The development and implementation of an innovative smartphone application to collect route choice preference data

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dc.contributor.advisor Venter, C.J. (Christoffel Jacobus)
dc.contributor.postgraduate Hayes, Gary Patrick
dc.date.accessioned 2024-03-06T13:19:10Z
dc.date.available 2024-03-06T13:19:10Z
dc.date.created 2023-09
dc.date.issued 2023-07
dc.description Thesis (PhD (Engineering))--University of Pretoria, 2023. en_US
dc.description.abstract The research presented in this thesis was motivated by two factors. Firstly, little route choice research has been undertaken in South Africa, especially in urban areas. This has resulted in significant gaps in our understanding of commuter route choice preferences and associated willingness-to-pay measures such as the value of travel time. Secondly, there are recognised limitations in the experimental methodologies used for route preference data collection, i.e., field data collected using revealed preference (RP) methods, and experimental data collected using stated preference (SP) methods. RP methods have high external validity, but the analyst has limited experimental control. SP methods have a high degree of analyst control of the experiment parameters, but the hypothetical nature of the route alternatives provides lower levels of external validity. The research presented in this thesis therefore had four objectives. Firstly, to provide a review of historical research and studies into mode choice and route choice modeling in South Africa and highlight any gaps in our understanding of commuter route choice preferences and the value of travel time. The findings confirmed that no route choice research has been undertaken in South African urban areas for the last two decades, and large gaps exist in our understanding of motorists’ route choice preferences these areas. The findings confirmed the urgent need to undertake route choice research in South African urban settings, especially in the light of the governments user pays policy for urban road and public transport provision. The second objective was to develop and demonstrate the proof-of-concept for an innovative, smartphone-based application with the acronym RAPP-UP (Route Choice Application – University of Pretoria), for collecting motorist route preference data in dense, congested urban road networks based on real-time traffic conditions at the time of the trip. The author of this thesis designed and prepared the specification for RAPP-UP, and an independent contractor was appointed to code the application and make it available on the Google Play Store® for survey participants to download. RAPP-UP was designed to achieve a better balance between external validity and analyst control. The third objective was to use RAPP-UP to collect route preference data from a sample of commuters in Gauteng Province, South Africa. The fourth objective was to estimate various types of discrete choice models to quantify different forms of route preference utility and estimate the associated willingness-to-pay measures such as the commuter value of travel time. RAPP-UP was designed for application in a self-validating survey context that included stated preference (SP) and revealed preference (RP) components. A degree of analyst control was introduced by allowing the analyst to factor the observed attribute levels before presentation to users in a predetermined manner based on an unlabelled fractional factorial design. RAPP-UP’s innovation was its ability to maximise external validity by generating two realistic alternative routes based on real-time road network travel data between a user specified origin and destination, thereby anchoring the experiment in a realistic and familiar setting. This innovation was enhanced by showing the route alternatives on a detailed road map background to provide orientation for the trip origin and destination locations, the routes themselves (highlighted on the road background), as well as the utility attribute levels for each route in a choice set format. After trading-off the attribute levels for each route, users were asked to choose their preferred route (SP component) and were then required to drive their chosen route (self-validating RP component). The GPS function in the smartphone was used to track the user to determine route adherence. An economic experiment was introduced by deducting the toll cost of a chosen tolled route from a user survey account that was allocated to each user at the commencement of the survey. The final survey account balance was paid to each user at the end of the survey. As each trip is one observation, the use of RAPP-UP was required over several days to obtain multiple observations from each user. RAPP-UP was designed to accommodate a detailed form of utility expression that contained a disaggregated form of travel time that specified the proportions of actual travel time (in minutes) in free-flow, slowed-down and stop-start travel conditions. The trip petrol cost (in Rands), toll cost (in Rands) and the probability of on-time arrival at the destination (in percent) were also included in the utility expression. To illustrate proof-of-concept, a small sample of car commuters in the Gauteng Province of South Africa was recruited to participate in a route choice survey using RAPP-UP. The road network in the urban areas of Gauteng Province is dense and congested in the weekday peak periods, and the motorways are tolled. The route preference data of the sample of commuters provided the basis for the estimation of various forms of discrete route choice models. The models confirmed that the attribute coefficients for each category of travel time were significant, thereby corroborating international evidence. The congestion multipliers, i.e., the ratios of the travel time attribute coefficients for each trip time category, were within the ranges determined in international studies. The petrol cost, toll cost and probability of on-time arrival attribute coefficients were also significant. A toll road quality bonus representing the unobserved factors of utility was introduced as a dummy utility attribute for routes with tolled sections. The attribute coefficient had a negative sign, revealing that the survey participants associated a disutility for routes with tolled sections for the unobserved factors of utility. All the objectives of the research were achieved. The research not only added to the body of literature on the topic of route choice behaviour in urban areas, but also provided insights into the practicalities of route choice data collection and model estimation. en_US
dc.description.availability Unrestricted en_US
dc.description.degree PhD (Engineering) en_US
dc.description.department Civil Engineering en_US
dc.description.faculty Faculty of Engineering, Built Environment and Information Technology en_US
dc.identifier.citation * en_US
dc.identifier.other S2023 en_US
dc.identifier.uri http://hdl.handle.net/2263/95096
dc.language.iso en en_US
dc.publisher University of Pretoria
dc.rights © 2021 University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria.
dc.subject UCTD en_US
dc.subject Innovative Smartphone Application en_US
dc.subject Collect Route Choice Preference Data en_US
dc.subject Stated Preference (SP) methods en_US
dc.subject Google Play Store® en_US
dc.subject.other Engineering, built environment and information technology theses SDG-09
dc.subject.other SDG-09: Industry, innovation and infrastructure
dc.subject.other Engineering, built environment and information technology theses SDG-11
dc.subject.other SDG-11: Sustainable cities and communities
dc.title The development and implementation of an innovative smartphone application to collect route choice preference data en_US
dc.type Thesis en_US


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