Remote Sensing Geodesy What is remote sensing History

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Remote Sensing & Geodesy

Remote Sensing & Geodesy

 • What is remote sensing? • History of satellite remote sensing • Satellite

• What is remote sensing? • History of satellite remote sensing • Satellite orbits • Geophysical Examples: Multispectral, GPS, Radar/INSAR, Satellite Gravity • Geodesy

What is Remote Sensing? … the science of deriving information about Earth's land water

What is Remote Sensing? … the science of deriving information about Earth's land water areas from images acquired at a distance

http: //rst. gsfc. nasa. gov/ • Starting in 1946, captured V-2 rockets were launched

http: //rst. gsfc. nasa. gov/ • Starting in 1946, captured V-2 rockets were launched to > 100 km by the U. S. Army • Launch 13 in the V-2 series contained a motion picture camera in its nose cone, which acquired a series of views of the Earth's surface as it proceeded to a 134 km altitude.

The Soviet Union surprised the world when it launched Sputnik, the world's first satellite,

The Soviet Union surprised the world when it launched Sputnik, the world's first satellite, on October 4, 1957. The U. S. quickly followed suit: Explorer I, was launched into Earth orbit on Jan. 31, 1958 and discovered the Van Allen radiation belts (above, right). In the 1960’s spy planes and satellites were common (e. g. , right: Cuban missile crisis).

Landsat • The first Landsat satellite was launched in 1972; the most recent, Landsat

Landsat • The first Landsat satellite was launched in 1972; the most recent, Landsat 7, was launched on April 15, 1999. • Images are archived at Landsat receiving stations and used for global change research and applications in agriculture, geology, forestry, regional planning, education and national security. http: //geo. arc. nasa. gov/sge/landsat/ S. F. Bay Area

Satellite Orbits Geostationary Kepler’s 3 rd Law T 2 = A r 3 M

Satellite Orbits Geostationary Kepler’s 3 rd Law T 2 = A r 3 M A = 5. 92 x 1011 s 2 kg/m 3 • Communications satellites use a geostationary orbit, in which the satellite is always in the same position (above the equator) with respect to the rotating Earth. • Geostationary orbits are high altitude (35700 km)

Satellite Orbits Polar Kepler’s 3 rd Law T 2 = A r 3 M

Satellite Orbits Polar Kepler’s 3 rd Law T 2 = A r 3 M A = 5. 92 x 1011 s 2 kg/m 3 • Many remote-sensing satellites use a polar orbit to provide a more global view of Earth • These satellites operate in a sunsynchronous orbit at an altitude of 700 to 800 km.

Multispectral Imaging Systems • MSI systems are passive devices that measure electromagnetic waves (e.

Multispectral Imaging Systems • MSI systems are passive devices that measure electromagnetic waves (e. g. light, infrared) at different wavelengths, then combine the results • Example: Landsat Thematic Mapper (TM) images are produced using 7 different spectral bands http: //www. classzone. com/books/earth_science/terc/content/investigations/esu 101 page 07. cfm

Multispectral Imaging Systems http: //www. classzone. com/books/earth_science/terc/content/investigations/esu 101 page 07. cfm

Multispectral Imaging Systems http: //www. classzone. com/books/earth_science/terc/content/investigations/esu 101 page 07. cfm

Global Positioning System • The Global Positioning System is a network of 24 satellites

Global Positioning System • The Global Positioning System is a network of 24 satellites placed into orbit by the U. S. Department of Defense. • The satellites circle the earth twice a day in a very precise orbit and transmit information to earth.

Global Positioning System • A GPS location is pinpointed using triangulation from 3 or

Global Positioning System • A GPS location is pinpointed using triangulation from 3 or more satellites. • Today, GPS is used extensively for navigation and geodetic studies. http: //pasadena. wr. usgs. gov/office/hudnut/scec/97 _SCEC_E_summary. html

Satellite Radar Systems • Radar satellites (e. g. , ERS 2, Radarsat) are active

Satellite Radar Systems • Radar satellites (e. g. , ERS 2, Radarsat) are active systems that reflect radar beams from Earth’s surface. • Radar waves can pass through clouds and so provide more continuous coverage of the surface

Satellite Radar Systems • Since the satellite orbits approximately repeat, radar images of the

Satellite Radar Systems • Since the satellite orbits approximately repeat, radar images of the same region can be compared (radar interferometry) • Interferometric synthetic aperture radar (In. SAR) techniques are used to study dynamic systems (e. g. , Indian earthquake on right) http: //www. gfz-potsdam. de/ pb 1/pg 5/research/methods/insar_uk. html

Satellite Gravity Systems • CHAMP (CHAllenging Minisatellite Payload), launched July 15, 2000, is a

Satellite Gravity Systems • CHAMP (CHAllenging Minisatellite Payload), launched July 15, 2000, is a German small satellite mission that measures Earth’s gravity using precise GPS orbital data

Satellite Gravity Systems • The Gravity Recovery and Climate Experiment (GRACE) March 2002 mission

Satellite Gravity Systems • The Gravity Recovery and Climate Experiment (GRACE) March 2002 mission detects changes in Earth’s gravity field by monitoring the distance between the two satellites • The trailing spacecraft is actually about 220 kilometers behind the lead spacecraft.

Satellite Gravity Data • New data from satellite gravity missions is being used for

Satellite Gravity Data • New data from satellite gravity missions is being used for plate tectonic research • Note improvement in the resolution of gravity anomalies in Tonga trench region http: //www. csr. utexas. edu/grace/gravity/solid_earth. html

http: //www. gfz-potsdam. de/pb 1/op/champ/

http: //www. gfz-potsdam. de/pb 1/op/champ/

Geodesy: Study of Earth’s shape The Earth is not quite a perfect sphere This

Geodesy: Study of Earth’s shape The Earth is not quite a perfect sphere This shape is called the reference ellipsoid (RE) RE has the shape of a drop of ideal fluid rotating at same velocity as Earth! http: //earth. leeds. ac. uk/dynamicearth/internal/shape. htm

Geodesy: Study of Earth’s shape Geoid: The hypothetical Earth surface that coincides with sea

Geodesy: Study of Earth’s shape Geoid: The hypothetical Earth surface that coincides with sea level everywhere. Usually, the Reference Ellipsoid is used for a datum. Large-scale Geoid anomalies reflect the mass distribution in Earth’s mantle.

100 m Geoid low in the Indian ocean 70 m Geoid high in the

100 m Geoid low in the Indian ocean 70 m Geoid high in the SW Pacific Geoid