Urban Radiance

What have global data sets that estimate population density, economic productivity, measles outbreaks, rural poverty, resource footprints and electrification rates, urbanization and suburbanization, or average wages in common? They are all based on nighttime imagery of city lights captured by the Operational Line Scanner (OLS) sensor on the satellites from the US Defense Meteorological Satellite Program (DMSP).

History

What should later become the workhorse of geographers and economists was initially a completely accidental by-product: of a cold-war era military satellite program—launched in the 1950s by the US Air Force for estimating cloud cover and precipitation for reconnaissance missions. Army engineers discovered that the sensors were sensitive enough to capture artificial radiance of cities during moonless nights without cloud cover.

In 1978, Thomas A. Croft published the first global composite of night-time images in the Scientific American. At that time, the image data had to be manually stitched together from analog films ejected in capsules from the satellite, which had to be laboriously recovered by the military. Today, the Black Marble data set has become one of the most popular motifs of space imagery.

While DPMS images are usually used to show regional differences, this project visualizes temporal change in urban radiance from 1992 until 2015. It is the first interactive visualization of radiance time series data.

How to read the images

Methods

Radiance information is compared with country-level GDP and Population data from the UN. To this end, the frequency-normalized satellite composites were re-projected into the equal-area Sinusoidal projection and summarized by brightness. Tools used: R and Qgis

Despite its robustness for spatial analysis, DMSP composites are noisy data. Original composites contain artifacts originating from gas flares, Aurorae Borealis, variations due to cloud cover and sensor technology. In highly illuminated areas such as Singapore, brightness is clipped to a maximum value. Since the sensors are not calibrated for measuring urban radiance, the resulting values are dimensionless.

2016, Dietmar Offenhuber

Bibliography

1. Sutton P. Modeling population density with night-time satellite imagery and GIS. Comput Environ Urban Syst. Elsevier; 1997;21: 227–244.
2. Sutton PC. A scale-adjusted measure of “Urban sprawl” using nighttime satellite imagery. Remote Sens Environ. 2003;86: 353–369.
3. Henderson JV, Storeygard A, Weil DN. Measuring Economic Growth from Outer Space. National Bureau of Economic Research; 2009 Jul. Report No.: 15199.
4. Florida R. The Economic Data Hidden in Nighttime Views of City Lights. In: CityLab. 29 May 2014.
5. Bharti N, Tatem AJ, Ferrari MJ, Grais RF, Djibo A, Grenfell BT. Explaining seasonal fluctuations of measles in Niger using nighttime lights imagery. Science. 2011;334: 1424–1427.
6. Jean N, Burke M, Xie M, Davis WM, Lobell DB, Ermon S. Combining satellite imagery and machine learning to predict poverty. Science. 2016;353: 790–794.
7. Elvidge CD, Sutton PC, Ghosh T, Tuttle BT, Baugh KE, Bhaduri B, et al. A global poverty map derived from satellite data. 2009;35: 1652–1660.
8. Elvidge CD, Baugh KE, Sutton PC, Bhaduri B, Tuttle BT, Ghosh T, et al. Who’s in the Dark—Satellite Based Estimates of Electrification Rates. Urban Remote Sensing. John Wiley & Sons, Ltd; 2011. pp. 211–224.
9. Campanella TJ. The Concrete Dragon: China’s Urban Revolution and What it Means for the World. Princeton Architectural Press; 2012.
10. Mellander C, Stolarick K, Matheson Z, Lobo J. Night-Time Light Data: A Good Proxy Measure for Economic Activity?. Royal Institute of Technology, CESIS - Centre of Excellence for Science and Innovation Studies; 2013 Jun. Report No.: 315.
11. Hall RC. A history of the military polar orbiting meteorological satellite program. DTIC Document; 2001.
12. Croft TA. Nighttime Images of the Earth from Space. Scientific American. Jul 1978. doi:10.1038/scientificamerican0778-86