Abstract
Driving speed is one of the most critical indicators in safety evaluation and network monitoring in freight transportation. Speed prediction model serves as the most efficient method to obtain the data of driving speed. Current speed prediction models mostly focus on operating speed, which is hard to reveal the overall condition of driving speed on the road section. Meanwhile, the models were mostly developed based on the regression method, which is inconsistent with natural driving process. Recurrent neural network (RNN) is a distinctive type of deep learning method to capture the temporary dependency in behavioral research. The aim of this paper is to apply the deep learning method to predict the general condition of driving speed in consideration of the road geometry and the temporal evolutions. 3D mobile mapping was applied to obtain road geometry information with high precision, and driving simulation experiment was then conducted with the help of the road geometry data. Driving speed was characterized by the bimodal Gauss mixture model. RNN and its variants including long short-term memory (LSTM) and RNN and gated recurrent units (GRUs) were utilized to predict speed distribution in a spatial-temporal dimension with KL divergence being the loss function. The result proved the applicability of the model in speed distribution prediction of freight vehicles, while LSTM holds the best performance with the length of input sequence being 400 m. The result can be related to the threshold of drivers’ information processing on mountainous freeway. Multiple linear regression models were constructed to be a contrast with the LSTM model, and the results showed that LSTM was superior to regression models in terms of the model accuracy and interpretability of the driving process and the formation of vehicle speed. This study may help to understand speed change behavior of freight vehicles on mountainous freeways, while providing the feasible method for safety evaluation or network efficiency analysis.
Highlights
In the driving process of freight vehicles, driving speed is one of the most important indicators in safety evaluation and e ciency analysis
Targeting the weakness of traditional speed prediction models, this study applies several types of deep learning methods based on Recurrent neural network (RNN) to predict speed distribution on mountainous freeways
(1) It is reasonable to apply bimodal Gaussian mixture model (GMM) to characterize the distribution of speed of freight vehicle, which improved the traditional method by using single normal distribution or lognormal distribution
Summary
In the driving process of freight vehicles, driving speed is one of the most important indicators in safety evaluation and e ciency analysis. The speed prediction model plays an important role in obtaining the driving speed of vehicles [1]. The poor terrain conditions allowed relatively unfavorable road geometry design, and combined vertical and horizontal alignments are not uncommon in mountainous freeways, which directly produces many accident-prone road sections [2]. On the selection of the variables in the input of the speed prediction model, parameters are mostly related to environmental conditions (e.g., road geometry, roadside vegetation, guardrail, and delineator) [3, 4]. Typical road alignment features include horizontal and vertical curvature, curve length, guardrails, roadside vegetation, and road delineator [8]. E previous studies agree that road geometry plays a dominant role affecting operating speed under most circumstances Typical road alignment features include horizontal and vertical curvature, curve length, guardrails, roadside vegetation, and road delineator [8]. e previous studies agree that road geometry plays a dominant role affecting operating speed under most circumstances
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