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Auteurs principaux: Kim, Changhun, Mun, Yechan, Jang, Hyeongwon, Lee, Eunseo, Hahn, Sangchul, Yang, Eunho
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2511.23036
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author Kim, Changhun
Mun, Yechan
Jang, Hyeongwon
Lee, Eunseo
Hahn, Sangchul
Yang, Eunho
author_facet Kim, Changhun
Mun, Yechan
Jang, Hyeongwon
Lee, Eunseo
Hahn, Sangchul
Yang, Eunho
contents Explaining online time series monitoring models is crucial across sensitive domains such as healthcare and finance, where temporal and contextual prediction dynamics underpin critical decisions. While recent XAI methods have improved the explainability of time series models, they mostly analyze each time step independently, overlooking temporal dependencies. This results in further challenges: explaining prediction changes is non-trivial, methods fail to leverage online dynamics, and evaluation remains difficult. To address these challenges, we propose Delta-XAI, which adapts 14 existing XAI methods through a wrapper function and introduces a principled evaluation suite for the online setting, assessing diverse aspects, such as faithfulness, sufficiency, and coherence. Experiments reveal that classical gradient-based methods, such as Integrated Gradients (IG), can outperform recent approaches when adapted for temporal analysis. Building on this, we propose Shifted Window Integrated Gradients (SWING), which incorporates past observations in the integration path to systematically capture temporal dependencies and mitigate out-of-distribution effects. Extensive experiments consistently demonstrate the effectiveness of SWING across diverse settings with respect to diverse metrics. Our code is publicly available at https://github.com/AITRICS/Delta-XAI.
format Preprint
id arxiv_https___arxiv_org_abs_2511_23036
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Delta-XAI: A Unified Framework for Explaining Prediction Changes in Online Time Series Monitoring
Kim, Changhun
Mun, Yechan
Jang, Hyeongwon
Lee, Eunseo
Hahn, Sangchul
Yang, Eunho
Machine Learning
Artificial Intelligence
Explaining online time series monitoring models is crucial across sensitive domains such as healthcare and finance, where temporal and contextual prediction dynamics underpin critical decisions. While recent XAI methods have improved the explainability of time series models, they mostly analyze each time step independently, overlooking temporal dependencies. This results in further challenges: explaining prediction changes is non-trivial, methods fail to leverage online dynamics, and evaluation remains difficult. To address these challenges, we propose Delta-XAI, which adapts 14 existing XAI methods through a wrapper function and introduces a principled evaluation suite for the online setting, assessing diverse aspects, such as faithfulness, sufficiency, and coherence. Experiments reveal that classical gradient-based methods, such as Integrated Gradients (IG), can outperform recent approaches when adapted for temporal analysis. Building on this, we propose Shifted Window Integrated Gradients (SWING), which incorporates past observations in the integration path to systematically capture temporal dependencies and mitigate out-of-distribution effects. Extensive experiments consistently demonstrate the effectiveness of SWING across diverse settings with respect to diverse metrics. Our code is publicly available at https://github.com/AITRICS/Delta-XAI.
title Delta-XAI: A Unified Framework for Explaining Prediction Changes in Online Time Series Monitoring
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2511.23036