistics tenutosi a esp).
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1727978
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