1. ESM 266: Multispectral remote sensing
2. 2 Radiation and remote sensing For example, if energy being sensed comes from the Sun, it:
is radiated by atomic particles at the source (the Sun)
propagates through the vacuum of space at the speed of light
interacts with Earth's atmosphere
interacts with Earth's surface
interacts with Earth's atmosphere once again, and
finally reaches our sensing system
where it interacts with various optical systems, filters, emulsions, or detectors
3. 3 Atmospheric absorption�and scattering
4. 4 Relation between frequency and wavelength
6. Sun glint and wildfires near Carpenteria Bay, Queensland, Australia
7. 7 Terminology Radiant flux F, units W
Irradiance (flux density) E, units Wm–2
(called Exitance M when away from surface)
Radiance L, units Wm–2sr–1
Note: All can be functions of wavelength and have units µm–1
8. 8 Reflectance terminology
9. 9 Relation between flux density and intensity
10. Steradian (Solid Angle) The steradian (sr) is the unit of solid angle
defined as: W = A/r2
11. 11 Overview of typical system
12. 12 Format of a multispectral image
13. 13 Detector configurations: breaking up the spectrum
14. 14 Characteristics of several sensors
15. 15 Spatial, spectral characteristics of some multispectral sensors
16. Sun’s radiant energy distribution
17. 17 Landsat ETM+ spectral bands
18. Band 1 (Blue: 0.45 - 0.52 mm)
good water penetration
differentiating soil and rock surfaces from vegsmoke plumes
most sensitive to atmospheric haze
Band 2 (Green: 0.52 - 0.60 mm)
water turbidity differences
sediment and pollution plumes
discrimination of broad classes of vegetation
Band 3 (Red: 0.63 - 0.69 mm)
strong chlorophyll absorption (veg. vs. soil)
urban vs. rural areas
19. Band 4 (NIR1: 0.76 - 0.90 mm)
different vegetation varieties and conditions
dry vs. moist soil
coastal wetland, swamps, flooded areas
Band 5 (NIR2: 1.55 - 1.75 mm)
leaf-tissue water content
soil moisture
snow vs cloud discrimination
Band 6 (Thermal: 10.4 - 12.5 mm)
heat mapping applications (coarse resolution)
radiant surface temperature range: -100oC to +150oC
Band 7 (NIR3: 2.08 - 2.35 mm)
absorption band by hydrous minerals (clay, mica)
lithologic mapping (clay zones)
20. 20 Landsat 7 orbits and acquisitions, 4/30/2005
21. 21 ASTER: Advanced Spaceborne Thermal Emission and Reflection Radiometer Launched on Terra 12/18/1999
4 VNIR bands
15m resolution, 24ş crosstrack pointing
6 SWIR bands
30m resolution, 8.5ş crosstrack pointing
5 thermal bands
60m resolution, 8.5ş crosstrack pointing
See ASTER website for details
23. 23 MODIS: Moderate Resolution Imaging Spectroradiometer Launched on Terra 12/18/1999, on Aqua 3/24/2002
Terra crosses Equator ~10:30 am, Aqua ~1:30 pm (orbit time is ~98 min)
36 spectral bands with resolutions of 250m, 500m, and 1km
http://modis.gsfc.nasa.gov/about/specifications.php
Global coverage 1-2 days depending on latitude
Pointing, ±55° from nadir
24. 24 Spectral signatures The spectral signature of an object in an image involves
spectral BRDF of the object, i.e. fr(?, angles)
(and other objects in the IFOV)
(may change w time, e.g. vegetation in summer vs winter)
the sensor’s bands, wavelengths, spectral and radiometric resolution, dynamic range
scattering and absorption by the atmosphere in those bands
amount of energy available (Sun or emitted) in those bands
(A combination of physical and sensor characteristics)
25. Atmospheric spectrum
26. Snow, vegetation, rock: spectra of mixed pixels
27. 27 Ice dam on Russell Fjord by Hubbard Glacier
28. Ice shelf disintegration from MODIS Direct response to regional warming
29. 29 ASTER: Erupting Mt Usu, Hokkaido
30. 30 MODIS: Fires in southeastern U.S.
31. Spectra with 7 MODIS “land” bands (250-500m resolution, global daily coverage)
32. 32 Simple (snow/no-snow) algorithm for TM bands on MODIS Normalized difference snow index
Thresholds for MODIS algorithm (Hall)
If TMband 4>11%
and NDSI>0.4
Pixel is >50% snow covered
33. 33 Example: vegetation near Hudson Bay
34. 34 Vegetation (NDVI) from Landsat image
35. 35 Confluence of Tigris and Euphrates, Iraq
36. 36 MODIS: Snow in northeastern U.S.
37. 37 Data rate
38. 38 Data rates of some sensors
40. 40 MISR: Multi-angle Imaging SpectroRadiometer Launched on Terra, 12/18/1999
Exploits angular information in signal
Surface BRDF
Path lengths through atmosphere
4 spectral bands: blue, green, red, near-infrared
9 angles: 0ş, fore and aft 26.1ş, 45.6ş, 60.0ş, 70.5ş
Global coverage 2-9 days depending on latitude
http://www-misr.jpl.nasa.gov/mission/minst.html
41. 41 MISR: Aerosol optical depth over central/eastern Europe
42. Spectral solar irradiance
43. 43 QuickBird: Commercial imagery at 0.6m resolution panchromatic, 2.44m multispectral
44. NASA’s Earth Observing System (EOS): Idea of standard products Landsat, AVHRR, most earlier missions provide, at best, calibrated radiances at satellite
Interpretation of these radiances to estimate geophysical and biological information requires arcane knowledge and difficult processing
Need to understand relationship between electromagnetic properties of surface of interest and the properties of real interest
Need to account for effects from atmosphere and sensor
Need to deal with sensor geometry to provide information on a map base, so that you can integrate with other spatial information
Therefore, EOS provides information, in addition to data
45. MODIS the canonical (but not only) example http://modis.gsfc.nasa.gov/data/dataprod/index.php
Each has a nontechnical description, information about the data, and an “ATBD” (algorithm theoretical basis document)
Levels of processing
Calibrated radiances and geolocation information
Geophysical products
Mapped to a projection
46. MODIS Leaf Area Index
47. MODIS FPAR�(Fraction of absorbed Photosynthetically Active Radiation)�
48. 48 MODIS ocean chlorophyll, Indian Ocean
