Supervised Deep Learning Based for Traffic Flow Prediction

2018 International Conference on Smart Green Technology in Electrical and Information Systems (ICSGTEIS) Pub Date : 2018-10-01 DOI:10.1109/ICSGTEIS.2018.8709102

Hendrik Tampubolon, Pao-Ann Hsiung

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引用次数: 4

Abstract

In metropolitan areas, common traffic issues include traffic congestion, traffic accidents, air pollution, and energy consumption occur. To resolve this issues, Intelligent Transportation Systems (ITS) have been evolved by many researchers. One of the important sub-systems in the development of ITS is a Traffic Management System (TMS) which attempts to reduce a traffic congestion. In fact, TMS itself relies on the estimation of traffic flow, therefore providing such an accurate traffic flow prediction is needed. For this reason, we aim to provide an accurate traffic flow prediction to facilitate this system. In this works, a Supervised Deep Learning Based Traffic Flow Prediction (SDLTFP) was proposed which is a type of fully-connected deep neural network (FC-DNN). Timely prediction is also a major issue in guaranteeing reliable traffic flow prediction. However, training a deep network could be time-consuming, and overfitting is might be happening, especially when feeding small data into the deep architecture. The network is learned perfectly during the training, but in testing with the new data, it could fail to generalize the model. We adopt the Batch Normalization (BN) and Dropout techniques to help the network training. SGD and momentum are carried out to update the weight. We then take advantage of open data as historical traffic data which are then used to predict future traffic flow with the proposed method and model above. Experiments show that the Mean Absolute Percentage Error (MAPE) for our traffic flow prediction is within 5 % using sample data and between 15% to 20% using out of the sample data. Training a deep network faster with BN and Dropout reduces the overfitting.

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基于监督深度学习的交通流量预测

在大都市地区，交通拥堵、交通事故、空气污染、能源消耗等交通问题是普遍存在的。为了解决这一问题，智能交通系统(ITS)得到了许多研究者的发展。交通管理系统(TMS)是智能交通系统发展的重要子系统之一，它试图减少交通拥堵。实际上，TMS本身依赖于对交通流的估计，因此需要提供如此精确的交通流预测。因此，我们的目标是提供一个准确的交通流量预测，以促进该系统。在这项工作中，提出了一种基于监督深度学习的交通流量预测(SDLTFP)，它是一种全连接深度神经网络(FC-DNN)。及时预测也是保证交通流量预测可靠的主要问题。然而，训练深度网络可能很耗时，而且可能会发生过拟合，特别是在将小数据输入深度架构时。在训练过程中，网络学习得很好，但在使用新数据进行测试时，它可能无法泛化模型。我们采用批处理归一化(Batch Normalization, BN)和Dropout技术来帮助网络训练。执行SGD和动量来更新权重。然后，我们利用开放数据作为历史交通数据，然后使用上述提出的方法和模型来预测未来的交通流量。实验表明，我们的交通流量预测的平均绝对百分比误差(MAPE)使用样本数据在5%以内，使用样本外数据在15%到20%之间。使用BN和Dropout更快地训练深度网络可以减少过拟合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 International Conference on Smart Green Technology in Electrical and Information Systems (ICSGTEIS)

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