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Bibliographic Details
Main Authors: Staerman, Guillaume, Loison, Virginie, Moreau, Thomas
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.16938
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author Staerman, Guillaume
Loison, Virginie
Moreau, Thomas
author_facet Staerman, Guillaume
Loison, Virginie
Moreau, Thomas
contents Physiological signal analysis often involves identifying events crucial to understanding biological dynamics. Traditional methods rely on handcrafted procedures or supervised learning, presenting challenges such as expert dependence, lack of robustness, and the need for extensive labeled data. Data-driven methods like Convolutional Dictionary Learning (CDL) offer an alternative but tend to produce spurious detections. This work introduces UNHaP (Unmix Noise from Hawkes Processes), a novel approach addressing the joint learning of temporal structures in events and the removal of spurious detections. Leveraging marked Hawkes processes, UNHaP distinguishes between events of interest and spurious ones. By treating the event detection output as a mixture of structured and unstructured events, UNHaP efficiently unmixes these processes and estimates their parameters. This approach significantly enhances the understanding of event distributions while minimizing false detection rates.
format Preprint
id arxiv_https___arxiv_org_abs_2406_16938
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Unmixing Noise from Hawkes Process to Model Learned Physiological Events
Staerman, Guillaume
Loison, Virginie
Moreau, Thomas
Signal Processing
Machine Learning
Physiological signal analysis often involves identifying events crucial to understanding biological dynamics. Traditional methods rely on handcrafted procedures or supervised learning, presenting challenges such as expert dependence, lack of robustness, and the need for extensive labeled data. Data-driven methods like Convolutional Dictionary Learning (CDL) offer an alternative but tend to produce spurious detections. This work introduces UNHaP (Unmix Noise from Hawkes Processes), a novel approach addressing the joint learning of temporal structures in events and the removal of spurious detections. Leveraging marked Hawkes processes, UNHaP distinguishes between events of interest and spurious ones. By treating the event detection output as a mixture of structured and unstructured events, UNHaP efficiently unmixes these processes and estimates their parameters. This approach significantly enhances the understanding of event distributions while minimizing false detection rates.
title Unmixing Noise from Hawkes Process to Model Learned Physiological Events
topic Signal Processing
Machine Learning
url https://arxiv.org/abs/2406.16938