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Main Authors: Mabrouk, Mohamed Tahar, Padmanabhan, Shri Balaji, Lacarrière, Bruno, Delinchant, Benoit, Hodencq, Sacha, Roboam, Xavier, Sareni, Bruno, Vallee, Mathieu
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.05585
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author Mabrouk, Mohamed Tahar
Padmanabhan, Shri Balaji
Lacarrière, Bruno
Delinchant, Benoit
Hodencq, Sacha
Roboam, Xavier
Sareni, Bruno
Vallee, Mathieu
author_facet Mabrouk, Mohamed Tahar
Padmanabhan, Shri Balaji
Lacarrière, Bruno
Delinchant, Benoit
Hodencq, Sacha
Roboam, Xavier
Sareni, Bruno
Vallee, Mathieu
contents This paper surveys the primary computational hurdles of Energy Systems optimization coming from different sources: model-induced complexity, optimization algorithm requirements, and uncertainties handling (both aleatoric and epistemic). Techniques to reduce complexity such as time-series and spatial aggregation, model order reduction, and specialized optimization strategies are reviewed for their effectiveness in balancing computational feasibility and model fidelity. Furthermore, Various uncertainty-management frameworks, including scenario-based approaches, robust optimization, and distributionally robust methods, are reviewed and their limitations in scaling and data requirements are discussed. The potential of hybrid modeling emerges as a key avenue: by fusing mechanistic and machine learning elements, hybrid techniques for modelling and optimization can harness the strengths of both worlds while mitigating their respective drawbacks. The paper highlights several directions for further research to develop advanced methods to tackle the complexity of MES.
format Preprint
id arxiv_https___arxiv_org_abs_2512_05585
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Opportunities for Hybrid Modeling Approaches in Energy Systems optimization
Mabrouk, Mohamed Tahar
Padmanabhan, Shri Balaji
Lacarrière, Bruno
Delinchant, Benoit
Hodencq, Sacha
Roboam, Xavier
Sareni, Bruno
Vallee, Mathieu
Optimization and Control
This paper surveys the primary computational hurdles of Energy Systems optimization coming from different sources: model-induced complexity, optimization algorithm requirements, and uncertainties handling (both aleatoric and epistemic). Techniques to reduce complexity such as time-series and spatial aggregation, model order reduction, and specialized optimization strategies are reviewed for their effectiveness in balancing computational feasibility and model fidelity. Furthermore, Various uncertainty-management frameworks, including scenario-based approaches, robust optimization, and distributionally robust methods, are reviewed and their limitations in scaling and data requirements are discussed. The potential of hybrid modeling emerges as a key avenue: by fusing mechanistic and machine learning elements, hybrid techniques for modelling and optimization can harness the strengths of both worlds while mitigating their respective drawbacks. The paper highlights several directions for further research to develop advanced methods to tackle the complexity of MES.
title Opportunities for Hybrid Modeling Approaches in Energy Systems optimization
topic Optimization and Control
url https://arxiv.org/abs/2512.05585