A periodical decomposition-based two-stage NARX model for demand prediction of bike-sharing travel in hotspot areas

IF 4.1 2区工程技术 Q2 BUSINESS

Research in Transportation Business and Management Pub Date : 2024-11-11 DOI:10.1016/j.rtbm.2024.101237

Chao Sun , Jian Lu

{"title":"A periodical decomposition-based two-stage NARX model for demand prediction of bike-sharing travel in hotspot areas","authors":"Chao Sun , Jian Lu","doi":"10.1016/j.rtbm.2024.101237","DOIUrl":null,"url":null,"abstract":"<div><div>Future free-floating bike-sharing travel demand forecasting systems can mitigate dispatch failures. Typically, time series forecasts for traffic demand and flow are computed using a global study area, which does not account for spatial heterogeneity. To address this, a periodical decomposition-based two-stage NARX (Nonlinear Auto Regressive with Exogenous Inputs) model is developed to accurately predict free-floating bike-sharing travel demand (BSTD) for individual hotspot areas. Kernel density analysis-based hotspot detection is employed to divide the study area into basic predicting units, thereby enhancing efficiency and guidance quality. Weather factors with poor predictability or low correlation with BSTD are further eliminated using rescaled range and gray correlation methods. Based on periodic decomposition results, an improved two-stage NARX model is constructed for BSTD prediction in multiple important steps. A random selection of 50 hotspot areas in Beijing was performed for methodology verification, with hotspots numbered and selected using a random number generator. Results indicate that the periodical decomposition-based NARX model significantly improves BSTD prediction accuracy in hotspot areas compared to typical time series forecasting methods. The model demonstrates higher R-values (correlation between targets and outputs) and lower MSEs (Mean Squared Errors). For instance, the average MSE of the periodical decomposition-based two-stage NARX model is 20.225, compared to ARIMA (26.151), NARX (28.748), ARIMA (32.854), and NAR (41.666), highlighting superior robustness and effectiveness across different hotspot types and locations. These findings enhance understanding of the spatial-temporal variation of BSTD and provide a foundation for optimizing time series forecasting within specific areas.</div></div>","PeriodicalId":47453,"journal":{"name":"Research in Transportation Business and Management","volume":"57 ","pages":"Article 101237"},"PeriodicalIF":4.1000,"publicationDate":"2024-11-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Research in Transportation Business and Management","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S2210539524001391","RegionNum":2,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"BUSINESS","Score":null,"Total":0}

引用次数: 0

Abstract

Future free-floating bike-sharing travel demand forecasting systems can mitigate dispatch failures. Typically, time series forecasts for traffic demand and flow are computed using a global study area, which does not account for spatial heterogeneity. To address this, a periodical decomposition-based two-stage NARX (Nonlinear Auto Regressive with Exogenous Inputs) model is developed to accurately predict free-floating bike-sharing travel demand (BSTD) for individual hotspot areas. Kernel density analysis-based hotspot detection is employed to divide the study area into basic predicting units, thereby enhancing efficiency and guidance quality. Weather factors with poor predictability or low correlation with BSTD are further eliminated using rescaled range and gray correlation methods. Based on periodic decomposition results, an improved two-stage NARX model is constructed for BSTD prediction in multiple important steps. A random selection of 50 hotspot areas in Beijing was performed for methodology verification, with hotspots numbered and selected using a random number generator. Results indicate that the periodical decomposition-based NARX model significantly improves BSTD prediction accuracy in hotspot areas compared to typical time series forecasting methods. The model demonstrates higher R-values (correlation between targets and outputs) and lower MSEs (Mean Squared Errors). For instance, the average MSE of the periodical decomposition-based two-stage NARX model is 20.225, compared to ARIMA (26.151), NARX (28.748), ARIMA (32.854), and NAR (41.666), highlighting superior robustness and effectiveness across different hotspot types and locations. These findings enhance understanding of the spatial-temporal variation of BSTD and provide a foundation for optimizing time series forecasting within specific areas.

查看原文本刊更多论文

基于周期分解的两阶段 NARX 模型用于热点地区共享单车出行需求预测

未来的自由浮动共享单车出行需求预测系统可以减少调度故障。通常情况下，交通需求和流量的时间序列预测是通过全球研究区域来计算的，这并不考虑空间异质性。为解决这一问题，我们开发了一个基于周期分解的两阶段 NARX（带外生输入的非线性自回归）模型，以准确预测单个热点区域的自由浮动共享单车出行需求（BSTD）。采用基于核密度分析的热点检测，将研究区域划分为基本预测单元，从而提高效率和指导质量。采用重标定范围法和灰色关联法进一步剔除预测性差或与 BSTD 相关性低的天气因素。根据周期性分解结果，分多个重要步骤构建了用于 BSTD 预测的改进型两阶段 NARX 模型。在北京随机选择了 50 个热点区域进行方法验证，使用随机数发生器对热点区域进行编号和选择。结果表明，与典型的时间序列预测方法相比，基于周期分解的 NARX 模型显著提高了热点地区的 BSTD 预测精度。该模型显示出更高的 R 值（目标与输出之间的相关性）和更低的 MSE（平均平方误差）。例如，基于周期分解的两阶段 NARX 模型的平均 MSE 值为 20.225，而 ARIMA（26.151）、NARX（28.748）、ARIMA（32.854）和 NAR（41.666）的平均 MSE 值分别为 26.151、28.748、32.854 和 41.666。这些发现加深了对 BSTD 时空变化的理解，为优化特定地区的时间序列预测奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Research in Transportation Business and Management Multiple-

CiteScore

7.10

自引率

8.30%

发文量

175

期刊介绍： Research in Transportation Business & Management (RTBM) will publish research on international aspects of transport management such as business strategy, communication, sustainability, finance, human resource management, law, logistics, marketing, franchising, privatisation and commercialisation. Research in Transportation Business & Management welcomes proposals for themed volumes from scholars in management, in relation to all modes of transport. Issues should be cross-disciplinary for one mode or single-disciplinary for all modes. We are keen to receive proposals that combine and integrate theories and concepts that are taken from or can be traced to origins in different disciplines or lessons learned from different modes and approaches to the topic. By facilitating the development of interdisciplinary or intermodal concepts, theories and ideas, and by synthesizing these for the journal''s audience, we seek to contribute to both scholarly advancement of knowledge and the state of managerial practice. Potential volume themes include: -Sustainability and Transportation Management- Transport Management and the Reduction of Transport''s Carbon Footprint- Marketing Transport/Branding Transportation- Benchmarking, Performance Measurement and Best Practices in Transport Operations- Franchising, Concessions and Alternate Governance Mechanisms for Transport Organisations- Logistics and the Integration of Transportation into Freight Supply Chains- Risk Management (or Asset Management or Transportation Finance or ...): Lessons from Multiple Modes- Engaging the Stakeholder in Transportation Governance- Reliability in the Freight Sector