Integrating physical model-based features and spatial contextual information to estimate building height in complex urban areas

•A new building heights estimation method for heterogeneous urban areas.•Physical model-based features enhanced the physical significance of the model.•Spatial contextual information reduced model RMSE by on average of 2.3 m.•Spatial contextual information reduced the overestimation of low-rise buil...

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Bibliographic Details
Published in:International journal of applied earth observation and geoinformation 2024-02, Vol.126, p.103625, Article 103625
Main Authors: Dong, Baiyu, Zheng, Qiming, Lin, Yue, Chen, Binjie, Ye, Ziran, Huang, Chenhao, Tong, Cheng, Li, Sinan, Deng, Jinsong, Wang, Ke
Format: Article
Language:English
Subjects:
Building Height Estimation
Machine Learning
Physical Model-Based Features
Spatial Contextual Information
Urbanization
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Summary:•A new building heights estimation method for heterogeneous urban areas.•Physical model-based features enhanced the physical significance of the model.•Spatial contextual information reduced model RMSE by on average of 2.3 m.•Spatial contextual information reduced the overestimation of low-rise buildings. Building height, as an essential measure of urban vertical structure, is key to understanding how urbanization is reshaping inner-city characteristics, particularly in developing countries. However, estimating building height in urban environments remains challenging. Building height estimation with physical model-based feature approaches and machine learning approaches are limited by a constrained large-scale application capability and the lack of physical significance, respectively. In this study, we proposed a two-step method to estimate building height in spatially heterogeneous urban areas by integrating the merits of machine learning approaches and physical model-based features, together with spatial contextual information. First, we trained a block-level machine learning model on Hangzhou block units to estimate average block-level building height as spatial contextual information. Second, we trained a building-level machine learning model to estimate the final building height of Hangzhou with the estimated spatial contextual information and additional physical model-based features, including radar look angle, building wall orientation, the length of the building, and dielectric constants of the building wall. Our results showed that the proposed method can largely improve the performance of building height estimation, with an overall R2 and RMSE of 0.76 and 6.64 m, respectively. Incorporating physical model-based features and spatial contextual information reduced model RMSE by 32 %. Compared with existing methods, our proposed model demonstrated a better accuracy performance and improved capability in addressing the prevailing overestimation of low-rise buildings and the underestimation of high-rise buildings in highly heterogeneous urban areas.
ISSN:1569-8432
1872-826X
DOI:10.1016/j.jag.2023.103625