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Main Authors: Baumgartner, David, da Silva, Eliezer de Souza, Urteaga, Iñigo
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.11756
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author Baumgartner, David
da Silva, Eliezer de Souza
Urteaga, Iñigo
author_facet Baumgartner, David
da Silva, Eliezer de Souza
Urteaga, Iñigo
contents Deep generative models for anomaly detection in multivariate time-series are typically trained by maximizing data likelihood. However, likelihood in observation space measures marginal density rather than conformity to structured temporal dynamics, and therefore can assign high probability to anomalous or out-of-distribution samples. We address this structural limitation by relocating the notion of anomaly to a prescribed latent space. We introduce explicit inductive biases in conditional normalizing flows, modeling time-series observations within a discrete-time state-space framework that constrains latent representations to evolve according to prescribed temporal dynamics. Under this formulation, expected behavior corresponds to compliance with a specified distribution over latent trajectories, while anomalies are defined as violations of these dynamics. Anomaly detection is consequently reduced to a statistically grounded compliance test, such that observations are mapped to latent space and evaluated via goodness-of-fit tests against the prescribed latent evolution. This yields a principled decision rule that remains effective even in regions of high observation likelihood. Experiments on synthetic and real-world time-series demonstrate reliable detection of anomalies in frequency, amplitude, and observation noise, while providing interpretable diagnostics of model compliance.
format Preprint
id arxiv_https___arxiv_org_abs_2603_11756
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Anomaly detection in time-series via inductive biases in the latent space of conditional normalizing flows
Baumgartner, David
da Silva, Eliezer de Souza
Urteaga, Iñigo
Artificial Intelligence
Machine Learning
Deep generative models for anomaly detection in multivariate time-series are typically trained by maximizing data likelihood. However, likelihood in observation space measures marginal density rather than conformity to structured temporal dynamics, and therefore can assign high probability to anomalous or out-of-distribution samples. We address this structural limitation by relocating the notion of anomaly to a prescribed latent space. We introduce explicit inductive biases in conditional normalizing flows, modeling time-series observations within a discrete-time state-space framework that constrains latent representations to evolve according to prescribed temporal dynamics. Under this formulation, expected behavior corresponds to compliance with a specified distribution over latent trajectories, while anomalies are defined as violations of these dynamics. Anomaly detection is consequently reduced to a statistically grounded compliance test, such that observations are mapped to latent space and evaluated via goodness-of-fit tests against the prescribed latent evolution. This yields a principled decision rule that remains effective even in regions of high observation likelihood. Experiments on synthetic and real-world time-series demonstrate reliable detection of anomalies in frequency, amplitude, and observation noise, while providing interpretable diagnostics of model compliance.
title Anomaly detection in time-series via inductive biases in the latent space of conditional normalizing flows
topic Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2603.11756