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GPS-Based Traffic Conditions Classification Using Machine Learning Approaches

Ahmed, Usman ; Tu, Ran ; Xu, Junshi ; [et al.]

SAGE Publications ; 2023

In: Transportation Research Record: Journal of the Transportation Research Board Vol. 2677, No. 2 ( 2023-02), p. 1445-1454

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In: Transportation Research Record: Journal of the Transportation Research Board, SAGE Publications, Vol. 2677, No. 2 ( 2023-02), p. 1445-1454

Abstract: This paper addresses the problem of accurately estimating traffic conditions based on sparse GPS information. GPS data have limited spatial-temporal availability, particularly at a regional scale. Therefore, it lacks reliability to accurately estimate traffic conditions of a transportation network. This study proposes a novel methodology to address this problem. First, instead of estimating traffic conditions on a geographic road segment, traffic conditions are estimated for trip segments, which span multiple road segments. Second, machine learning methods are applied to classify traffic conditions. In this study, traffic conditions are defined as the combination of congestion level and road type. This study develops two machine learning models—a random forest (RF) model and a supervised clustering method—to classify traffic conditions, using trip characteristics such as average speed and acceleration. The two models are compared in relation to their accuracy and computational efficiency. Results show that speed-related trip characteristics, such as average instantaneous speed, are the most important variables for classifying traffic conditions in both methods. In addition, the proportion of idling in a trip is essential in distinguishing the Congested Highway and Uncongested Urban traffic conditions when applying the supervised clustering method. The comparison shows that the RF model has a higher estimation accuracy (81%) than the supervised clustering method (72%). Overall, this study shows that traffic conditions can be determined efficiently even in cases of limited GPS data.

Type of Medium: Online Resource

ISSN: 0361-1981 , 2169-4052

URL: Article

DOI: 10.1177/03611981221111370

Language: English

Publisher: SAGE Publications

Publication Date: 2023

detail.hit.zdb_id: 2403378-9

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Bayesian Global Optimization Gated Recurrent Unit Model for Human-Driven Vehicle Lane-Change Trajectory Prediction Considering Hyperparameter Optimization

Hu, Xinghua ; Chen, Shanzhi ; Zhao, Jiahao ; [et al.]

SAGE Publications ; 2023

In: Transportation Research Record: Journal of the Transportation Research Board

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In: Transportation Research Record: Journal of the Transportation Research Board, SAGE Publications

Abstract: To address the low accuracy and inefficiency of current lane-change trajectory prediction methods for human-driven vehicles, this study develops a neural network lane-change trajectory prediction model with hyperparametric optimization capability using Bayesian optimization and gated recurrent units to consider the effect of lane-change intention on vehicle lane-change behavior and to predict it. The proposed model was instantiated using trajectory data of 8,721 vehicles. The results show that the overall recognition accuracy of intention recognition under the optimal input is 93.54%, and the recognition accuracy of keeping straight, left lane-change and right lane-change is 95.59%, 91.72%, and 93.30%, respectively. The root mean square errors of the predicted and actual trajectories to the left and to the right under the optimal input are 0.2582 and 0.2957, respectively. This paper demonstrates that, for the intention recognition module, the low-dimensional input enables the model to obtain high prediction accuracy, while for the trajectory prediction module, the high-latitude input enables the model to obtain a low prediction error. The developed trajectory prediction model can be used to assist in driving decision-making, path planning, and so forth.

Type of Medium: Online Resource

ISSN: 0361-1981 , 2169-4052

URL: Article

DOI: 10.1177/03611981231182390

Language: English

Publisher: SAGE Publications

Publication Date: 2023

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Using Artificial Potential Field Theory for a Cooperative Control Model in a Connected and Automated Vehicles Environment

Yi, Ziwei ; Li, Linheng ; Qu, Xu ; [et al.]

SAGE Publications ; 2020

In: Transportation Research Record: Journal of the Transportation Research Board Vol. 2674, No. 9 ( 2020-09), p. 1005-1018

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In: Transportation Research Record: Journal of the Transportation Research Board, SAGE Publications, Vol. 2674, No. 9 ( 2020-09), p. 1005-1018

Abstract: Artificial potential field (APF) theory has been extensively applied in traffic path planning as an efficient method to avoid collision. However, studies in collision avoidance based on APF theory only considered the movement of single vehicle. In this paper, a vehicle cooperative control model for avoiding collision in the connected and autonomous vehicles (CAVs) environment is presented, using APF theory. The proposed model not merely guarantees the travel safety of vehicles in avoiding collision, but also promotes driving comfort and improves traffic efficiency. To verify the cooperative control model, simulations of four scenarios are designed and compared with the human driving environment. Five indicators are selected to evaluate the results, that is, time–space diagram, time mean speed (TMS), the rate of large deceleration time (large deceleration is that deceleration larger than –2 m/s 2 ), the inverse time-to-collision ([Formula: see text]), and lane-changing times. According to the simulation results, the cooperative control model could alleviate the capacity drop and increase the TMS to improve traffic efficiency, reduce the rate of the large deceleration time to promote driving comfort, and decrease [Formula: see text] to promote safety in small and large input flow rates. The results reveal the proposed model is significantly superior to the human driving environment whether in free or congested situations, except for the lane-change times, which are slightly larger.

Type of Medium: Online Resource

ISSN: 0361-1981 , 2169-4052

URL: Article

DOI: 10.1177/0361198120933271

Language: English

Publisher: SAGE Publications

Publication Date: 2020

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