Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands

Inigo Lopez-Villamor; Olaia Eguiarte; Benat Arregi; Roberto Garay-Martinez; Juan Pablo Aguilar-Lopez; Leonardo Duarte-Campos

doi:10.23919/SpliTech65624.2025.11091657

Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands

Inigo Lopez-Villamor^*
, Olaia Eguiarte
, Benat Arregi
, Roberto Garay-Martinez
, Juan Pablo Aguilar-Lopez
, Leonardo Duarte-Campos

^*Autor correspondiente de este trabajo

University of Deusto
Delft University of Technology

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

Resumen

Extreme temperatures in urban environments exacerbate thermal discomfort and intensify the Urban Heat Island (UHI) effect, particularly during peak warm periods. Pavements, which constitute a significant portion of urban surfaces, contribute significantly to heat retention, whereas soil and vegetated areas aid in cooling through lower heat storage and higher moisture retention. Accurate forecasting of soil and pavement surface temperatures is critical for developing effective UHI mitigation strategies. This paper explores the application of Resistance-Capacitance (RC) models, a type of grey-box model, for soil surface temperature prediction. Unlike purely physics-based and data-driven models, RC models integrate physical principles with data-driven insights, balancing accuracy and interpretability. The proposed methodology is validated using real-world data from a dike in the Netherlands, where an optimal RC model is identified through an iterative process based on the Akaike Information Criterion (AIC). Results demonstrate that a two-node RC model provides a reliable balance between complexity and predictive accuracy, achieving an R² of 0.862 and a mean absolute error (MAE) of 0.675°C. These findings highlight the feasibility of applying RC models for soil temperature prediction while maintaining physical interpretability. Future research could extend this methodology to various soil types and urban surfaces, including pavements, to further enhance predictive capabilities and inform climate-responsive urban design.

Idioma original	Inglés
Título de la publicación alojada	2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025
Editores	Petar Solic, Sandro Nizetic, Joel J. P. C. Rodrigues, Joel J. P. C. Rodrigues, Joel J.P.C. Rodrigues, Diego Lopez-de-Ipina Gonzalez-de-Artaza, Toni Perkovic, Katarina Vukojevic, Luca Catarinucci, Luigi Patrono
Editorial	Institute of Electrical and Electronics Engineers Inc.
ISBN (versión digital)	9789532901429
DOI	https://doi.org/10.23919/SpliTech65624.2025.11091657
Estado	Publicada - 2025
Evento	10th International Conference on Smart and Sustainable Technologies, SpliTech 2025 - Split, Croacia Duración: 16 jun 2025 → 20 jun 2025

Serie de la publicación

Nombre	2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025

Conferencia

Conferencia	10th International Conference on Smart and Sustainable Technologies, SpliTech 2025
País/Territorio	Croacia
Ciudad	Split
Período	16/06/25 → 20/06/25

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

ODS 11: Ciudades y comunidades sostenibles

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10.23919/SpliTech65624.2025.11091657

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Lopez-Villamor, I., Eguiarte, O., Arregi, B., Garay-Martinez, R., Aguilar-Lopez, J. P., & Duarte-Campos, L. (2025). Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands. En P. Solic, S. Nizetic, J. J. P. C. Rodrigues, J. J. P. C. Rodrigues, J. J. P. C. Rodrigues, D. Lopez-de-Ipina Gonzalez-de-Artaza, T. Perkovic, K. Vukojevic, L. Catarinucci, & L. Patrono (Eds.), 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025 (2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.23919/SpliTech65624.2025.11091657

Lopez-Villamor, Inigo ; Eguiarte, Olaia ; Arregi, Benat et al. / Application of resistance-capacitance (RC) models to predict soil surface temperature : A case study in the Netherlands. 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025. editor / Petar Solic ; Sandro Nizetic ; Joel J. P. C. Rodrigues ; Joel J. P. C. Rodrigues ; Joel J.P.C. Rodrigues ; Diego Lopez-de-Ipina Gonzalez-de-Artaza ; Toni Perkovic ; Katarina Vukojevic ; Luca Catarinucci ; Luigi Patrono. Institute of Electrical and Electronics Engineers Inc., 2025. (2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025).

@inproceedings{799bf9202b4d49e5a460f98450f66103,

title = "Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands",

abstract = "Extreme temperatures in urban environments exacerbate thermal discomfort and intensify the Urban Heat Island (UHI) effect, particularly during peak warm periods. Pavements, which constitute a significant portion of urban surfaces, contribute significantly to heat retention, whereas soil and vegetated areas aid in cooling through lower heat storage and higher moisture retention. Accurate forecasting of soil and pavement surface temperatures is critical for developing effective UHI mitigation strategies. This paper explores the application of Resistance-Capacitance (RC) models, a type of grey-box model, for soil surface temperature prediction. Unlike purely physics-based and data-driven models, RC models integrate physical principles with data-driven insights, balancing accuracy and interpretability. The proposed methodology is validated using real-world data from a dike in the Netherlands, where an optimal RC model is identified through an iterative process based on the Akaike Information Criterion (AIC). Results demonstrate that a two-node RC model provides a reliable balance between complexity and predictive accuracy, achieving an R2 of 0.862 and a mean absolute error (MAE) of 0.675°C. These findings highlight the feasibility of applying RC models for soil temperature prediction while maintaining physical interpretability. Future research could extend this methodology to various soil types and urban surfaces, including pavements, to further enhance predictive capabilities and inform climate-responsive urban design.",

keywords = "RC models, Urban Heat Island, pavement, soil, surface temperature prediction",

author = "Inigo Lopez-Villamor and Olaia Eguiarte and Benat Arregi and Roberto Garay-Martinez and Aguilar-Lopez, \{Juan Pablo\} and Leonardo Duarte-Campos",

note = "Publisher Copyright: {\textcopyright} 2025 University of Split, FESB.; 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025 ; Conference date: 16-06-2025 Through 20-06-2025",

year = "2025",

doi = "10.23919/SpliTech65624.2025.11091657",

language = "English",

series = "2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

editor = "Petar Solic and Sandro Nizetic and Rodrigues, \{Joel J. P. C.\} and Rodrigues, \{Joel J. P. C.\} and Rodrigues, \{Joel J.P.C.\} and \{Lopez-de-Ipina Gonzalez-de-Artaza\}, Diego and Toni Perkovic and Katarina Vukojevic and Luca Catarinucci and Luigi Patrono",

booktitle = "2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025",

address = "United States",

}

Lopez-Villamor, I, Eguiarte, O, Arregi, B, Garay-Martinez, R, Aguilar-Lopez, JP & Duarte-Campos, L 2025, Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands. En P Solic, S Nizetic, JJPC Rodrigues, JJPC Rodrigues, JJPC Rodrigues, D Lopez-de-Ipina Gonzalez-de-Artaza, T Perkovic, K Vukojevic, L Catarinucci & L Patrono (eds.), 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025. 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025, Institute of Electrical and Electronics Engineers Inc., 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025, Split, Croacia, 16/06/25. https://doi.org/10.23919/SpliTech65624.2025.11091657

Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands. / Lopez-Villamor, Inigo; Eguiarte, Olaia; Arregi, Benat et al.
2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025. ed. / Petar Solic; Sandro Nizetic; Joel J. P. C. Rodrigues; Joel J. P. C. Rodrigues; Joel J.P.C. Rodrigues; Diego Lopez-de-Ipina Gonzalez-de-Artaza; Toni Perkovic; Katarina Vukojevic; Luca Catarinucci; Luigi Patrono. Institute of Electrical and Electronics Engineers Inc., 2025. (2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025).

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

TY - GEN

T1 - Application of resistance-capacitance (RC) models to predict soil surface temperature

T2 - 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025

AU - Lopez-Villamor, Inigo

AU - Eguiarte, Olaia

AU - Arregi, Benat

AU - Garay-Martinez, Roberto

AU - Aguilar-Lopez, Juan Pablo

AU - Duarte-Campos, Leonardo

PY - 2025

Y1 - 2025

N2 - Extreme temperatures in urban environments exacerbate thermal discomfort and intensify the Urban Heat Island (UHI) effect, particularly during peak warm periods. Pavements, which constitute a significant portion of urban surfaces, contribute significantly to heat retention, whereas soil and vegetated areas aid in cooling through lower heat storage and higher moisture retention. Accurate forecasting of soil and pavement surface temperatures is critical for developing effective UHI mitigation strategies. This paper explores the application of Resistance-Capacitance (RC) models, a type of grey-box model, for soil surface temperature prediction. Unlike purely physics-based and data-driven models, RC models integrate physical principles with data-driven insights, balancing accuracy and interpretability. The proposed methodology is validated using real-world data from a dike in the Netherlands, where an optimal RC model is identified through an iterative process based on the Akaike Information Criterion (AIC). Results demonstrate that a two-node RC model provides a reliable balance between complexity and predictive accuracy, achieving an R2 of 0.862 and a mean absolute error (MAE) of 0.675°C. These findings highlight the feasibility of applying RC models for soil temperature prediction while maintaining physical interpretability. Future research could extend this methodology to various soil types and urban surfaces, including pavements, to further enhance predictive capabilities and inform climate-responsive urban design.

AB - Extreme temperatures in urban environments exacerbate thermal discomfort and intensify the Urban Heat Island (UHI) effect, particularly during peak warm periods. Pavements, which constitute a significant portion of urban surfaces, contribute significantly to heat retention, whereas soil and vegetated areas aid in cooling through lower heat storage and higher moisture retention. Accurate forecasting of soil and pavement surface temperatures is critical for developing effective UHI mitigation strategies. This paper explores the application of Resistance-Capacitance (RC) models, a type of grey-box model, for soil surface temperature prediction. Unlike purely physics-based and data-driven models, RC models integrate physical principles with data-driven insights, balancing accuracy and interpretability. The proposed methodology is validated using real-world data from a dike in the Netherlands, where an optimal RC model is identified through an iterative process based on the Akaike Information Criterion (AIC). Results demonstrate that a two-node RC model provides a reliable balance between complexity and predictive accuracy, achieving an R2 of 0.862 and a mean absolute error (MAE) of 0.675°C. These findings highlight the feasibility of applying RC models for soil temperature prediction while maintaining physical interpretability. Future research could extend this methodology to various soil types and urban surfaces, including pavements, to further enhance predictive capabilities and inform climate-responsive urban design.

KW - RC models

KW - Urban Heat Island

KW - pavement

KW - soil

KW - surface temperature prediction

UR - https://www.scopus.com/pages/publications/105013471634

U2 - 10.23919/SpliTech65624.2025.11091657

DO - 10.23919/SpliTech65624.2025.11091657

M3 - Conference contribution

AN - SCOPUS:105013471634

T3 - 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025

BT - 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025

A2 - Solic, Petar

A2 - Nizetic, Sandro

A2 - Rodrigues, Joel J. P. C.

A2 - Rodrigues, Joel J.P.C.

A2 - Lopez-de-Ipina Gonzalez-de-Artaza, Diego

A2 - Perkovic, Toni

A2 - Vukojevic, Katarina

A2 - Catarinucci, Luca

A2 - Patrono, Luigi

PB - Institute of Electrical and Electronics Engineers Inc.

Y2 - 16 June 2025 through 20 June 2025

ER -

Lopez-Villamor I, Eguiarte O, Arregi B, Garay-Martinez R, Aguilar-Lopez JP, Duarte-Campos L. Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands. En Solic P, Nizetic S, Rodrigues JJPC, Rodrigues JJPC, Rodrigues JJPC, Lopez-de-Ipina Gonzalez-de-Artaza D, Perkovic T, Vukojevic K, Catarinucci L, Patrono L, editores, 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025. Institute of Electrical and Electronics Engineers Inc. 2025. (2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025). doi: 10.23919/SpliTech65624.2025.11091657

Application of resistance-capacitance (RC) models to predict soil surface temperature: A case study in the Netherlands

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