Abstract
As urbanization has progressed over the past 40 years, continuous population growth and the rapid expansion of urban land use have caused some regions to experience various problems, such as insufficient resources and issues related to the environmental carrying capacity. The urbanization process can be understood using nighttime light data to quickly and accurately extract urban boundaries at large scales. A new method is proposed here to quickly and accurately extract urban boundaries using nighttime light imagery. Three types of nighttime light data from the DMSP/OLS (US military’s defense meteorological satellite), NPP-VIIRS (National Polar-orbiting Partnership-Visible Infrared Imaging Radiometer Suite), and Luojia1-01 data sets are selected, and the high-precision urban boundaries obtained from a high-resolution image are selected as the true value. Next, 15 cities are selected as the training samples, and the Jaccard coefficient is introduced. The spatial data comparison method is then used to determine the optimal threshold function for the urban boundary extraction. Alternative high-precision urban boundary truth-values for the 13 cities are then selected, and the accuracy of the urban boundary extraction results obtained using the optimal threshold function and the mutation detection method are evaluated. The following observations are made from the results: (i) The average relative errors for the urban boundary extraction results based on the three nighttime light data sources (DMSP/OLS, NPP-VIIRS, and Luojia1-01) using the optimal threshold functions are 29%, 20%, and 39%, respectively. Compared with the mutation detection method, these relative errors are reduced by 83%, 18%, and 77%, respectively; (ii) The average overall classification accuracies of the extracted urban boundaries are 95%, 96%, and 93%, respectively, which are 5%, 1%, and 7% higher than those for the mutation detection method; (iii) The average Kappa coefficients of the extracted urban boundaries are 61%, 71%, and 61%, respectively, which are 5%, 4%, and 12% higher than for the mutation detection method.
Highlights
Over the past 40 years, China has experienced rapid urbanization due to its policies of reform and opening up [1]
The urban boundary extraction is based on the NPP-VIIRS data that was first released in 2012, while the true values used in this paper are from 2010, and some areas are impacted by the urban growth over this two-year discrepancy
The high-precision urban boundary obtained from high-resolution imagery is used as the true value, and 15 cities are selected as the training samples to introduce and determine the Jaccard coefficients
Summary
Over the past 40 years, China has experienced rapid urbanization due to its policies of reform and opening up [1]. Higher resolution images (such as from QuickBird in the United States, GF satellite imagery in China, etc.) have the ability to better distinguish features and can be used for urban boundary extraction. These data come with a high acquisition cost, a high data processing workload, a weak acquisition ability, a long renewal period, large spectral differences in ground objects, and a strong regional heterogeneity, which hinder the automation of urban boundary extraction at national or large regional scales [3,4,5,6]. Nighttime light data has been used as early as 1970 for urban extraction [17]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
