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Supervised versus semi-supervised urban functional area prediction: uncertainty, robustness and sensitivity

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Fraedrich,  Klaus F.
MPI for Meteorology, Max Planck Society;

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Citation

Deng, R., Guan, Y., Cai, D., Yang, T., Fraedrich, K. F., Zhang, C., et al. (2023). Supervised versus semi-supervised urban functional area prediction: uncertainty, robustness and sensitivity. Remote Sensing, 15: 341. doi:10.3390/rs15020341.


Cite as: https://hdl.handle.net/21.11116/0000-000C-999D-7
Abstract
To characterize a community-scale urban functional area using geo-tagged data and available land-use information, several supervised and semi-supervised models are presented and evaluated in Hong Kong for comparing their uncertainty, robustness and sensitivity. The following results are noted: (i) As the training set size grows, models' accuracies are improved, particularly for multi-layer perceptron (MLP) or random forest (RF). The graph convolutional network (GCN) (MLP or RF) model reveals top accuracy when the proportion of training samples is less (greater) than 10% of the total number of functional areas; (ii) With a large amount of training samples, MLP shows the highest prediction accuracy and good performances in cross-validation, but less stability on same training sets; (iii) With a small amount of training samples, GCN provides viable results, by incorporating the auxiliary information provided by the proposed semantic linkages, which is meaningful in real-world predictions; (iv) When the training samples are less than 10%, one should be cautious using MLP to test the optimal epoch for obtaining the best accuracy, due to its model overfitting problem. The above insights could support efficient and scalable urban functional area mapping, even with insufficient land-use information (e.g., covering only similar to 20% of Beijing in the case study).