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RESEARCH ARTICLE
Contents Vol 27(3)

The usefulness of GPS bicycle tracking data for evaluating the impact of infrastructure change on cycling behaviour

Kristiann C. Heesch A C and Michael Langdon B
+ Author Affiliations
- Author Affiliations

A School of Public Health and Social Work and Institute of Health and Biomedical Innovation, Queensland University of Technology, Victoria Park Road, Herston, Qld 4059, Australia.

B Infrastructure Management and Delivery Division, Department of Transport and Main Roads, Floor 11, 313 Adelaide Street, Brisbane, Qld 4000, Australia.

C Corresponding author. Email: k.heesch@qut.edu.au

Health Promotion Journal of Australia 27(3) 222-229 https://doi.org/10.1071/HE16032
Submitted: 19 April 2016  Accepted: 18 July 2016   Published: 1 September 2016

Abstract

Issue addressed: A key strategy to increase active travel is the construction of bicycle infrastructure. Tools to evaluate this strategy are limited. This study assessed the usefulness of a smartphone GPS tracking system for evaluating the impact of this strategy on cycling behaviour.

Methods: Cycling usage data were collected from Queenslanders who used a GPS tracking app on their smartphone from 2013–2014. ‘Heat’ and volume maps of the data were reviewed, and GPS bicycle counts were compared with surveillance data and bicycle counts from automatic traffic–monitoring devices.

Results: Heat maps broadly indicated that changes in cycling occurred near infrastructure improvements. Volume maps provided changes in counts of cyclists due to these improvements although errors were noted in geographic information system (GIS) geo-coding of some GPS data. Large variations were evident in the number of cyclists using the app in different locations. These variations limited the usefulness of GPS data for assessing differences in cycling across locations.

Conclusion: Smartphone GPS data are useful in evaluating the impact of improved bicycle infrastructure in one location. Using GPS data to evaluate differential changes in cycling across multiple locations is problematic when there is insufficient traffic-monitoring devices available to triangulate GPS data with bicycle traffic count data.

So what?: The use of smartphone GPS data with other data sources is recommended for assessing how infrastructure improvements influence cycling behaviour.

Key words: built environment, evaluation, exercise, physical activity.


References

[1]  Litman T. Evaluating active transport benefits and costs: guide to valuing walking and cycling improvements and encouragement programs. Victoria, Canada: Victoria Transport Policy Institute; 2015.

[2]  Figliozzi M, Blanc B. Evaluating the use of crowdsourcing as a data collection method for bicycle performance measures and identification of facility improvement needs. Salem, Oregon: Oregon Department of Transportation and Federal Highway Administration; 2015.

[3]  Garrard J. Evaluating cycle promotion interventions. In Bonham J, Johnson M, editors. Cycling futures. (pp. 429–52). Adelaide: University of Adelaide Press; 2015.

[4]  Götschi T, Garrard J, Giles-Corti B (2016) Cycling as a part of daily life: a review of health perspectives. Transport Rev 36, 45–71.
Cycling as a part of daily life: a review of health perspectives.Crossref | GoogleScholarGoogle Scholar |

[5]  Garrard J, Rissel C, Bauman A. Health benefits of cycling. In Pucher J, Buehler R, editors. City cycling (pp. 31–55). Cambridge, MA: MIT Press; 2012.

[6]  Kelly P, Kahlmeier S, Götschi T, Orsini N, Richards J, Roberts N, et al (2014) Systematic review and meta-analysis of reduction in all-cause mortality from walking and cycling and shape of dose response relationship. Int J Behav Nutr Phys Act 11, 132
Systematic review and meta-analysis of reduction in all-cause mortality from walking and cycling and shape of dose response relationship.Crossref | GoogleScholarGoogle Scholar | 25344355PubMed |

[7]  Mueller N, Rojas-Rueda D, Cole-Hunter T, de Nazelle A, Dons E, Gerike R, et al (2015) Health impact assessment of active transportation: a systematic review. Prev Med 76, 103–14.
Health impact assessment of active transportation: a systematic review.Crossref | GoogleScholarGoogle Scholar | 25900805PubMed |

[8]  Pucher J, Buehler R, Seinen M (2011) Bicycling renaissance in North America? An update and re-appraisal of cycling trends and policies. Transport Res A-Pol 45, 451–75.

[9]  Koorey G. Spaces for cycling. In Bonham J, Johnson M, editors. Cycling futures (pp. 251–82). Adelaide: University of Adelaide Press; 2015.

[10]  Australian Bicycle Council. Australian Census 2011 Travel to work by bicycle only. Sydney: Australian Bicycle Council; 2013.

[11]  World Health Organization. The Ottawa Charter for Health Promotion. Geneva, Switzerland: WHO; 2016 Available from: http://www.who.int/healthpromotion/conferences/previous/ottawa/en/. [Verified 31 March 2016].

[12]  Petrunoff N, Rissel C, Wen LM (2016) The effect of active travel interventions conducted in work settings on driving to work: a systematic review. J Transp Health 3, 61–76.
The effect of active travel interventions conducted in work settings on driving to work: a systematic review.Crossref | GoogleScholarGoogle Scholar |

[13]  Pucher J, Dill J, Handy S (2010) Infrastructure, programs, and policies to increase bicycling: an international review. Prev Med 50, S106–25.
Infrastructure, programs, and policies to increase bicycling: an international review.Crossref | GoogleScholarGoogle Scholar | 19765610PubMed |

[14]  Rissel C, Greaves S, Wen LM, Crane M, Standen C (2015) Use of and short-term impacts of new cycling infrastructure in inner-Sydney, Australia: a quasi-experimental design. Int J Behav Nutr Phys Act 12, 129
Use of and short-term impacts of new cycling infrastructure in inner-Sydney, Australia: a quasi-experimental design.Crossref | GoogleScholarGoogle Scholar | 26444001PubMed |

[15]  Scheepers CE, Wendel-Vos GCW, den Broeder JM, van Kempen EEMM, van Wesemael PJV, Schuit AJ (2014) Shifting from car to active transport: a systematic review of the effectiveness of interventions. Transport Res A-Pol 70, 264–80.

[16]  Broach J, Dill J, Gliebe J (2012) Where do cyclists ride? A route choice model developed with revealed preference GPS data. Transport Res A-Pol 46, 1730–40.

[17]  Casello JM, Usyukov V (2014) Modeling cyclists’ route choice based on GPS data. Transport Res Rec 2430, 155–61.
Modeling cyclists’ route choice based on GPS data.Crossref | GoogleScholarGoogle Scholar |

[18]  Dill J (2009) Bicycling for transportation and health: the role of infrastructure. J Public Health Policy 30, S95–110.
Bicycling for transportation and health: the role of infrastructure.Crossref | GoogleScholarGoogle Scholar | 19190585PubMed |

[19]  Johnson M, Chong D, Carroll J, Katz R, Oxley J, Charlton J. Naturalist cycling study: identifying risk factors for cyclists in the Australian Capital Territory. Report No. 322. Melbourne: MUARC, Monash University, Amy Gillett Foundation; 2014.

[20]  Menghini G, Carrasco N, Schussler N, Axhausen KW (2010) Route choice of cyclists in Zurich. Transport Res A-Pol 44, 754–65.

[21]  Shen L, Stopher PR (2014) Review of GPS travel survey and GPS data-processing methods. Transport Rev 34, 316–34.
Review of GPS travel survey and GPS data-processing methods.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC2cXptlKhsL4%3D&md5=1f8c4be7d910b84e6896a0acd309da4aCAS |

[22]  Griffin GP, Jiao J (2015) Where does bicycling for health happen? Analysing volunteered geographic information through place and plexus. J Transp Health 2, 238–47.
Where does bicycling for health happen? Analysing volunteered geographic information through place and plexus.Crossref | GoogleScholarGoogle Scholar |

[23]  Hood J, Sall E, Charlton B (2011) A GPS-based bicycle route choice model for San Francisco, California. Transport Lett 3, 63–75.
A GPS-based bicycle route choice model for San Francisco, California.Crossref | GoogleScholarGoogle Scholar |

[24]  Hudson JG, Duthie JC, Rathod YK, Larsen KA, Meyer JL. Using smartphones to collect bicycle travel data in Texas. UTCM Project 11–35–69. College Station, Texas: Texas Transportation Institute; 2012.

[25]  Oksanen J, Bergman C, Sainio J, Westerholm J (2015) Methods for deriving and calibrating privacy-preserving heat maps from mobile sports tracking application data. J Transp Geogr 48, 135–44.
Methods for deriving and calibrating privacy-preserving heat maps from mobile sports tracking application data.Crossref | GoogleScholarGoogle Scholar |

[26]  Strava Inc. Strava Metro: better data for better cities. Hanover, New Hampshire: Strava Inc. 2014. Available from: http://metro.strava.com [Verified 15 July 2016].

[27]  Riordan B, Langdon M. Using Strava Metro data for cycling policy and planning. Paper presented at the Asia-Pacific Cycling Congress; 13–16 September 2015. Brisbane, Qld.

[28]  Gordon M. What is Strava Metro? Hanover, New Hampshire: Strava Inc.; 2016. Available from https://support.strava.com/hc/en-us/articles/216918877-What-is-Strava-Metro- [Verified 15 July 2016].

[29]  Norman G, Kesha N. Using smartphones for cycle planning. Paper presented at the IPENZ Transportation Group Conference; 22–24 March 2015. Christchurch, NZ. Available from http://conf.hardingconsultants.co.nz/workspace/uploads/paper-norman-graham-using-54fe436fb2a3e.pdf. [Verified 31 March 2016].

[30]  Australian Bureau of Statistics. Participation in sport and physical recreation, Australia, 2013–14. Canberra: ABS; 2015. Available from: http://www.abs.gov.au/AUSSTATS/abs@.nsf/Lookup/4177.0Explanatory%20Notes12013-14?OpenDocument. [Verified 25 March 2016].

[31]  Heesch KC, Sahlqvist S, Garrard J (2012) Gender differences in recreational and transport cycling: a cross-sectional mixed-methods comparison of cycling patterns, motivators, and constraints. Int J Behav Nutr Phys Act 9, 106
Gender differences in recreational and transport cycling: a cross-sectional mixed-methods comparison of cycling patterns, motivators, and constraints.Crossref | GoogleScholarGoogle Scholar | 22958280PubMed |

[32]  Burke M, James B, Heesch K, Washington TL. Analysis and evaluation of use of the V1 and the South East Freeway Bicycleway post-completion of Stage C of the V1. Brisbane: Transport and Main Roads; 2015.

[33]  Dill J, Gliebe J. Understanding and measuring bicycling behavior: a focus on travel time and route choice. Portland, OR: Oregon Transportation Research and Education Consortium (OTREC); 2008.

[34]  Madsen T, Schipperijn J, Christiansen LB, Nielsen TS, Troelsen J (2014) Developing suitable buffers to capture transport cycling behavior. Front Public Health 2, 61
Developing suitable buffers to capture transport cycling behavior.Crossref | GoogleScholarGoogle Scholar | 24926478PubMed |

[35]  Mavoa S, Oliver M, Witten K, Badland HM (2011) Linking GPS and travel diary data using sequence alignment in a study of children’s independent mobility. Int J Health Geogr 10, 64
Linking GPS and travel diary data using sequence alignment in a study of children’s independent mobility.Crossref | GoogleScholarGoogle Scholar | 22142322PubMed |

[36]  Nitsche P, Widhalm P, Breuss S, Brandle N, Maurer P (2014) Supporting large-scale travel surveys with smartphones – a practical approach. Transport Res A-Pol 43, 212–21.

[37]  Langdon M. An evidence-based assessment of the impact of cycling infrastructure in South East Queensland. Paper presented at the Australian Institute of Traffic Planning and Management 2015 National Conference, 28–31 July 2015, Brisbane. Available from http://www.aitpm.com.au/conference/papers/2015-papers/2015-transport-planning [Verified 29 July 2016].

[38]  Munro C. Australian cycling participation 2013. Report No. AP-C91–13. Sydney, NSW: Austroads Ltd; 2013.

[39]  Rissel CE, New C, Wen LM, Merom D, Bauman AE, Garrard J (2010) The effectiveness of community-based cycling promotion: findings from the Cycling Connecting Communities project in Sydney, Australia. Int J Behav Nutr Phys Act 7, 8
The effectiveness of community-based cycling promotion: findings from the Cycling Connecting Communities project in Sydney, Australia.Crossref | GoogleScholarGoogle Scholar | 20181019PubMed |

[40]  MapMyFitness Inc. MapMyRide. Austin, TX: MapMyFitness; 2016. Available from: http://www.mapmyride.com. [Verified 15 July 2016].

[41]  Heesch KC, James B, Washington T, Zuniga K, Burke M Evaluation of the Veloway 1: a natural experiment of new bicycle infrastructure in Brisbane, Australia. J Transport Health In press.

[42]  Abvio Inc. Cyclemeter. USA; 2015. Available from: https://abvio.com/cyclemeter. [Verified 15 July 2016].

[43]  Pettit CJ, Lieske SN, Leao SZ. Big bicycle data processing: from personal data to urban applications. Paper presented at the XXIII International Society for Photogrammetry and Remote Sensing Conference; 12–19 July 2016. Prague, Czech Republic.

[44]  Australian Institute of Health and Welfare. NACDC: Population projections, 2012 (base) to 2027 for all states and territories at Statistical Area Level 2 (SA2) by sex and age. Canberra: AIHW; 2016. Available from http://www.aihw.gov.au/nacdc/population-projections/. [Verified 25 March 2016].

[45]  Gong H, Chen C, Bialostozy E, Lawon CTA (2012) GPS/GIS method for travel mode detection in New York City. Comput Environ Urban Syst 36, 131–9.
GPS/GIS method for travel mode detection in New York City.Crossref | GoogleScholarGoogle Scholar |

[46]  Li H, Kulik L, Ramamohanarao R (2015) Robust inferences of travel paths from GPS trajectories. Int J Geogr Inf Sci 29, 2194–222.
Robust inferences of travel paths from GPS trajectories.Crossref | GoogleScholarGoogle Scholar |