An Ensemble Learning Approach for Urban Land Use Mapping Based on Remote Sensing Imagery and Social Sensing Data
Abstract
:1. Introduction
2. Materials and Methods
2.1. The Ensemble Learning Model
2.2. Urban Feature Engineering
2.2.1. Extraction of Physical Features
2.2.2. Extraction of Socioeconomic Features
2.3. Land Use Taxonomy for Model Training and Validation
Algorithm 1 Semi-Automatically Label Method |
Input: Research units U, Land use type data in raster dataset LU Output: Label of land use type for each unit L Foreach unit u of U do I←the number of each raster cells intersects with u P←Proportion of each type in I P←sort(P) If P [0] > 0.6 do //Pure parcel L[u]←type of P[0] Else if P[0] > 0.4 and P[1] < 0.2 do //Mixed parcel with a major category L[u]←type of P[0] Else //Mixed parcel L[u]←Artificial discrimination considering multisource data such as POI and Street view End End Return L |
3. Results
3.1. Classification Accuracy
3.2. Analysis of Contributing Features
3.3. Comparison with Alternative Models
4. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
Appendix A.1. Google Remote Sensing Images
Appendix A.2. Tencent Street-View Images
Appendix A.3. Building Footprints
Appendix A.4. Baidu POIs
Appendix A.5. Sina Weibo Check-Ins
Appendix A.6. Derived Urban Features
Data Source | Variable | Description |
---|---|---|
Remote sensing image | Lawn | Lawn, and small-scale permeable land inside a large lawn area |
Shrub | Shrubs and trees | |
Ground | Bare land, farmland, construction site, etc. | |
Impervious surface | Impervious surface except for roads, such as parking lot, square, cement floor | |
Road | Artificial paved and nonpaved pavement, Including trunk roads, feeder roads, airport runways | |
Building | Artificial roofed buildings of various shapes and types, excluding open-air stadiums. | |
Water | Lakes, oceans, rivers, sewage treatment plants, swimming pools, etc. | |
Street-view image | 365 scene categories | See the link for the full list: https://github.com/metalbubble/places_devkit/blob/master/categories_places365.txt |
Building footprint | Volume (area) | Plot ratio of a parcel |
Height (mean) | The average height of all buildings in a parcel. | |
Height (std) | The standard deviation of the height of all buildings within a parcel. | |
Height (mean/area) | The average building height weighted by building area. | |
Height (std/area) | The standard deviation of building height weighted by building area. | |
Building area (mean) | The average building area of all the buildings in a parcel | |
Building area (std) | The standard deviation of building area in a parcel | |
Perimeter (mean) | The average perimeter of the buildings | |
Perimeter (std) | The standard deviation of building circumference. | |
Corner (mean) | The average number of buildings’ area/perimeter in a parcel. | |
Corner (std) | The standard deviation of buildings’ area/perimeter in a parcel. | |
Age (mean) | Average completion time of the building. | |
Age (std) | The standard deviation of completion time. | |
Nearest distance | The average of nearest-neighbor distance between buildings in a parcel | |
Zonal nearest distance | Neighborhood distance calculated by regional method | |
POI | Residence | Residential buildings and apartments |
Company | Companies | |
Education | Education and training institutions | |
Office | Office buildings and other workplaces | |
Hospital | Hospitals, clinics and pharmacies | |
Parking | Open or indoor parking lot | |
Shop | Retail store, market or other shopping place | |
Food | Restaurants and snack bars | |
Domestic | Domestic services and amenities | |
University | Universities and colleges | |
Government | Government agencies and other organizations | |
Car service | Automobile sales and maintenance | |
Hotel | Hotels, inns and other places for temporary accommodation | |
Leisure | Recreation facilities and the bars | |
Beauty | Beauty salons, hair salons | |
Sport | Stadiums and other sports facilities | |
Finance | Banks and other financial institutions | |
Media | Press, TV station | |
Tourism | Tourist attractions and museums | |
Transport | Transportation facilities | |
School | Kindergartens, primary schools and middle schools | |
Research | Research institutes | |
Check-in | Local | Volumes of locals’ check-ins in 24 h |
Visitor | Volumes of visitor’ check-ins in 24 h |
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Land Use | Description |
---|---|
Commercial | Retail, wholesale market, restaurant, office building, shopping center, hotel, entertainment (such as theatre, concert hall, recreational facilities) |
Educational | Universities, colleges, primary and secondary schools, kindergarten and its ancillary facilities |
Residential | Urban residential buildings (including bungalow, multistorey or high-rise buildings), homestead |
Natural | Natural vegetation or artificial vegetation, water and water infrastructure |
Civic | Government agencies and organizations, hospitals, etc. |
Transport | Airport, railway station, bus stop, and other transportation facilities |
Industrial | Industrial land and storehouse |
Agricultural | Farmland, natural or artificial grasslands and shrublands for grazing livestock |
Other | Vacant land, bare land, railway, highway, rural road, etc. |
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Huang, Z.; Qi, H.; Kang, C.; Su, Y.; Liu, Y. An Ensemble Learning Approach for Urban Land Use Mapping Based on Remote Sensing Imagery and Social Sensing Data. Remote Sens. 2020, 12, 3254. https://doi.org/10.3390/rs12193254
Huang Z, Qi H, Kang C, Su Y, Liu Y. An Ensemble Learning Approach for Urban Land Use Mapping Based on Remote Sensing Imagery and Social Sensing Data. Remote Sensing. 2020; 12(19):3254. https://doi.org/10.3390/rs12193254
Chicago/Turabian StyleHuang, Zhou, Houji Qi, Chaogui Kang, Yuelong Su, and Yu Liu. 2020. "An Ensemble Learning Approach for Urban Land Use Mapping Based on Remote Sensing Imagery and Social Sensing Data" Remote Sensing 12, no. 19: 3254. https://doi.org/10.3390/rs12193254
APA StyleHuang, Z., Qi, H., Kang, C., Su, Y., & Liu, Y. (2020). An Ensemble Learning Approach for Urban Land Use Mapping Based on Remote Sensing Imagery and Social Sensing Data. Remote Sensing, 12(19), 3254. https://doi.org/10.3390/rs12193254