Automatic detection of public transport (PT) usage has important applications for intelligent transport systems. It is crucial for understanding the commuting habits of passengers at large and over longer periods of time. It also enables compilation of door-to-door trip chains, which in turn can assist public transport providers in improved optimisation of their transport networks. In addition, predictions of future trips based on past activities can be used to assist passengers with targeted information. This article documents a dataset compiled from a day of active commuting by a small group of people using different means of PT in the Helsinki region. Mobility data was collected by two means: (a) manually written details of each PT trip during the day, and (b) measurements using sensors of travellers’ mobile devices. The manual log is used to cross-check and verify the results derived from automatic measurements. The mobile client application used for our data collection provides a fully automated measurement service and implements a set of algorithms for decreasing battery consumption. The live locations of some of the public transport vehicles in the region were made available by the local transport provider and sampled with a 30-s interval. The stopping times of local trains at stations during the day were retrieved from the railway operator. The static timetable information of all the PT vehicles operating in the area is made available by the transport provider, and linked to our dataset. The challenge is to correctly detect as many manually logged trips as possible by using the automatically collected data. This paper includes an analysis of challenges due to missing or partially sampled information, and initial results from automatic recognition using a set of algorithms comparing measured trips with both live vehicle locations and static timetables. Improvement of correct recognitions is left as an ongoing challenge.
[1]
Seppo Törmä,et al.
Mobile crowdsensing of parking space using geofencing and activity recognition
,
2014
.
[2]
Hjp Harry Timmermans,et al.
Transportation mode recognition using GPS and accelerometer data
,
2013
.
[3]
Sasu Tarkoma,et al.
Accelerometer-based transportation mode detection on smartphones
,
2013,
SenSys '13.
[4]
Daniel G. Aliaga,et al.
Urban sensing: Using smartphones for transportation mode classification
,
2015,
Comput. Environ. Urban Syst..
[5]
Mikko Rinne.
Towards interoperable traffic data sources
,
2014
.
[6]
Geoffrey Challen,et al.
PocketParker: pocketsourcing parking lot availability
,
2014,
UbiComp.
[7]
J. Jokinen,et al.
Crowdsensing-based transportation services - An analysis from business model and sustainability viewpoints
,
2016
.
[8]
John D. Nelson,et al.
GetThere: A Rural Passenger Information System Utilising Linked Data & Citizen Sensing
,
2013,
International Semantic Web Conference.
[9]
Yakov Shafranovich,et al.
Common Format and MIME Type for Comma-Separated Values (CSV) Files
,
2005,
RFC.
[10]
Christine Julien,et al.
Virtual sensors: abstracting data from physical sensors
,
2006,
2006 International Symposium on a World of Wireless, Mobile and Multimedia Networks(WoWMoM'06).