Population Mapping with Multisensor Remote Sensing Images and Point-Of-Interest Data

Yang, Xuchao; Ye, Tingting; Zhao, Naizhuo; Chen, Qian; Yue, Wenze; Qi, Jiaguo; Zeng, Biao; Jia, Peng

doi:10.3390/rs11050574

Cited by 67 publications

(63 citation statements)

References 55 publications

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“…To evaluate the performance of the models and for consistency with previous validation studies ( Zou et al, 2019;Yang, Ye, et al, 2019;Wang et al, 2019), the tenfold CV method is used in our study and four statistical metrics-the coefficient of determination (R 2 ), root-mean-square error (RMSE), mean fractional bias (MB), and correlation coefficient (R)-are used to measure the prediction performance. The four statistical metrics are calculated at each radiation site using the following equations (1)-(4), respectively:…”

Section: /2019ea001058mentioning

confidence: 99%

“…DGSR is also crucial for the utilization of solar energy through transformation of technologies (Wu et al, 2012(Wu et al, , 2016Tang et al, 2018;Prăvălie et al, 2019;Zou et al, 2019). In recent years, there has been an aggravation of air pollution in China induced by massive fossil fuel consumption and emissions coinciding with unfavorable weather conditions (Guo et al, 2016Lou et al, 2019;Yang, et al, 2018;Yang, Ye, et al, 2019;Zheng et al, 2019). On the one hand, this has significantly modulated the change in surface solar radiation (Che et al, 2005;Guo et al, 2018;Wang et al, 2012Wang et al, , 2013Wang & Wild, 2016;Zheng et al, 2018;He & Wang, 2020;Yang et al, 2020), while on the other hand, it has led to solar radiation becoming one of the fastest-growing and important sources of clean and renewable energy.…”

Section: Introductionmentioning

confidence: 99%

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Daily Global Solar Radiation in China Estimated From High‐Density Meteorological Observations: A Random Forest Model Framework

Zeng

Wang

Gui

et al. 2020

Earth and Space Science

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Accurate estimation of the spatiotemporal variations of solar radiation is crucial for assessing and utilizing solar energy, one of the fastest‐growing and most important clean and renewable resources. Based on observations from 2,379 meteorological stations along with scare solar radiation observations, the random forest (RF) model is employed to construct a high‐density network of daily global solar radiation (DGSR) and its spatiotemporal variations in China. The RF‐estimated DGSR is in good agreement with site observations across China, with an overall correlation coefficient (R) of 0.95, root‐mean‐square error of 2.34 MJ/m2, and mean bias of −0.04 MJ/m2. The geographical distributions of R values, root‐mean‐square error, and mean bias values indicate that the RF model has high predictive performance in estimating DGSR under different climatic and geographic conditions across China. The RF model further reveals that daily sunshine duration, daily maximum land surface temperature, and day of year play dominant roles in determining DGSR across China. In addition, compared with other models, the RF model exhibits a more accurate estimation performance for DGSR. Using the RF model framework at the national scale allows the establishment of a high‐resolution DGSR network, which can not only be used to effectively evaluate the long‐term change in solar radiation but also serve as a potential resource to rationally and continually utilize solar energy.

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Section: /2019ea001058mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Daily Global Solar Radiation in China Estimated From High‐Density Meteorological Observations: A Random Forest Model Framework

Zeng

Wang

Gui

et al. 2020

Earth and Space Science

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“…This is especially important in low-and middle-income countries (LMICs) where resources for conducting surveys are usually limited. Moreover, the accuracy of the population distribution products in urban areas and in the outskirts is lower due to the high heterogeneity of the urban features [16]. Given the increasing urbanization experienced worldwide, the demand for mapping and the understanding of population distribution at a high-resolution is increasing as well.Dasymetric mapping is a particular cartographic representation of data, where census data are disaggregated into spatial units/grids with the aid of ancillary data to produce HGPS [17].…”

mentioning

confidence: 99%

An Optimal Population Modeling Approach Using Geographically Weighted Regression Based on High-Resolution Remote Sensing Data: A Case Study in Dhaka City, Bangladesh

Roni

Jia

2020

Remote Sensing

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Traditional choropleth maps, created on the basis of administrative units, often fail to accurately represent population distribution due to the high spatial heterogeneity and the temporal dynamics of the population within the units. Furthermore, updating the data of spatial population statistics is time-consuming and costly, which underlies the relative lack of high-resolution and high-quality population data for implementing or validating population modeling work, in particular in low-and middle-income countries (LMIC). Dasymetric modeling has become an important technique to produce high-resolution gridded population surfaces. In this study, carried out in Dhaka City, Bangladesh, dasymetric mapping was implemented with the assistance of a combination of an object-based image analysis method (for generating ancillary data) and Geographically Weighted Regression (for improving the accuracy of the dasymetric modeling on the basis of building use). Buildings were extracted from WorldView 2 imagery as ancillary data, and a building-based GWR model was selected as the final model to disaggregate population counts from administrative units onto 5 m raster cells. The overall accuracy of the image classification was 77.75%, but the root mean square error (RMSE) of the building-based GWR model for the population disaggregation was significantly less compared to the RMSE values of GWR based land use, Ordinary Least Square based land use and building modeling. Our model has potential to be adapted to other LMIC countries, where high-quality ground-truth population data are lacking. With increasingly available satellite data, the approach developed in this study can facilitate high-resolution population modeling in a complex urban setting, and hence improve the demographic, social, environmental and health research in LMICs.producing high-resolution gridded population surfaces (HGPS), which have large benefits for many [5]. Traditionally, the census has been the main data source for such mapping. Yet, the census is normally conducted every 10 years, which is insufficient to fully capture the fast dynamics of the population changes over time. Using traditional methods to update population data frequently is time-consuming, costly, and even infeasible at a large scale [6].Over the past decade, researchers have developed a wide range of methods for mapping the spatial distribution of the population with the aid of Geographic Information Systems (GIS) technology, which is used to create choropleth maps. As the population is not uniformly distributed over space within the administrative units [7], GIS-based discrete and aggregated choropleth maps cannot represent the spatial distribution of the population accurately [8]. Recently, several projects incorporated remote sensing (RS) derived datasets to model population distribution, such as Gridded Population of the World (GPW) [9], Global Rural-Urban Mapping Project (GRUMP) [10], LandScan Global [11], and WorldPop (Asia, Africa, and South America) [12]. Other studies that have be...

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“…Moreover, two raster layers were produced for each POI category. Kernel density estimation (KDE) was applied to each category to generate a smooth and continuous POI density layer [34,47]. KDE is a well-known method to estimate the probability density function of a random variable.…”

Section: Geospatial Big Datamentioning

confidence: 99%

“…In the context of dasymetric mapping, the accuracy of the population estimates depends greatly on the covariates used [27]. Remote sensing products and geospatial big data are the most commonly used covariates in dasymetric mapping [1,3,18,[28][29][30][31][32][33][34][35]. Remotely sensed population-related products, such as land use/land cover (LULC) data and nighttime light (NTL) data, could show the actual surface conditions that reflect the physical factors that affect the population distribution.…”

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confidence: 99%

Improving the Accuracy of Fine-Grained Population Mapping Using Population-Sensitive POIs

Zhao

Zhang

et al. 2019

Remote Sensing

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Many methods have been used to generate gridded population maps by downscaling demographic data. As one of these methods, the accuracy of the dasymetric model depends heavily on the covariates. Point-of-interest (POI) data, as important covariates, have been widely used for population estimation. However, POIs are often used indiscriminately in existing studies. A few studies further used selected categories of POIs identified based only on the nonspatial quantitative relationship between the POIs and population. In this paper, the spatial association between the POIs and population distribution was considered to identify the POIs with a strong spatial correlation with the population distribution, i.e., population-sensitive POIs. The ability of population-sensitive POIs to improve the fine-grained population mapping accuracy was explored by comparing the results of random forest dasymetric models driven by population-sensitive POIs, all POIs, and no POIs, along with the same sets of multisource remote sensing and social sensing data. The results showed that the model driven by population-sensitive POI had the highest accuracy. Population-sensitive POIs were also more effective in improving the population mapping accuracy than were POIs selected based only on their quantitative relationship with the population. The model built using population-sensitive POIs also performed better than the two popular gridded population datasets WorldPop and LandScan. The model we proposed in this study can be used to generate accurate spatial population distribution information and contributes to achieving more reliable analyses of population-related social problems.Dasymetric mapping, on the other hand, was used to generate the 1-km LandScan [5] and the 100-m WorldPop [18] annual population datasets.Dasymetric mapping is a well-known cartographic approach for generating high-resolution population maps [22][23][24]. The idea of dasymetric mapping is to generate a weighting layer using different kinds of covariates. This layer will then be used to redistribute the demographic data. Dasymetric mapping has been demonstrated to be more effective in generating more accurate population estimates than other approaches [25,26]. In the context of dasymetric mapping, the accuracy of the population estimates depends greatly on the covariates used [27]. Remote sensing products and geospatial big data are the most commonly used covariates in dasymetric mapping [1,3,18,[28][29][30][31][32][33][34][35]. Remotely sensed population-related products, such as land use/land cover (LULC) data and nighttime light (NTL) data, could show the actual surface conditions that reflect the physical factors that affect the population distribution. However, these data often lack semantic information. Semantic information can be used to describe the relationship between geographic attributes and geographic features, such as different human activities occurring at accurate geographic locations. With the development of location-aware devices and the emergence and p...

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Population Mapping with Multisensor Remote Sensing Images and Point-Of-Interest Data

Cited by 67 publications

References 55 publications

Daily Global Solar Radiation in China Estimated From High‐Density Meteorological Observations: A Random Forest Model Framework

Daily Global Solar Radiation in China Estimated From High‐Density Meteorological Observations: A Random Forest Model Framework

An Optimal Population Modeling Approach Using Geographically Weighted Regression Based on High-Resolution Remote Sensing Data: A Case Study in Dhaka City, Bangladesh

Improving the Accuracy of Fine-Grained Population Mapping Using Population-Sensitive POIs

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