An artificial intelligence framework for explainable drift detection in energy forecasting

Chamod Samarajeewa; Daswin De Silva; Milos Manic; Nishan Mills; Harsha Moraliyage; Damminda Alahakoon; Andrew Jennings

Energy and AI (Sep 2024)

An artificial intelligence framework for explainable drift detection in energy forecasting

Chamod Samarajeewa,
Daswin De Silva,
Milos Manic,
Nishan Mills,
Harsha Moraliyage,
Damminda Alahakoon,
Andrew Jennings

Affiliations

Chamod Samarajeewa: Centre for Data Analytics and Cognition, La Trobe University, Australia
Daswin De Silva: Centre for Data Analytics and Cognition, La Trobe University, Australia; Corresponding author.
Milos Manic: Department of Computer Science, Virginia Commonwealth University, Richmond, USA
Nishan Mills: Centre for Data Analytics and Cognition, La Trobe University, Australia
Harsha Moraliyage: Centre for Data Analytics and Cognition, La Trobe University, Australia
Damminda Alahakoon: Centre for Data Analytics and Cognition, La Trobe University, Australia
Andrew Jennings: Centre for Data Analytics and Cognition, La Trobe University, Australia

Journal volume & issue: Vol. 17
p. 100403

Abstract

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Accurate energy consumption forecasting is crucial for reducing operational costs, achieving net-zero carbon emissions, and ensuring sustainable buildings and cities of the future. Despite the frequent use of Artificial Intelligence (AI) algorithms for learning energy consumption patterns and predictions in Building Science, relying solely on these techniques for energy demand prediction addresses only a fraction of the challenge. A drift in energy usage can lead to inaccuracies in these AI models and subsequently to poor decision-making and interventions. While drift detection techniques have been reported, a reliable and robust approach capable of explaining identified discrepancies with actionable insights has not been discussed in extant literature. Hence, this paper presents an Artificial Intelligence framework for energy consumption forecasting with explainable drift detection, aimed at addressing these challenges. The proposed framework is composed of energy embeddings, an optimized dimensional model integrated within a data warehouse, and scalable cloud implementation for effective drift detection with explainability capability. The framework is empirically evaluated in the real-world setting of a multi-campus, mixed-use tertiary education setting in Victoria, Australia. The results of these experiments highlight its capabilities in detecting concept drift, adapting forecast predictions, and providing an interpretation of the changes using energy embeddings.

Published in Energy and AI

ISSN: 2666-5468 (Online)
Publisher: Elsevier
Country of publisher: United Kingdom
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering; Science: Mathematics: Instruments and machines: Electronic computers. Computer science: Computer software
Website: https://www.journals.elsevier.com/energy-and-ai

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