A novel road traffic flow prediction model using hybrid Particle Swarm Optimization (PSO) and Radial Basis Function Neural Network (RBFNN)

Shanhua Zhang, H. An
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Abstract

Traffic congestion is a major problem in urban areas, leading to increased travel time, air pollution, and fuel consumption. Road impedance function, which describes the relationship between traffic status and travel time, plays an important role in predicting travel time and managing traffic flow. Traditional methods for estimating road impedance function rely on manual calibration and may have limitations in reflecting the complexity of traffic patterns. To address these challenges, researchers have proposed various machine learning models for predicting travel time and road impedance function. In this paper, a hybrid particle swarm optimization—radial basis function neural network model is proposed for improving the accuracy of the road impedance function. The model takes into consideration various vehicle types and is validated using travel time data collected from a road section in Huai’an City, China. The effectiveness of the proposed model is compared with the traditional road impedance function calibrated by nonlinear regression. The experimental results indicate that the Mean Relative Error (MRE) of PSORBFNN is increased by 3.89% and 6.28% respectively when compared with DPNR training samples and validation samples. When compared with DPPSO training and validation samples, the MRE of PSORBFNN is increased by 2.87% and 3.3% respectively. These findings suggest that the proposed model could guide and assist traffic engineers and practitioners in predicting travel time on road sections with improved accuracy.
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基于粒子群算法和径向基函数神经网络的道路交通流预测模型
交通拥堵是城市地区的一个主要问题,导致出行时间、空气污染和燃料消耗增加。道路阻抗函数描述了交通状况和行驶时间之间的关系,在预测行驶时间和管理交通流量方面发挥着重要作用。估计道路阻抗函数的传统方法依赖于手动校准,并且在反映交通模式的复杂性方面可能存在局限性。为了应对这些挑战,研究人员提出了各种机器学习模型来预测行驶时间和道路阻抗函数。为了提高道路阻抗函数的精度,本文提出了一种混合粒子群优化——径向基函数神经网络模型。该模型考虑了各种车辆类型,并使用从中国淮安市某路段收集的行驶时间数据进行了验证。将所提出的模型的有效性与通过非线性回归校准的传统道路阻抗函数进行了比较。实验结果表明,与DPNR训练样本和验证样本相比,PSORBFNN的平均相对误差分别提高了3.89%和6.28%。与DPPSO训练和验证样本相比,PSORBFNN的MRE分别提高了2.87%和3.3%。这些发现表明,所提出的模型可以指导和帮助交通工程师和从业者以更高的准确性预测路段的行驶时间。
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CiteScore
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发文量
25
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