Using Poisson proximity-based weights for traffic flow state prediction

IF 0.7 4区计算机科学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Neural Network World Pub Date : 2023-01-01 DOI:10.14311/nnw.2023.33.017

Evženie Uglickich, Ivan Nagy

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Abstract

The development of traffic state prediction algorithms embedded in intelligent transportation systems is of great importance for improving traffic conditions for drivers and pedestrians. Despite the large number of prediction methods, existing limitations still confirm the need to find a systematic solution and its adaptation to specific traffic data. This paper focuses on the relationship between traffic flow states in different urban locations, where these states are identified as clusters of traffic counts. Extending the recursive Bayesian mixture estimation theory to the Poisson mixtures, the paper uses the mixture pointers to construct the traffic state prediction model. Using the predictive model, the cluster at the target urban location is predicted based on the traffic counts measured in real time at the explanatory urban location. The main contributions of this study are: (i) recursive identification and prediction of the traffic state at each time instant, (ii) straightforward Poisson mixture initialization, and (iii) systematic theoretical background of the prediction approach. Results of testing the prediction algorithm on real traffic counts are presented.

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基于泊松近似权值的交通流状态预测

智能交通系统中嵌入的交通状态预测算法的发展对于改善驾驶员和行人的交通状况具有重要意义。尽管预测方法很多，但现有的局限性仍然需要找到一个系统的解决方案，并适应具体的交通数据。本文重点研究了不同城市位置的交通流状态之间的关系，这些状态被识别为交通计数集群。将递推贝叶斯混合估计理论推广到泊松混合，利用混合指针构造交通状态预测模型。使用该预测模型，基于在解释城市位置实时测量的交通量来预测目标城市位置的集群。本研究的主要贡献是:(1)递归识别和预测每个时刻的交通状态;(2)简单的泊松混合初始化;(3)系统的预测方法的理论背景。给出了基于实际流量的预测算法的测试结果。

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来源期刊

Neural Network World 工程技术-计算机：人工智能

CiteScore

1.80

自引率

0.00%

发文量

审稿时长

12 months

期刊介绍： Neural Network World is a bimonthly journal providing the latest developments in the field of informatics with attention mainly devoted to the problems of: brain science, theory and applications of neural networks (both artificial and natural), fuzzy-neural systems, methods and applications of evolutionary algorithms, methods of parallel and mass-parallel computing, problems of soft-computing, methods of artificial intelligence.