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Pu Wang, Jian-Jiang Lu, Wei Chen, Peng-Peng Zhao, Lei Zhao. Spatio-Temporal Location Recommendation for Urban Facility Placement via Graph Convolutional and Recurrent Networks[J]. Journal of Computer Science and Technology. DOI: 10.1007/s11390-023-2608-0
Citation: Pu Wang, Jian-Jiang Lu, Wei Chen, Peng-Peng Zhao, Lei Zhao. Spatio-Temporal Location Recommendation for Urban Facility Placement via Graph Convolutional and Recurrent Networks[J]. Journal of Computer Science and Technology. DOI: 10.1007/s11390-023-2608-0

Spatio-Temporal Location Recommendation for Urban Facility Placement via Graph Convolutional and Recurrent Networks

  • The ability to recommend candidate locations for service facility placement is crucial for the success of urban planning. Whether a location is suitable for establishing new facilities is largely determined by its potential popularity. However, it is a non-trivial task to predict popularity of candidate locations due to three significant challenges: 1) the spatio-temporal behavior correlations of urban dwellers, 2) the spatial correlations between candidate locations and existing facilities, 3) the temporal auto-correlations of locations themselves. To this end, we propose a novel semi-supervised learn- ing model, Spatio-Temporal Graph Convolutional and Recurrent Networks, aiming for popularity prediction and location recommendation. Specifically, we first partition the urban space into spatial neighborhood regions centered by locations, extract the corresponding features, and develop the location correlation graph. Next, a contextual graph convolution module based on attention mechanism is introduced to incorporate local and global spatial correlations of locations. A recurrent neural network is proposed to capture temporal dependencies between locations. Furthermore, we adopt a location popularity approximation block to estimate the missing popularity from both spatial and temporal domains. Finally, the overall implicit characteristics are concatenated and then fed into the recurrent neural network to obtain the ultimate popularity. The extensive experiments on two real-world datasets demonstrate the superiority of the proposed model compared with state-of-the-art baselines. 
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