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DEPARTMENT OF GEOMATIC ENGINEERING Mapping Anthropogenic Activities from Earth Observation Data Christopher Doll, Jan-Peter Muller Workshop on Gridding Population Data Columbia University, New York Tuesday 2nd May 2000
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DEPARTMENT OF GEOMATIC ENGINEERING Overview Scientific Justification Mapping Socio-economic parameters from Night-time Data Night-lights and Datasets over the UK Initial Conclusions Future Research Directions
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DEPARTMENT OF GEOMATIC ENGINEERING Scientific Justification Global population remains poorly defined across the Earth’s surface (Clark & Rhind, 1992) Human activity affects both the atmosphere and the surrounding terrestrial/coastal environs Global change has many manifestations and effects on human life –flooding and landslides (Venezuela 10/99, Mozambique 2/2000) »Thousands of people killed and displaced –Storms over Western Europe 12/99, US Hurricanes »Billions of $ insurance loss Satellite monitoring provides the best opportunity to survey changing population rapidly, albeit indirectly through land use changes
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DEPARTMENT OF GEOMATIC ENGINEERING Mapping Anthropogenic Parameters from DMSP-OLS Data Doll, Muller & Elvidge. Ambio May 2000 Global relationships established by country level correlation of lit area and CO 2 emissions (CDIAC) Lit area remapped from 30’’ to 1 with a % lit value in each cell Relationship applied to new 1 map with areal approximation into 10 latitudinal zones
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DEPARTMENT OF GEOMATIC ENGINEERING Mapping CO 2 from DMSP-OLS Global Image gridded to 1º and % lit figure assigned. Result compared with CDIAC 1995 map Similar distribution, but magnitudes are lower than CDIAC ~25% kT of Carbon
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DEPARTMENT OF GEOMATIC ENGINEERING CO 2 Emission difference Map CDIAC - OLS
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DEPARTMENT OF GEOMATIC ENGINEERING Total Lit Area (by country) vs. Purchasing Power Parity GDP provided by WRI (1995)
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DEPARTMENT OF GEOMATIC ENGINEERING Mapping Economic Activity Purchasing Power Parity GDP used as a more equal measure GDP map uses night-lights to distribute relationship at 1° resolution Total of global economy figure of $22.1 trillion cf. $27.7 trillion Intl $, from WRI figures
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DEPARTMENT OF GEOMATIC ENGINEERING DN Value Night-lights within the UK Doll & Muller(2000) ISPRS2000, July 2000 Amsterdam Bartholomew’s 1:250 000 road network map –22 road classes grouped by road type in standard road atlases Institute of Terrestrial Ecology (ITE) land cover map (25 classes) at 25m derived from Landsat imagery –1km summary product giving % coverage of each class –‘Urban’ and ‘Suburban & rural infrastructure’ classes of interest Gridded 200m Population data from UK government 1991 census
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DEPARTMENT OF GEOMATIC ENGINEERING Night-lights and the UK Road Network (Bartholomew’s 1:250 000) Radiance; x10 -10 W.cm 2. m -1.sr -1
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DEPARTMENT OF GEOMATIC ENGINEERING Night-lights and Road Density Non-primary A- Roads dominate in urban areas B-Roads also peak in city centres No comprehensive central list exists of lit road sections for the UK Assumes all roads are lit Will make road density map and compare to gridded population
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DEPARTMENT OF GEOMATIC ENGINEERING 65 km Night-lights and other parameters over London at 1km % coverage Urban (ITE) Suburban/Rural infrastructure (ITE)Gridded Population (1991 census) DMSP-OLS Radiance Calibrated Night-lights Population.km -2 Radiance; W.cm 2. m -1.sr -1 60 km
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DEPARTMENT OF GEOMATIC ENGINEERING Land cover-Population Relationships 43% of urban+suburban land cover 2000 people/km 2 DCW urban layer Less obvious relationship with radiance –Single threshold overestimates some settlements, but omits others Doll & Muller (RSS99) estimated country-level urban population for 12 countries to within 97% Potential to examine population morphology of urban centres All distributions appear to behave like self-critical phenomena 1km pixels for the UK European Cities Log Radiance Log Suburb. cover
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DEPARTMENT OF GEOMATIC ENGINEERING Population density cf. DMSP-OLS radiance Which is best to map urban areas? DN Value Population.km -2
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DEPARTMENT OF GEOMATIC ENGINEERING Initial Conclusions Mapping urban area from night-time data has significant advantages over other RS data sources –But DMSP-OLS data is coarse, 2.7km re-sampled to 1km may not be fine enough Need to distinguish between urban and rural light sources –Consider the use of population density to map urban area Population mapping with radiance calibrated data appears to offer a lot of potential –Data set flexible to a much wider range of methodologies
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DEPARTMENT OF GEOMATIC ENGINEERING Future Research Directions Trial acquisition of night-time data from NASA-EOS (Terra) sensors planned in May/June –MODIS (250m sensitive band) –MISR (possible analysis of directional effects) Assess the potential and limitations in accuracy and reliability of city lights to map global population distribution within urban areas including –How Temporally stable are coefficients? –Next step to try to extrapolate 1km distributions rather than just produce aggregated (country-level) statistics Develop better classification techniques for night- light data –Adaptive Pixel allocation algorithm (ADAPIX) –Assign urban/rural classification based on pixel’s position within a cluster (country-dependent)
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DEPARTMENT OF GEOMATIC ENGINEERING Modelling approach: Adaptive Pixel Allocation Algorithm Multiple orbit compositing can cause small urban areas to look larger Pixels of equal, low radiance can occur in different locations, though unlikely to have same population density Algorithm will assess pixel class based on the size of its cluster and distance from centre Low radiance pixel out of town Low radiance pixel near the centre of town 175 km
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DEPARTMENT OF GEOMATIC ENGINEERING Thank you for your time Christopher Doll; cdoll@ge.ucl.ac.uk Los Angeles at night- 1988
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