Abstract
Identifying stops from GPS trajectories is one of the main concerns in the study of moving objects and has a major effect on a wide variety of location-based services and applications. Although the spatial and non-spatial characteristics of trajectories have been widely investigated for the identification of stops, few studies have concentrated on the impacts of the contextual features, which are also connected to the road network and nearby Points of Interest (POIs). In order to obtain more precise stop information from moving objects, this paper proposes and implements a novel approach that represents a spatio-temproal dynamics relationship between stopping behaviors and geospatial elements to detect stops. The relationship between the candidate stops based on the standard time–distance threshold approach and the surrounding environmental elements are integrated in a complex way (the mobility context cube) to extract stop features and precisely derive stops using the classifier classification. The methodology presented is designed to reduce the error rate of detection of stops in the work of trajectory data mining. It turns out that 26 features can contribute to recognizing stop behaviors from trajectory data. Additionally, experiments on a real-world trajectory dataset further demonstrate the effectiveness of the proposed approach in improving the accuracy of identifying stops from trajectories.
Highlights
In recent years, Global Positioning System technology has become more widely applied in our daily lives
By comparing four Mobility Context Cube (MCC) with different performance, we found that the combination of spatial resolution 200 m × 200 m and temporal resolution 60 min is easier to capture the spatial-temporal dynamic changes in the semantic environment of Points of Interest (POIs)
By projecting the stop points into the MCCs we constructed, staying behaviors can be able to analyze when it is more likely to occur and where the type of POIs is more likely to occur
Summary
Global Positioning System technology (such as GPS, Beidou, GLONASS, and so on) has become more widely applied in our daily lives. Trajectory data offer a wealth of information and knowledge that can be applied to many sectors, such as location services [3,4], traffic management [5,6], urban planning [7,8], and animal welfare [9,10]. It is important to accurately discover the semantic information behind the original trajectory data and to interpret the human movement actions described by the trajectory from a semantic perspective. This will help to direct certain applications of location-based services and make them more convenient to use, which is the primary concern of new research. Trajectory data often includes human movement connected to the geographical context, which is becoming increasingly important in the representation and interpretation of real information embedded in movements and further processing [11]
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