Coupling between detailed building energy models and a data driven urban canopy model

Miguel Martin; Mario Berges; Jantien Stoter; Clara Garcia Sanchez

Coupling between detailed building energy models and a data driven urban canopy model

Miguel Martin, Mario Berges, Jantien Stoter, Clara Garcia Sanchez

Urban Data Science

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

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Abstract

This paper describes a data driven urban canopy model that can be coupled with detailed building energy models. The data driven model is used to assess the outdoor air temperature and humidity in a street canyon considering as inputs weather conditions at the atmospheric layer, the surface temperature of surrounding building facades and the street, and the heat released from the use of air-conditioning. Predictions made by the model were tested using measurements of the outdoor air temperature and humidity collected between April and August 2019 in Singapore. Results show that the model estimates the outdoor air temperature with a similar accuracy than others that were validated using the same input and test data, while providing estimates with a higher temporal resolution and considering urban morphology with a higher fidelity. They also demonstrate that the model can predict the impact of waste heat releases and cool pavement on the outdoor air temperature and building energy consumption. In the future, vegetation could be considered as an input of the model if the land surface temperature is measured using an infrared thermal camera. Another improvement would be to define weather conditions at the atmospheric layer from rooftop measurements or a climate model.

Original language	English
Title of host publication	PLEA 2024: (Re)Thinking Resilience
Subtitle of host publication	The Book of Proceedings
Editors	Barbara Widera, Marta Rudnicka-Bogusz, Jakub Onyszkiewicz, Agata Woźniczka
Place of Publication	Wrocław
Publisher	Wroclaw University of Technology
Pages	729-734
Number of pages	6
ISBN (Print)	978-83-7493-275-2
Publication status	Published - 2024
Event	Passive and Low Energy Architecture: (RE)THINKING RESILIENCE - Wroclaw, Poland Duration: 25 Jun 2024 → 28 Jun 2024 Conference number: 37 https://plea2024.pl/

Conference

Conference	Passive and Low Energy Architecture
Abbreviated title	PLEA2024
Country/Territory	Poland
City	Wroclaw
Period	25/06/24 → 28/06/24
Internet address	https://plea2024.pl/

Keywords

Urban heat island
Urban canopy modelling
Building energy modelling
Machine learning
Mitigation strategies

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

PLEA2024_BOOK OF PROCEEDINGS-1Final published version, 1.05 MB

Cite this

@inproceedings{dfdc5aec7adf4bb995b0f56963c86c04,

title = "Coupling between detailed building energy models and a data driven urban canopy model",

abstract = "This paper describes a data driven urban canopy model that can be coupled with detailed building energy models. The data driven model is used to assess the outdoor air temperature and humidity in a street canyon considering as inputs weather conditions at the atmospheric layer, the surface temperature of surrounding building facades and the street, and the heat released from the use of air-conditioning. Predictions made by the model were tested using measurements of the outdoor air temperature and humidity collected between April and August 2019 in Singapore. Results show that the model estimates the outdoor air temperature with a similar accuracy than others that were validated using the same input and test data, while providing estimates with a higher temporal resolution and considering urban morphology with a higher fidelity. They also demonstrate that the model can predict the impact of waste heat releases and cool pavement on the outdoor air temperature and building energy consumption. In the future, vegetation could be considered as an input of the model if the land surface temperature is measured using an infrared thermal camera. Another improvement would be to define weather conditions at the atmospheric layer from rooftop measurements or a climate model.",

keywords = "Urban heat island, Urban canopy modelling, Building energy modelling, Machine learning, Mitigation strategies",

author = "Miguel Martin and Mario Berges and Jantien Stoter and {Garcia Sanchez}, Clara",

year = "2024",

language = "English",

isbn = "978-83-7493-275-2",

pages = "729--734",

editor = "Widera, {Barbara } and Marta Rudnicka-Bogusz and Jakub Onyszkiewicz and Agata Wo{\'z}niczka",

booktitle = "PLEA 2024: (Re)Thinking Resilience",

publisher = "Wroclaw University of Technology",

note = "Passive and Low Energy Architecture : (RE)THINKING RESILIENCE, PLEA2024 ; Conference date: 25-06-2024 Through 28-06-2024",

url = "https://plea2024.pl/",

}

Martin, M, Berges, M, Stoter, J & Garcia Sanchez, C 2024, Coupling between detailed building energy models and a data driven urban canopy model. in B Widera, M Rudnicka-Bogusz, J Onyszkiewicz & A Woźniczka (eds), PLEA 2024: (Re)Thinking Resilience: The Book of Proceedings. Wroclaw University of Technology, Wrocław, pp. 729-734, Passive and Low Energy Architecture, Wroclaw, Poland, 25/06/24.

Coupling between detailed building energy models and a data driven urban canopy model. / Martin, Miguel; Berges, Mario; Stoter, Jantien et al.
PLEA 2024: (Re)Thinking Resilience: The Book of Proceedings. ed. / Barbara Widera; Marta Rudnicka-Bogusz; Jakub Onyszkiewicz; Agata Woźniczka. Wrocław: Wroclaw University of Technology, 2024. p. 729-734.

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Coupling between detailed building energy models and a data driven urban canopy model

AU - Martin, Miguel

AU - Berges, Mario

AU - Stoter, Jantien

AU - Garcia Sanchez, Clara

N1 - Conference code: 37

PY - 2024

Y1 - 2024

N2 - This paper describes a data driven urban canopy model that can be coupled with detailed building energy models. The data driven model is used to assess the outdoor air temperature and humidity in a street canyon considering as inputs weather conditions at the atmospheric layer, the surface temperature of surrounding building facades and the street, and the heat released from the use of air-conditioning. Predictions made by the model were tested using measurements of the outdoor air temperature and humidity collected between April and August 2019 in Singapore. Results show that the model estimates the outdoor air temperature with a similar accuracy than others that were validated using the same input and test data, while providing estimates with a higher temporal resolution and considering urban morphology with a higher fidelity. They also demonstrate that the model can predict the impact of waste heat releases and cool pavement on the outdoor air temperature and building energy consumption. In the future, vegetation could be considered as an input of the model if the land surface temperature is measured using an infrared thermal camera. Another improvement would be to define weather conditions at the atmospheric layer from rooftop measurements or a climate model.

AB - This paper describes a data driven urban canopy model that can be coupled with detailed building energy models. The data driven model is used to assess the outdoor air temperature and humidity in a street canyon considering as inputs weather conditions at the atmospheric layer, the surface temperature of surrounding building facades and the street, and the heat released from the use of air-conditioning. Predictions made by the model were tested using measurements of the outdoor air temperature and humidity collected between April and August 2019 in Singapore. Results show that the model estimates the outdoor air temperature with a similar accuracy than others that were validated using the same input and test data, while providing estimates with a higher temporal resolution and considering urban morphology with a higher fidelity. They also demonstrate that the model can predict the impact of waste heat releases and cool pavement on the outdoor air temperature and building energy consumption. In the future, vegetation could be considered as an input of the model if the land surface temperature is measured using an infrared thermal camera. Another improvement would be to define weather conditions at the atmospheric layer from rooftop measurements or a climate model.

KW - Urban heat island

KW - Urban canopy modelling

KW - Building energy modelling

KW - Machine learning

KW - Mitigation strategies

UR - https://doi.org/10.37190/PLEA_2024

M3 - Conference contribution

SN - 978-83-7493-275-2

SP - 729

EP - 734

BT - PLEA 2024: (Re)Thinking Resilience

A2 - Widera, Barbara

A2 - Rudnicka-Bogusz, Marta

A2 - Onyszkiewicz, Jakub

A2 - Woźniczka, Agata

PB - Wroclaw University of Technology

CY - Wrocław

T2 - Passive and Low Energy Architecture

Y2 - 25 June 2024 through 28 June 2024

ER -

Coupling between detailed building energy models and a data driven urban canopy model

Abstract

Conference

Keywords

UN SDGs

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