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http://dx.doi.org/10.13161/kibim.2018.8.3.012

Big Data Based Urban Transportation Analysis for Smart Cities - Machine Learning Based Traffic Prediction by Using Urban Environment Data -  

Jang, Sun-Young (성균관대학교 건축학과)
Shin, Dong-Youn (단국대학교 건축학과)
Publication Information
Journal of KIBIM / v.8, no.3, 2018 , pp. 12-19 More about this Journal
Abstract
The research aims to find implications of machine learning and urban big data as a way to construct the flexible transportation network system of smart city by responding the urban context changes. This research deals with a problem that existing a bus headway model is difficult to respond urban situations in real-time. Therefore, utilizing the urban big data and machine learning prototyping tool in weathers, traffics, and bus statues, this research presents a flexible headway model to predict bus delay and analyze the result. The prototyping model is composed by real-time data of buses. The data is gathered through public data portals and real time Application Program Interface (API) by the government. These data are fundamental resources to organize interval pattern models of bus operations as traffic environment factors (road speeds, station conditions, weathers, and bus information of operating in real-time). The prototyping model is implemented by the machine learning tool (RapidMiner Studio) and conducted several tests for bus delays prediction according to specific circumstances. As a result, possibilities of transportation system are discussed for promoting the urban efficiency and the citizens' convenience by responding to urban conditions.
Keywords
Big Data; Bus Headway Prediction; Machine Learning; Public Transportation; Smart City; Information Architecture;
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  • Reference
1 Maze, T., Agarwai, M. & Burchett, G. (2006). Whether weather matters to traffic demand, traffic safety, and traffic operations and flow, Transportation research record: Journal of the transportation research board, 1948, pp. 170-176.   DOI
2 National Weather Center, https://data.kma.go.kr/cmmn/main.do (Aug. 14. 2018)
3 Dobre, C. & Xhafa, F. (2014). Intelligent services for big data science, Future Generation Computer Systems, 37, pp. 267-281.   DOI
4 Eboli, L. & Mazzulla, G. (2011). A Methodology for Evaluating Transit Service Quality Based on Subjective and Objective Measures from the Passenger's Point of View, Transport Policy, 18(1), pp. 172-181.   DOI
5 Friman, M. (2004). Implementing Quality Improvements in Public Transport, Journal of Public Transportation, 7(4), pp. 49-65.   DOI
6 Gubbi, J., Buyya, R., Marusic, S. & Palaniswami, M. (2013). Internet of Things (IoT): A vision, architectural elements, and future directions, Future generation computer systems, 29(7), pp. 1645-1660.   DOI
7 Gyeonggi Bus Information System (GBIS), www.gbis.go.kr/(Aug. 14. 2018)
8 Kim, K. (2012). Study on the city bus use demand and flexible service during precipitation, Ph. D. Dissertation, Busan National University.
9 Ko, S., Ko, J. & Jeon, J. (1999). Development of Real Time Vehicle Scheduling Model for Public Transportation, Journal of the Research Institute of Industrial Technology, 18, pp. 181-186.
10 Korea Planners Association (2009). Urban Planning, Bosunggak, 2009, pp. 36-37.
11 Lee, H., Park, J., Jo, S. & Yun, B. (2006). Development of Optimal Bus Scheduling Algorithm with Multi-constraints, Journal of Korean Society of Transportation, 24(7), pp. 129-138.
12 Lee, S. (2013). Big Data for Transportation Policies and Their Applications, The Korea Transport Institute.
13 Lee, W., Kim, M., Kim, Y. & Lee, J. (2009). Study on implementation plan of flexible headway service of city bus, Busan Development Institute.
14 Liebig, T., Piatkowski, N., Bockermann, C. & Morik, K. (2017). Dynamic route planning with real-time traffic predictions, Information Systems, 64, pp. 258-265.   DOI
15 Intelligent Transport Society of Korea, www.itskorea.kr/02_sta/sta1.jsp (Aug. 14. 2018)