Transportation mode detection – an in-depth review of applicability and reliability

Prelipcean, Adrian Corneliu; Gidófalvi, Gyözö; Susilo, Yusak O.

doi:10.1080/01441647.2016.1246489

Cited by 68 publications

(56 citation statements)

References 50 publications

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“…In the past, inaccurate GPS measurements and heavy energy-consuming GPS measurements have been obstacles for large-scale applications (Rieser-Schüssler and Axhausen, 2014). Recently, with increased accuracy and employment of battery-management strategies, a growing number of studies have reported successful pilot applications (e.g., Reddy et al, 2010;Nitsche et al, 2012;Geurs et al, 2015;Cottrill et al, 2013;Zhao et al, 2015;Prelipcean et al, 2014Prelipcean et al, , 2017Safi et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Automatic Trip Detection with the Dutch Mobile Mobility Panel: Towards Reliable Multiple-Week Trip Registration for Large Samples

Thomas¹,

Geurs²,

Koolwaaij³

et al. 2018

Journal of Urban Technology

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This paper examines the accuracy of trip and mode choice detection of the last wave of the Dutch Mobile Mobility Panel, a large-scale three-year, smartphone-based travel survey. Departure and arrival times, origins, destinations, modes, and travel purposes were recorded during a four week period in 2015, using the MoveSmarter app for a representative sample of 615 respondents, yielding over 60 thousand trips. During the monitoring period, respondents also participated in a web-based prompted recall survey and answered additional questions. This enables a comparison between automatic detected and reported trips. Most trips were detected with no clear biases in trip length or duration, and transport modes were classified correctly for over 80 percent of these trips. There is strong evidence that smartphone-based trip detection helps to reduce underreporting of trips, which is a common phenomenon in travel surveys. In the Dutch Mobile Mobility Panel, trip rates are substantially higher than trip-diary based travel surveys in the Netherlands, in particular for business and leisure trips which are often irregular. The rate of reporting also hardly decreased during the four-week period, which is a promising result for the use of smartphones in long duration travel surveys.

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Section: Introductionmentioning

confidence: 99%

Automatic Trip Detection with the Dutch Mobile Mobility Panel: Towards Reliable Multiple-Week Trip Registration for Large Samples

Thomas¹,

Geurs²,

Koolwaaij³

et al. 2018

Journal of Urban Technology

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“…Using heterogeneous sensor datasets to classify in‐vehicle status and PA with hierarchical processes is novel and has considerable potential for application in a wide range of domains. For instance, Prelipcean, Gidyfalvi, and Susilo () highlighted that interdisciplinary solutions regarding travel‐mode detection should not be limited to one research domain. They also emphasized that the current research trend of validating new algorithms and using datasets that cannot be shared widely hinders interdisciplinary studies.…”

Section: Discussionmentioning

confidence: 99%

Automatic physical activity and in‐vehicle status classification based on GPS and accelerometer data: A hierarchical classification approach using machine learning techniques

Lee

Kwan

2018

Transactions in GIS

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Due to the advancement of tracking technology, a large quantity of movement data has been collected and analyzed in various research domains. In human mobility and physical activity (PA) research, GPS trajectories and the capabilities of geographic information systems (GIS) facilitate a better understanding of the associations between PA and various environmental factors taking individuals' daily travels into account. PA research, however, needs to widen its focus from the intensity of PA to types of PA, which may provide useful clues for understanding specific health behaviors in particular geographic contexts. This study proposes and develops an algorithm to automatically classify PA types and in-vehicle status using GPS and accelerometer data. Walking, standing, jogging, biking and sedentary/in-vehicle statuses are identified through hierarchical classification processes based on machine learning and geospatial techniques. The proposed algorithm achieved high predictive accuracy on real-world GPS and accelerometer data. It can greatly reduce participants' and researchers' burdens by automatically identifying PA types and in-vehicle status for human mobility research, which is also known as travel mode imputation in transportation research. | 1523 LEE and KWAN

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“…Applying AI and ML methods for automatically inferring the aforementioned entities and attributes is an active field of research (see Prelipcean et al, 2014Prelipcean et al, , 2016 for automatic travel mode detection, Bohte & Maat, 2009 for purpose inference and Prelipcean, 2016;J. Wolf, 2006 for destination inference) that does not have any widely accepted methods to perform the inferences or to measure the performance of the methods (Prelipcean et al, , 2017b. In its current form, MEILI uses standard AI and ML algorithms, i.e., a variation of a clustered nearest neighbor classifier for travel mode detection (which obtained an initial precision of 53.5% for 15 travel modes and increased to 75% precision after each user annotated the triplegs of their first days), and a Naive-Bayes classifier for destination and purpose inference (a precision of 54.7% for 13 purposes, and a precision of 41.9% for destination inference 2 ) .…”

Section: Middleware Component -Artificial Intelligencementioning

confidence: 99%

“…The learning power of the classifier from annotated data is shown in Figure 7. Whereas the common research focus is infering travel modes (Gong et al, 2017;Prelipcean et al, 2014Prelipcean et al, , 2016Prelipcean et al, , 2017bShafique & Hato, 2017;Zhou et al, 2017) or destinations and purposes (Gong et al, 2016(Gong et al, , 2017Prelipcean, 2016;Su et al, 2014;Usyukov, 2017) after the completion of the case study, the main issue with that approach is the lack of focus on user experience improvements. Embedding active learning as part of the annotation process improves the user experience since it minimizes the amount of data the users have to annotate and gives the users the opportunity to correct the output of the classifiers.…”

Section: The Effect Of Active Learning For Travel Mode Detectionmentioning

confidence: 99%

“…An in-depth analysis of the performance of the classifiers used by MEILI has been extensively covered by Prelipcean, 2016, where the classifier achieves a top 3 precision of 82.1% for 14 different travel modes. For further discussions on travel mode detection from an interdisciplinary perspective, the reader is directed towards Prelipcean et al, 2017b.…”

Section: The Effect Of Active Learning For Travel Mode Detectionmentioning

confidence: 99%

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MEILI: A travel diary collection, annotation and automation system

Prelipcean

Gidófalvi²,

Susilo

2018

Computers, Environment and Urban Systems

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Transportation mode detection – an in-depth review of applicability and reliability

Cited by 68 publications

References 50 publications

Automatic Trip Detection with the Dutch Mobile Mobility Panel: Towards Reliable Multiple-Week Trip Registration for Large Samples

Automatic Trip Detection with the Dutch Mobile Mobility Panel: Towards Reliable Multiple-Week Trip Registration for Large Samples

Automatic physical activity and in‐vehicle status classification based on GPS and accelerometer data: A hierarchical classification approach using machine learning techniques

MEILI: A travel diary collection, annotation and automation system

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