Forecasting the Gap Between Demand and Supply of E-hailing Vehicle in Large Scale of Network Based on Two-stage Model

Recently, taxi play an increasingly important role in transit mode due to its accessibility and convenient. However, vacant e-hailing vehicles occupy the road capacity, thus, aggravated traffic congestions. With the availability of real-time data, one way to deal with these concerns is to improve the forecast accuracy of demand and supply thus help improving the dispatching efficiency. This paper proposes a two-stage forecast model based on big data to real-time predict the gap between demand and supply in large scale of network. The framework includes four steps, GPS data dimensionality reduction based on Principle Component Analysis, pattern analysis, the proposed methodology of two-stage forecast model and model verification. The methodology combines both non-linear Support Vector Machine and Backpropagation neural network. In the cast study of Beijing city, the model is testified and the results show that two-stage forecast model fastens responsive performance and improves the prediction accuracy. The proposed framework not only reveals the mobility pattern, it also improves the prediction accuracy for the gap between demand and supply of taxis thus helps to improve the taxi utilizations.

[1]  Moshe Ben-Akiva,et al.  Personalized Menu Optimization with Preference Updater: A Boston Case Study , 2018 .

[2]  S. Phithakkitnukoon,et al.  Urban mobility study using taxi traces , 2011, TDMA '11.

[3]  Yinhai Wang,et al.  Revealing intra-urban travel patterns and service ranges from taxi trajectories , 2017 .

[4]  Xiao Liang,et al.  The scaling of human mobility by taxis is exponential , 2011, ArXiv.

[5]  Johan A. K. Suykens,et al.  Least Squares Support Vector Machine Classifiers , 1999, Neural Processing Letters.

[6]  Judith C. Chow,et al.  Corrigendum to “Chemical mass balance source apportionment for combined PM2.5 measurements from U.S. non-urban and urban long-term networks” [Atmos. Environ. 44 (2010) 4908–4918] , 2012 .

[7]  Y. Nie How can the taxi industry survive the tide of ridesourcing? Evidence from Shenzhen, China , 2017 .

[8]  Constantinos Antoniou,et al.  Quantifying Demand Dynamics for Supporting Optimal Taxi Services Strategies , 2017 .

[9]  Lun Wu,et al.  Intra-Urban Human Mobility and Activity Transition: Evidence from Social Media Check-In Data , 2014, PloS one.

[10]  Moshe Ben-Akiva,et al.  The concept and impact analysis of a flexible mobility on demand system , 2015 .

[11]  M. Quddus,et al.  A survey of Demand Responsive Transport in Great Britain , 2012 .

[12]  Satish V. Ukkusuri,et al.  Urban Link Travel Time Estimation Using Large-scale Taxi Data with Partial Information , 2013 .

[13]  Shing Chung Josh Wong,et al.  Network Model of Urban Taxi Services: Improved Algorithm , 1998 .

[14]  Lu Ling,et al.  Analyzing the Relationship Between Urban Macroeconomic Development and Transport Infrastructure System Based on Neural Network , 2016 .

[15]  B. Moore Principal component analysis in linear systems: Controllability, observability, and model reduction , 1981 .

[16]  Zhaohui Wu,et al.  This article has been accepted for inclusion in a future issue of this journal. Content is final as presented, with the exception of pagination. IEEE TRANSACTIONS ON INTELLIGENT TRANSPORTATION SYSTEMS 1 Land-Use Classification Using Taxi GPS Traces , 2022 .

[17]  Tamer Çetin,et al.  Estimating the effects of entry regulation in the Istanbul taxicab market , 2011 .

[18]  Hai Yang,et al.  DEMAND-SUPPLY EQUILIBRIUM OF TAXI SERVICES IN A NETWORK UNDER COMPETITION AND REGULATION , 2002 .

[19]  Xiaobo Liu,et al.  Testing the proportionality condition with taxi trajectory data , 2017 .

[20]  Liang Liu,et al.  Uncovering cabdrivers' behavior patterns from their digital traces , 2010, Comput. Environ. Urban Syst..

[21]  B. Everitt,et al.  Exploratory Factor Analysis , 2011 .