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Main Authors: Lykkegaard, Mikkel Bue, Nielsen, Svend Vendelbo, Upadhyay, Akanksha, Copeland, Mikkel Bendixen, Trénell, Philipp
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.02606
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author Lykkegaard, Mikkel Bue
Nielsen, Svend Vendelbo
Upadhyay, Akanksha
Copeland, Mikkel Bendixen
Trénell, Philipp
author_facet Lykkegaard, Mikkel Bue
Nielsen, Svend Vendelbo
Upadhyay, Akanksha
Copeland, Mikkel Bendixen
Trénell, Philipp
contents Efficient time series forecasting is essential for smart energy systems, enabling accurate predictions of energy demand, renewable resource availability, and grid stability. However, the growing volume of high-frequency data from sensors and IoT devices poses challenges for storage and transmission. This study explores Discrete Wavelet Transform (DWT)-based data compression as a solution to these challenges while ensuring forecasting accuracy. A case study of a seawater supply system in Hirtshals, Denmark, operating under dynamic weather, operational schedules, and seasonal trends, is used for evaluation. Biorthogonal wavelets of varying orders were applied to compress data at different rates. Three forecasting models - Ordinary Least Squares (OLS), XGBoost, and the Time Series Dense Encoder (TiDE) - were tested to assess the impact of compression on forecasting performance. Lossy compression rates up to $r_{\mathrm{lossy}} = 0.999$ were analyzed, with the Normalized Mutual Information (NMI) metric quantifying the relationship between compression and information retention. Results indicate that wavelet-based compression can retain essential features for accurate forecasting when applied carefully. XGBoost proved highly robust to compression artifacts, maintaining stable performance across diverse compression rates. In contrast, OLS demonstrated sensitivity to smooth wavelets and high compression rates, while TiDE showed some variability but remained competitive. This study highlights the potential of wavelet-based compression for scalable, efficient data management in smart energy systems without sacrificing forecasting accuracy. The findings are relevant to other fields requiring high-frequency time series forecasting, including climate modeling, water supply systems, and industrial operations.
format Preprint
id arxiv_https___arxiv_org_abs_2505_02606
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Data Compression for Time Series Modelling: A Case Study of Smart Grid Demand Forecasting
Lykkegaard, Mikkel Bue
Nielsen, Svend Vendelbo
Upadhyay, Akanksha
Copeland, Mikkel Bendixen
Trénell, Philipp
Computational Engineering, Finance, and Science
Efficient time series forecasting is essential for smart energy systems, enabling accurate predictions of energy demand, renewable resource availability, and grid stability. However, the growing volume of high-frequency data from sensors and IoT devices poses challenges for storage and transmission. This study explores Discrete Wavelet Transform (DWT)-based data compression as a solution to these challenges while ensuring forecasting accuracy. A case study of a seawater supply system in Hirtshals, Denmark, operating under dynamic weather, operational schedules, and seasonal trends, is used for evaluation. Biorthogonal wavelets of varying orders were applied to compress data at different rates. Three forecasting models - Ordinary Least Squares (OLS), XGBoost, and the Time Series Dense Encoder (TiDE) - were tested to assess the impact of compression on forecasting performance. Lossy compression rates up to $r_{\mathrm{lossy}} = 0.999$ were analyzed, with the Normalized Mutual Information (NMI) metric quantifying the relationship between compression and information retention. Results indicate that wavelet-based compression can retain essential features for accurate forecasting when applied carefully. XGBoost proved highly robust to compression artifacts, maintaining stable performance across diverse compression rates. In contrast, OLS demonstrated sensitivity to smooth wavelets and high compression rates, while TiDE showed some variability but remained competitive. This study highlights the potential of wavelet-based compression for scalable, efficient data management in smart energy systems without sacrificing forecasting accuracy. The findings are relevant to other fields requiring high-frequency time series forecasting, including climate modeling, water supply systems, and industrial operations.
title Data Compression for Time Series Modelling: A Case Study of Smart Grid Demand Forecasting
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2505.02606