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Main Authors: Ma, Chutian, Pomazkin, Grigorii, Saggese, Giacinto Paolo, Smith, Paul
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.11653
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author Ma, Chutian
Pomazkin, Grigorii
Saggese, Giacinto Paolo
Smith, Paul
author_facet Ma, Chutian
Pomazkin, Grigorii
Saggese, Giacinto Paolo
Smith, Paul
contents Energy demand prediction is critical for grid operators, industrial energy consumers, and service providers. Energy demand is influenced by multiple factors, including weather conditions (e.g. temperature, humidity, wind speed, solar radiation), and calendar information (e.g. hour of day and month of year), which further affect daily work and life schedules. These factors are causally interdependent, making the problem more complex than simple correlation-based learning techniques satisfactorily allow for. We propose a structural causal model that explains the causal relationship between these variables. A full analysis is performed to validate our causal beliefs, also revealing important insights consistent with prior studies. For example, our causal model reveals that energy demand responds to temperature fluctuations with season-dependent sensitivity. Additionally, we find that energy demand exhibits lower variance in winter due to the decoupling effect between temperature changes and daily activity patterns. We then build a Bayesian model, which takes advantage of the causal insights we learned as prior knowledge. The model is trained and tested on unseen data and yields state-of-the-art performance in the form of a 3.84 percent MAPE on the test set. The model also demonstrates strong robustness, as the cross-validation across two years of data yields an average MAPE of 3.88 percent.
format Preprint
id arxiv_https___arxiv_org_abs_2512_11653
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Causal Inference in Energy Demand Prediction
Ma, Chutian
Pomazkin, Grigorii
Saggese, Giacinto Paolo
Smith, Paul
Artificial Intelligence
Energy demand prediction is critical for grid operators, industrial energy consumers, and service providers. Energy demand is influenced by multiple factors, including weather conditions (e.g. temperature, humidity, wind speed, solar radiation), and calendar information (e.g. hour of day and month of year), which further affect daily work and life schedules. These factors are causally interdependent, making the problem more complex than simple correlation-based learning techniques satisfactorily allow for. We propose a structural causal model that explains the causal relationship between these variables. A full analysis is performed to validate our causal beliefs, also revealing important insights consistent with prior studies. For example, our causal model reveals that energy demand responds to temperature fluctuations with season-dependent sensitivity. Additionally, we find that energy demand exhibits lower variance in winter due to the decoupling effect between temperature changes and daily activity patterns. We then build a Bayesian model, which takes advantage of the causal insights we learned as prior knowledge. The model is trained and tested on unseen data and yields state-of-the-art performance in the form of a 3.84 percent MAPE on the test set. The model also demonstrates strong robustness, as the cross-validation across two years of data yields an average MAPE of 3.88 percent.
title Causal Inference in Energy Demand Prediction
topic Artificial Intelligence
url https://arxiv.org/abs/2512.11653