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Predictive Intelligence Across Physical and Financial Systems: A Comparative Research Framework for Packed-Bed Thermal Energy Storage and AI-Driven Forecasting

DOI https://doi.org/10.55640/
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Elena M. Kovacs 1 ,
4 Department of Systems Innovation, University of Debrecen, Hungary

Abstract

Background: Predictive modeling has become a central organizing principle in both engineering and finance, yet these domains are often studied in isolation despite their shared dependence on uncertainty reduction, multiscale dynamics, data interpretation, and decision support. The references provided for this study cover two major bodies of knowledge: packed-bed thermal energy storage and heat-transfer modeling, and artificial intelligence-based financial forecasting, risk modeling, and analytics. Together, they offer an opportunity to develop an integrated research interpretation of how predictive intelligence operates across materially different but structurally comparable systems.

Objective: This article develops a publication-ready comparative research framework that examines how predictive intelligence is constructed, validated, and operationalized in packed-bed thermal energy storage systems and AI-driven financial forecasting environments. The study seeks to identify convergent modeling logics, domain-specific differences, methodological limitations, and future interdisciplinary opportunities.

Methodology: A qualitative comparative research design was adopted using structured literature-based synthesis of the supplied references only. The analysis followed a text-based interpretive approach that organized the literature into themes related to system complexity, state observability, temporal prediction, uncertainty treatment, model validation, operational deployment, and governance. No external sources, equations, or numerical derivations were introduced.

Results: The analysis shows that both domains rely on layered representations of dynamic systems, where predictive performance depends on the interaction of data fidelity, model structure, physical or behavioral assumptions, and validation against real operating conditions. Packed-bed studies emphasize thermophysical realism, flow structure, multiscale heat and momentum transfer, material behavior, and operational cycling, while finance-focused studies emphasize pattern extraction, risk anticipation, data integration, interpretability, profitability, and regulatory alignment. Despite these differences, both literatures converge on the importance of hybrid modeling, context-aware prediction, sensitivity to operational regimes, and the need to bridge simulated performance with real-world decision environments.

Conclusion: The article argues that predictive intelligence should be understood not simply as algorithmic forecasting but as a broader epistemic and operational framework for managing complex systems under uncertainty. By comparing thermal energy storage and financial forecasting, the study proposes a cross-domain research agenda centered on robustness, explainability, adaptive validation, and responsible deployment.

Keywords

Predictive intelligence, packed-bed thermal energy storage, heat transfer, artificial intelligence

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