Abstract
The ubiquitous connectivity of Location-Based Systems (LBS) allows people to share individual location-related data anytime. In this sense, Location-Based Social Networks (LBSN) provides valuable information to be available in large-scale and low-cost fashion via traditional data collection methods. Moreover, this data contains spatial, temporal, and social features of user activity, enabling a system to predict user mobility. In this sense, mobility prediction plays crucial roles in urban planning, traffic forecasting, advertising, and recommendations, and has thus attracted lots of attention in the past decade. In this article, we introduce the Ensemble Random Forest-Markov (ERFM) mobility prediction model, a two-layer ensemble learner approach, in which the base learners are also ensemble learning models. In the inner layer, ERFM considers the Markovian property (memoryless) to build trajectories of different lengths, and the Random Forest algorithm to predict the user’s next location for each trajectory set. In the outer layer, the outputs from the first layer are aggregated based on the classification performance of each weak learner. The experimental results on the real user trajectory dataset highlight a higher accuracy and f1-score of ERFM compared to five state-of-the-art predictors.
Highlights
Over the past decade, an overwhelming number of location-aware services and applications have profoundly changed the way people live [1]
We extend the previous work [18] by introducing an Ensemble Random Forest-Markov predictor, called ERFM
ERFM collective (ERFM-CT) had the worst performance with a low accuracy ratio and f1 score for both maximum lengths (2 and 3)
Summary
An overwhelming number of location-aware services and applications have profoundly changed the way people live [1]. The ubiquitous connectivity of Location-Based Systems (LBS) allows people to share individual location-related data anytime [2] In this sense, Location-Based Social Networks (LBSN) [3], such as Foursquare and Instagram, became popular to provide public data capable of mapping people through status, check-ins, and photos shared online, leading to a new urban computing era [4]. LBSN provides valuable information that is currently available in large-scale and low-cost fashion via any traditional data collection methods [7]. In this sense, social media is an important tool in urban computing to provide urban data with social features, such as the user’s preferences and Araújo et al Journal of Internet Services and Applications (2020) 11:7 routine. It can capture user preferences and location profiles to investigate where and when a user wants to explore (location recommendation)
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