Predictive Modeling of Vehicle Emissions Using Deep Learning Techniques and AERMOD

Elif Yavuz; Alihan Öztürk; Nedime Gaye Nur Balkanlı; Şeref Naci Engin; S. Levent Kuzu

doi:10.1007/978-3-032-02971-3_50

Predictive Modeling of Vehicle Emissions Using Deep Learning Techniques and AERMOD

Elif Yavuz^*
, Alihan Öztürk
, Nedime Gaye Nur Balkanlı
, Şeref Naci Engin
, S. Levent Kuzu

^*Corresponding author for this work

Department of Environmental Engineering

Yildiz Technical University
Istanbul Technical University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Real-time vehicle detection not only enables accurate counting and tracking of vehicles on the road but also provides valuable data for analyzing traffic patterns and vehicle-related emissions. Simultaneously, calculating vehicular emissions is crucial for assessing environmental impact and implementing pollution reduction strategies. These combined efforts play a pivotal role in enhancing transportation systems and creating a more sustainable infrastructure. In this study, we employed a real-time vehicle detection system based on deep learning. During rush hour traffic, vehicles traversing Beşiktaş-Barbaros Boulevard in Istanbul, Türkiye, were counted using the YOLO (You Only Look Once) version 8 (YOLOv8) and SORT (Simple Online and Real-time Tracking) algorithm based on video recordings. The system was trained using a custom ISTraffic dataset which includes 36,841 annotated instances across 1,125 images, covering various vehicle classes such as cars, shuttles, buses, and motorcycles. The proposed algorithm exhibited outstanding performance, achieving a mean average precision (mAP) of 0.903 at a confidence threshold of 0.5. It achieved a precision of 1.00 and a recall of 0.91. Furthermore, we calculated vehicle-related pollutant emissions, including CO, NO, NO₂,NO_x, and PM₁₀, using the COPERT program following the Tier 3 methodology. These emissions data were then used as input for the AERMOD model. AERMOD CO 2180 µg/m³, NO 2848 µg/m³,NO₂ 1373 µg/m³,NO_x 4222 µg/m³,PM₁₀ 155 µg/ m³ . By combining deep learning techniques with AERMOD, our research aims to improve predictive modeling of air quality impacts from transportation activities.

Original language	English
Title of host publication	Air Pollution Modeling and Its Application XXX
Editors	Clemens Mensink, Ulas Im
Publisher	Springer Science and Business Media B.V.
Pages	395-403
Number of pages	9
ISBN (Print)	9783032029706
DOIs	https://doi.org/10.1007/978-3-032-02971-3_50
Publication status	Published - 2026
Event	40th International Technical Meeting on Air Pollution Modeling, ITM 2024 - Copenhagen, Denmark Duration: 14 Oct 2024 → 18 Oct 2024

Publication series

Name	Springer Proceedings in Complexity
ISSN (Print)	2213-8684
ISSN (Electronic)	2213-8692

Conference

Conference	40th International Technical Meeting on Air Pollution Modeling, ITM 2024
Country/Territory	Denmark
City	Copenhagen
Period	14/10/24 → 18/10/24

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.

Keywords

AERMOD
COPERT
Deep learning
Vehicle emissions
YOLO

Access to Document

10.1007/978-3-032-02971-3_50

Cite this

Yavuz, E., Öztürk, A., Balkanlı, N. G. N., Engin, Ş. N., & Kuzu, S. L. (2026). Predictive Modeling of Vehicle Emissions Using Deep Learning Techniques and AERMOD. In C. Mensink, & U. Im (Eds.), Air Pollution Modeling and Its Application XXX (pp. 395-403). (Springer Proceedings in Complexity). Springer Science and Business Media B.V.. https://doi.org/10.1007/978-3-032-02971-3_50

@inproceedings{8dc35aca99ed434692aafd103f534697,

title = "Predictive Modeling of Vehicle Emissions Using Deep Learning Techniques and AERMOD",

abstract = "Real-time vehicle detection not only enables accurate counting and tracking of vehicles on the road but also provides valuable data for analyzing traffic patterns and vehicle-related emissions. Simultaneously, calculating vehicular emissions is crucial for assessing environmental impact and implementing pollution reduction strategies. These combined efforts play a pivotal role in enhancing transportation systems and creating a more sustainable infrastructure. In this study, we employed a real-time vehicle detection system based on deep learning. During rush hour traffic, vehicles traversing Be{\c s}ikta{\c s}-Barbaros Boulevard in Istanbul, T{\"u}rkiye, were counted using the YOLO (You Only Look Once) version 8 (YOLOv8) and SORT (Simple Online and Real-time Tracking) algorithm based on video recordings. The system was trained using a custom ISTraffic dataset which includes 36,841 annotated instances across 1,125 images, covering various vehicle classes such as cars, shuttles, buses, and motorcycles. The proposed algorithm exhibited outstanding performance, achieving a mean average precision (mAP) of 0.903 at a confidence threshold of 0.5. It achieved a precision of 1.00 and a recall of 0.91. Furthermore, we calculated vehicle-related pollutant emissions, including CO, NO, NO2,NOx, and PM10, using the COPERT program following the Tier 3 methodology. These emissions data were then used as input for the AERMOD model. AERMOD CO 2180 µg/m3, NO 2848 µg/m3,NO2 1373 µg/m3,NOx 4222 µg/m3,PM10 155 µg/ m3 . By combining deep learning techniques with AERMOD, our research aims to improve predictive modeling of air quality impacts from transportation activities.",

keywords = "AERMOD, COPERT, Deep learning, Vehicle emissions, YOLO",

author = "Elif Yavuz and Alihan {\"O}zt{\"u}rk and Balkanlı, \{Nedime Gaye Nur\} and Engin, \{{\c S}eref Naci\} and Kuzu, \{S. Levent\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.; 40th International Technical Meeting on Air Pollution Modeling, ITM 2024 ; Conference date: 14-10-2024 Through 18-10-2024",

year = "2026",

doi = "10.1007/978-3-032-02971-3\_50",

language = "English",

isbn = "9783032029706",

series = "Springer Proceedings in Complexity",

publisher = "Springer Science and Business Media B.V.",

pages = "395--403",

editor = "Clemens Mensink and Ulas Im",

booktitle = "Air Pollution Modeling and Its Application XXX",

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}

Yavuz, E, Öztürk, A, Balkanlı, NGN, Engin, ŞN & Kuzu, SL 2026, Predictive Modeling of Vehicle Emissions Using Deep Learning Techniques and AERMOD. in C Mensink & U Im (eds), Air Pollution Modeling and Its Application XXX. Springer Proceedings in Complexity, Springer Science and Business Media B.V., pp. 395-403, 40th International Technical Meeting on Air Pollution Modeling, ITM 2024, Copenhagen, Denmark, 14/10/24. https://doi.org/10.1007/978-3-032-02971-3_50

Predictive Modeling of Vehicle Emissions Using Deep Learning Techniques and AERMOD. / Yavuz, Elif; Öztürk, Alihan; Balkanlı, Nedime Gaye Nur et al.
Air Pollution Modeling and Its Application XXX. ed. / Clemens Mensink; Ulas Im. Springer Science and Business Media B.V., 2026. p. 395-403 (Springer Proceedings in Complexity).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Yavuz, Elif

AU - Öztürk, Alihan

AU - Balkanlı, Nedime Gaye Nur

AU - Engin, Şeref Naci

AU - Kuzu, S. Levent

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.

PY - 2026

Y1 - 2026

N2 - Real-time vehicle detection not only enables accurate counting and tracking of vehicles on the road but also provides valuable data for analyzing traffic patterns and vehicle-related emissions. Simultaneously, calculating vehicular emissions is crucial for assessing environmental impact and implementing pollution reduction strategies. These combined efforts play a pivotal role in enhancing transportation systems and creating a more sustainable infrastructure. In this study, we employed a real-time vehicle detection system based on deep learning. During rush hour traffic, vehicles traversing Beşiktaş-Barbaros Boulevard in Istanbul, Türkiye, were counted using the YOLO (You Only Look Once) version 8 (YOLOv8) and SORT (Simple Online and Real-time Tracking) algorithm based on video recordings. The system was trained using a custom ISTraffic dataset which includes 36,841 annotated instances across 1,125 images, covering various vehicle classes such as cars, shuttles, buses, and motorcycles. The proposed algorithm exhibited outstanding performance, achieving a mean average precision (mAP) of 0.903 at a confidence threshold of 0.5. It achieved a precision of 1.00 and a recall of 0.91. Furthermore, we calculated vehicle-related pollutant emissions, including CO, NO, NO2,NOx, and PM10, using the COPERT program following the Tier 3 methodology. These emissions data were then used as input for the AERMOD model. AERMOD CO 2180 µg/m3, NO 2848 µg/m3,NO2 1373 µg/m3,NOx 4222 µg/m3,PM10 155 µg/ m3 . By combining deep learning techniques with AERMOD, our research aims to improve predictive modeling of air quality impacts from transportation activities.

AB - Real-time vehicle detection not only enables accurate counting and tracking of vehicles on the road but also provides valuable data for analyzing traffic patterns and vehicle-related emissions. Simultaneously, calculating vehicular emissions is crucial for assessing environmental impact and implementing pollution reduction strategies. These combined efforts play a pivotal role in enhancing transportation systems and creating a more sustainable infrastructure. In this study, we employed a real-time vehicle detection system based on deep learning. During rush hour traffic, vehicles traversing Beşiktaş-Barbaros Boulevard in Istanbul, Türkiye, were counted using the YOLO (You Only Look Once) version 8 (YOLOv8) and SORT (Simple Online and Real-time Tracking) algorithm based on video recordings. The system was trained using a custom ISTraffic dataset which includes 36,841 annotated instances across 1,125 images, covering various vehicle classes such as cars, shuttles, buses, and motorcycles. The proposed algorithm exhibited outstanding performance, achieving a mean average precision (mAP) of 0.903 at a confidence threshold of 0.5. It achieved a precision of 1.00 and a recall of 0.91. Furthermore, we calculated vehicle-related pollutant emissions, including CO, NO, NO2,NOx, and PM10, using the COPERT program following the Tier 3 methodology. These emissions data were then used as input for the AERMOD model. AERMOD CO 2180 µg/m3, NO 2848 µg/m3,NO2 1373 µg/m3,NOx 4222 µg/m3,PM10 155 µg/ m3 . By combining deep learning techniques with AERMOD, our research aims to improve predictive modeling of air quality impacts from transportation activities.

KW - AERMOD

KW - COPERT

KW - Deep learning

KW - Vehicle emissions

KW - YOLO

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U2 - 10.1007/978-3-032-02971-3_50

DO - 10.1007/978-3-032-02971-3_50

M3 - Conference contribution

AN - SCOPUS:105035220321

SN - 9783032029706

T3 - Springer Proceedings in Complexity

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EP - 403

BT - Air Pollution Modeling and Its Application XXX

A2 - Mensink, Clemens

A2 - Im, Ulas

PB - Springer Science and Business Media B.V.

T2 - 40th International Technical Meeting on Air Pollution Modeling, ITM 2024

Y2 - 14 October 2024 through 18 October 2024

ER -

Predictive Modeling of Vehicle Emissions Using Deep Learning Techniques and AERMOD

Abstract

Publication series

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Bibliographical note

Keywords

Access to Document

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