Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Al-Shareeda, Sarah, Ozdemir, Gulcihan, Jeon, Heung Seok, Ahmad, Khaleel
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2510.16911
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866912659462422528
author Al-Shareeda, Sarah
Ozdemir, Gulcihan
Jeon, Heung Seok
Ahmad, Khaleel
author_facet Al-Shareeda, Sarah
Ozdemir, Gulcihan
Jeon, Heung Seok
Ahmad, Khaleel
contents How can short-term energy consumption be accurately forecasted when sensor data is noisy, incomplete, and lacks contextual richness? This question guided our participation in the \textit{2025 Competition on Electric Energy Consumption Forecast Adopting Multi-criteria Performance Metrics}, which challenged teams to predict next-day power demand using real-world high-frequency data. We proposed a robust yet lightweight Deep Learning (DL) pipeline combining hourly downsizing, dual-mode imputation (mean and polynomial regression), and comprehensive normalization, ultimately selecting Standard Scaling for optimal balance. The lightweight GRU-LSTM sequence-to-one model achieves an average RMSE of 601.9~W, MAE of 468.9~W, and 84.36\% accuracy. Despite asymmetric inputs and imputed gaps, it generalized well, captured nonlinear demand patterns, and maintained low inference latency. Notably, spatiotemporal heatmap analysis reveals a strong alignment between temperature trends and predicted consumption, further reinforcing the model's reliability. These results demonstrate that targeted preprocessing paired with compact recurrent architectures can still enable fast, accurate, and deployment-ready energy forecasting in real-world conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2510_16911
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Lightweight DL Model for Smart Grid Power Forecasting with Feature and Resolution Mismatch
Al-Shareeda, Sarah
Ozdemir, Gulcihan
Jeon, Heung Seok
Ahmad, Khaleel
Machine Learning
Artificial Intelligence
How can short-term energy consumption be accurately forecasted when sensor data is noisy, incomplete, and lacks contextual richness? This question guided our participation in the \textit{2025 Competition on Electric Energy Consumption Forecast Adopting Multi-criteria Performance Metrics}, which challenged teams to predict next-day power demand using real-world high-frequency data. We proposed a robust yet lightweight Deep Learning (DL) pipeline combining hourly downsizing, dual-mode imputation (mean and polynomial regression), and comprehensive normalization, ultimately selecting Standard Scaling for optimal balance. The lightweight GRU-LSTM sequence-to-one model achieves an average RMSE of 601.9~W, MAE of 468.9~W, and 84.36\% accuracy. Despite asymmetric inputs and imputed gaps, it generalized well, captured nonlinear demand patterns, and maintained low inference latency. Notably, spatiotemporal heatmap analysis reveals a strong alignment between temperature trends and predicted consumption, further reinforcing the model's reliability. These results demonstrate that targeted preprocessing paired with compact recurrent architectures can still enable fast, accurate, and deployment-ready energy forecasting in real-world conditions.
title A Lightweight DL Model for Smart Grid Power Forecasting with Feature and Resolution Mismatch
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2510.16911