Abstract
The increasing availability of location‐acquisition technologies has enabled collecting large‐scale spatiotemporal trajectories, from which we can derive semantic information in urban environments, including location, time, direction, speed, and point of interest. Such semantic information can give us a semantic interpretation of movement behaviors of moving objects. However, existing semantic enrichment process approaches, which can produce semantic trajectories, are generally time‐consuming. In this paper, we propose an efficient semantic enrichment process framework to annotate spatiotemporal trajectories by using geographic and application domain knowledge. The framework mainly includes preannotated semantic trajectory storage phase, spatiotemporal similarity measurement phase, and semantic information matching phase. Having observed the common trajectories in the same geospatial object scenes, we propose a semantic information matching algorithm to match semantic information in preannotated semantic trajectories to new spatiotemporal trajectories. In order to improve the efficiency of this approach, we build a spatial index to enhance the preannotated semantic trajectories. Finally, the experimental results based on a real dataset demonstrate the effectiveness and efficiency of our proposed approaches.
Highlights
Spatiotemporal trajectories record the spatiotemporal position sequences of moving objects
We propose a new semantic enrichment process approach named Efficient Semantic Enrichment Process for Spatiotemporal Trajectories based on Semantic Information Matching (SEPSIM), which firstly uses semantic information in preannotated semantic trajectories for annotating spatiotemporal trajectories
In order to improve the efficiency of the SEPSIM approach, we establish a spatial index (ii) We propose a new standard to measure the effectiveness of semantic enrichment process approaches
Summary
Spatiotemporal trajectories record the spatiotemporal position sequences of moving objects. Location-based social networks (LBSN), such as Twitter and Weibo, produce multifaceted semantic information, which contains the moving state of moving objects (e.g., speed and direction) and environment information (e.g., air temperature and spatial topological relationship) [1]. Combing semantic information, such as user’s personalized characteristics, landmark names, user’s interest, and occupation into the user’s spatiotemporal trajectories, will contribute to the recommendation of nearby hot spots of interest for users [2, 3]. It can be seen that mining semantic trajectories [4] can better meet the needs of decision analysis applications
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