Saved in:
Bibliographic Details
Main Authors: Kjærnli, Håkon Hanisch, Mas-Ribas, Lluis, Håland, Hans Jakob, Sjåvik, Vegard, Ashrafi, Aida, Langseth, Helge, Gundersen, Odd Erik
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.03508
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913915663810560
author Kjærnli, Håkon Hanisch
Mas-Ribas, Lluis
Håland, Hans Jakob
Sjåvik, Vegard
Ashrafi, Aida
Langseth, Helge
Gundersen, Odd Erik
author_facet Kjærnli, Håkon Hanisch
Mas-Ribas, Lluis
Håland, Hans Jakob
Sjåvik, Vegard
Ashrafi, Aida
Langseth, Helge
Gundersen, Odd Erik
contents When deploying time series forecasting models based on machine learning to real world settings, one often encounter situations where the data distribution drifts. Such drifts expose the forecasting models to out-of-distribution (OOD) data, and machine learning models lack robustness in these settings. Robustness can be improved by using deep generative models or genetic algorithms to augment time series datasets, but these approaches lack interpretability and are computationally expensive. In this work, we develop an interpretable and simple framework for generating time series. Our method combines time-series decompositions with analytic functions, and is able to generate time series with characteristics matching both in- and out-of-distribution data. This approach allows users to generate new time series in an interpretable fashion, which can be used to augment the dataset and improve forecasting robustness. We demonstrate our framework through EXPRTS, a visual analytics tool designed for univariate time series forecasting models and datasets. Different visualizations of the data distribution, forecasting errors and single time series instances enable users to explore time series datasets, apply transformations, and evaluate forecasting model robustness across diverse scenarios. We show how our framework can generate meaningful OOD time series that improve model robustness, and we validate EXPRTS effectiveness and usability through three use-cases and a user study.
format Preprint
id arxiv_https___arxiv_org_abs_2403_03508
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle EXPRTS: Exploring and Probing the Robustness of Time Series Forecasting Models
Kjærnli, Håkon Hanisch
Mas-Ribas, Lluis
Håland, Hans Jakob
Sjåvik, Vegard
Ashrafi, Aida
Langseth, Helge
Gundersen, Odd Erik
Machine Learning
When deploying time series forecasting models based on machine learning to real world settings, one often encounter situations where the data distribution drifts. Such drifts expose the forecasting models to out-of-distribution (OOD) data, and machine learning models lack robustness in these settings. Robustness can be improved by using deep generative models or genetic algorithms to augment time series datasets, but these approaches lack interpretability and are computationally expensive. In this work, we develop an interpretable and simple framework for generating time series. Our method combines time-series decompositions with analytic functions, and is able to generate time series with characteristics matching both in- and out-of-distribution data. This approach allows users to generate new time series in an interpretable fashion, which can be used to augment the dataset and improve forecasting robustness. We demonstrate our framework through EXPRTS, a visual analytics tool designed for univariate time series forecasting models and datasets. Different visualizations of the data distribution, forecasting errors and single time series instances enable users to explore time series datasets, apply transformations, and evaluate forecasting model robustness across diverse scenarios. We show how our framework can generate meaningful OOD time series that improve model robustness, and we validate EXPRTS effectiveness and usability through three use-cases and a user study.
title EXPRTS: Exploring and Probing the Robustness of Time Series Forecasting Models
topic Machine Learning
url https://arxiv.org/abs/2403.03508