Urban traffic congestion prediction: a multi-step approach utilizing sensor data and weather information

Tsalikidis, Nikolaos; Mystakidis, Aristeidis; Koukaras, Paraskevas; Ivaškevičius, Marius; Morkūnaitė, Lina; Ioannidis, Dimosthenis; Fokaides, Paris A.; Tjortjis, Christos; Tzovaras, Dimitrios

doi:10.3390/smartcities7010010

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Journal Article

Urban traffic congestion prediction: a multi-step approach utilizing sensor data and weather information
Citation	Tsalikidis N, Mystakidis A, Koukaras P, Ivaškevičius M, Morkūnaitė L, Ioannidis D, Fokaides PA, Tjortjis C, Tzovaras D. Smart Cities (Basel) 2024; 7(1): 233-253.
Copyright	(Copyright © 2024, MDPI Multidisciplinary Digital Publishing Institute)
DOI	10.3390/smartcities7010010
PMID	unavailable
Abstract	The continuous growth of urban populations has led to the persistent problem of traffic congestion, which imposes adverse effects on quality of life, such as commute times, road safety, and the local air quality. Advancements in Internet of Things (IoT) sensor technology have contributed to a plethora of new data streams regarding traffic conditions. Therefore, the recognition and prediction of traffic congestion patterns utilizing such data have become crucial. To that end, the integration of Machine Learning (ML) algorithms can further enhance Intelligent Transportation Systems (ITS), contributing to the smart management of transportation systems and effectively tackling traffic congestion in cities. This study seeks to assess a wide range of models as potential solutions for an ML-based multi-step forecasting approach intended to improve traffic congestion prediction, particularly in areas with limited historical data. Various interpretable predictive algorithms, suitable for handling the complexity and spatiotemporal characteristics of urban traffic flow, were tested and eventually shortlisted based on their predictive performance. The forecasting approach selects the optimal model in each step to maximize the accuracy. The findings demonstrate that, in a 24 h step prediction, variating Ensemble Tree-Based (ETB) regressors like the Light Gradient Boosting Machine (LGBM) exhibit superior performances compared to traditional Deep Learning (DL) methods. Our work provides a valuable contribution to short-term traffic congestion predictions and can enable more efficient scheduling of daily urban transportation. Language: en
Keywords	Deep Learning; Machine Learning; road traffic; smart cities; time series forecasting; traffic congestion prediction; weather information