Emerging micromobility services (e.g., e-scooters) have a great potential to enhance urban mobility but more knowledge on their usage patterns is needed. The General Bikeshare Feed Specification (GBFS) data are a possible source for examining micromobility trip patterns, but efforts are needed to infer trips from the GBFS data. Existing trip inference methods are usually based on the assumption that the vehicle identity (ID) of a micromobility option (e-scooter or e-bike) does not change, and so they cannot deal with data with vehicle IDs that change over time. This paper proposes a comprehensive package of algorithms to infer origin–destination (OD) pairs from GBFS data with static vehicle ID and unlinked trip origins and destinations from GBFS data with resetting and dynamic vehicle ID. The algorithms were implemented in Washington D.C. by analyzing one week (last week of February 2020) of GBFS data published by six vendors, and the inference accuracy of the proposed algorithms are evaluated by R-squared, mean absolute error, and sum absolute error. It is found that the R-squared measure is larger than 0.9 and the MAE measure is less than 2 when the algorithms are evaluated with a 400 m × 400 m grid. The absolute errors are relatively larger in the downtown area, and the inference error is relatively high during early morning and early nighttime. The accuracy of the trip inference algorithms is sufficiently high for most practical applications.
NACTO. Shared Micromobility in the U.S.: 2018. National Association of City Transportation Officials, New York, NY, 2019.
2.
McKenzieG.Spatiotemporal Comparative Analysis of Scooter-Share and Bike-Share Usage Patterns in Washington, DC. Journal of Transport Geography, Vol. 78, 2019, pp. 19–28.
3.
LaaB.LethU.Survey of E-Scooter Users in Vienna: Who They Are and How They Ride. Journal of Transport Geography, Vol. 89, 2020, p. 102874.
4.
BielińskiT.WażnaA.Electric Scooter Sharing and Bike Sharing User Behaviour and Characteristics. Sustainability, Vol. 12, No. 22, 2020, p. 9640.
5.
LeeH.BaekK.ChungJ.-H.KimJ.Factors Affecting Heterogeneity in Willingness to Use E-Scooter Sharing Services. Transportation Research Part D: Transport and Environment, Vol. 92, 2021, p. 102751.
6.
LatinopoulosC.PatrierA.SivakumarA.Planning for E-Scooter Use in Metropolitan Cities: A Case Study for Paris. Transportation Research Part D: Transport and Environment, Vol. 100, 2021, p. 103037.
7.
North American Bikeshare Association. General Bikeshare Feed Specification. NABSA, 2020. https://github.com/NABSA/gbfs. Accessed July 6, 2020.
ZouZ.YounesH.ErdoğanS.WuJ.Exploratory Analysis of Real-Time E-Scooter Trip Data in Washington, DC. Transportation Research Record: Journal of the Transportation Research Board, 2020. 2674: 285-299.
McKenzieG.Urban Mobility in the Sharing Economy: A Spatiotemporal Comparison of Shared Mobility Services. Computers, Environment and Urban Systems, Vol. 79, 2020, p. 101418.
12.
AlmannaaM. H.AlsahhafF. A.AshqarH. I.ElhenawyM.MasoudM.RakotonirainyA.Perception Analysis of E-Scooter Riders and Non-Riders in Riyadh, Saudi Arabia: Survey Outputs. Sustainability, Vol. 13, No. 2, 2021, p. 863.
13.
NikiforiadisA.PaschalidisE.StamatiadisN.RaptopoulouA.KostareliA.BasbasS.Analysis of Attitudes and Engagement of Shared E-Scooter Users. Transportation Research Part D: Transport and Environment, Vol. 94, 2021, p. 102790.
14.
RaptopoulouA.BasbasS.StamatiadisN.NikiforiadisA.A First Look at E-Scooter Users. In Proc., Advances in Mobility-as-a-Service Systems: Conference on Sustainable Urban Mobility (NathanailE. G.AdamosG.KarakikesI., eds.), Skiathos Island, Greece, June17–19, 2020, Springer, Cham, pp. 882–891.
15.
KrierC.ChrétienJ.LagadicM.LouvetN.How Do Shared Dockless E-Scooter Services Affect Mobility Practices in Paris? A Survey-Based Estimation of Modal Shift. Transportation Research Record: Journal of the Transportation Research Board, 2021. 2675: 291-304.
16.
GuoY.ZhangY.Understanding Factors Influencing Shared E-Scooter Usage and its Impact on Auto Mode Substitution. Transportation Research Part D: Transport and Environment, Vol. 99, 2021, p. 102991.
17.
BaiS.JiaoJ.Dockless E-Scooter Usage Patterns and Urban Built Environments: A Comparison Study of Austin, TX, and Minneapolis, MN. Travel Behaviour and Society, Vol. 20, 2020, pp. 264–272.
18.
CaspiO.SmartM. J.NolandR. B.Spatial Associations of Dockless Shared E-Scooter Usage. Transportation Research Part D: Transport and Environment, Vol. 86, 2020, p. 102396.
LiuM.SeederS.LiH.Analysis of E-Scooter Trips and Their Temporal Usage Patterns. Institute of Transportation Engineers, ITE Journal, Vol. 89, No. 6, 2019, pp. 44–49.
22.
BaltraG.ImanaB.JiangW.KorolovaA.On the Data Fight Between Cities and Mobility Providers. arXiv Preprint arXiv:2004.09072, 2020.
23.
ZhuR.ZhangX.KondorD.SantiP.RattiC.Understanding Spatio-Temporal Heterogeneity of Bike-Sharing and Scooter-Sharing Mobility. Computers, Environment and Urban Systems, Vol. 81, 2020, p. 101483.
24.
MartinE. W.ShaheenS. A.Evaluating Public Transit Modal Shift Dynamics in Response to Bikesharing: A Tale of Two US Cities. Journal of Transport Geography, Vol. 41, 2014, pp. 315–324.
25.
MaX.YuanY.Van OortN.HoogendoornS.Bike-Sharing Systems’ Impact on Modal Shift: A Case Study in Delft, the Netherlands. Journal of Cleaner Production, Vol. 259, 2020, p. 120846.
26.
JiaY.FuH.Association Between Innovative Dockless Bicycle Sharing Programs and Adopting Cycling in Commuting and Non-Commuting Trips. Transportation Research Part A: Policy and Practice, Vol. 121, 2019, pp. 12–21.
27.
GuoY.ZhouJ.WuY.LiZ.Identifying the Factors Affecting Bike-Sharing Usage and Degree of Satisfaction in Ningbo, China. PloS One, Vol. 12, No. 9, 2017, p. e0185100.
28.
BielińskiT.KwapiszA.WażnaA.Bike-Sharing Systems in Poland. Sustainability, Vol. 11, No. 9, 2019, p. 2458.
29.
WangJ.LindseyG.Neighborhood Socio-Demographic Characteristics and Bike Share Member Patterns of Use. Journal of Transport Geography, Vol. 79, 2019, p. 102475.
30.
XinF.ChenY.WangX.ChenX.Cyclist Satisfaction Evaluation Model for Free-Floating Bike-Sharing System: A Case Study of Shanghai. Transportation Research Record: Journal of the Transportation Research Board, 2018. 2672: 21–32.
31.
QianX.JallerM.NiemeierD.Enhancing Equitable Service Level: Which Can Address Better, Dockless or Dock-Based Bikeshare Systems?Journal of Transport Geography, Vol. 86, 2020, p. 102784.
32.
HirschJ. A.Stratton-RaynerJ.WintersM.StehlinJ.HosfordK.MooneyS. J.Roadmap for Free-Floating Bikeshare Research and Practice in North America. Transport Reviews, Vol. 39, No. 6, 2019, pp. 706–732.
33.
BrownA.Dockedvs.Dockless Equity: Comparing Three Micromobility Service Geographies. Journal of Transport Geography, Vol. 96, 2021, p. 103185.
34.
HuS.XiongC.LiuZ.ZhangL.Examining Spatiotemporal Changing Patterns of Bike-Sharing Usage During COVID-19 Pandemic. Journal of Transport Geography, Vol. 91, 2021, p. 102997.
35.
BradshawR.KitchinR.Charting the Design and Implementation of the Smart City: The Case of Citizen-Centric Bikeshare in Hamilton, Ontario. Urban Geography, 2021, pp. 1–23. https://doi.org/10.1080/02723638.2021.1878439.
36.
1.5. Invasion of Privacy. In California Law PART 1. Of Crime and Punishments: TITLE 15. Miscellaneous Crimes, California Law, 1967.
MerlinL. A.YanX.XuY.ZhaoX.A Segment-Level Model of Shared, Electric Scooter Origins and Destinations. Transportation Research Part D: Transport and Environment, Vol. 92, 2021, p. 102709.
40.
JiY.YouQ.JiangS.ZhangH. M.Statistical Inference on Transit Route-Level Origin–Destination Flows Using Automatic Passenger Counter Data. Journal of Advanced Transportation, Vol. 49, No. 6, 2015, pp. 724–737.
41.
JiY.MishalaniR. G.McCordM. R.. Transit Passenger Origin–Destination Flow Estimation: Efficiently Combining Onboard Survey and Large Automatic Passenger Count Datasets. Transportation Research Part C: Emerging Technologies, Vol. 58, 2015, pp. 178–192.
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