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GPS and Remote Sensing

GPS and Remote Sensing. Importance of GPS and RS. GPS and remote sensing imagery are primary GIS data sources, and are very important GIS data sources. GPS data creates points (positions), polylines, or polygons for GIS Remote sensing imagery are used as major basis map in GIS

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GPS and Remote Sensing

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  1. GPS and Remote Sensing

  2. Importance of GPS and RS • GPS and remote sensing imagery are primary GIS data sources, and are very important GIS data sources. • GPS data creates points (positions), polylines, or polygons for GIS • Remote sensing imagery are used as major basis map in GIS • Information digitized or classified from imagery are important GIS layers and datasets

  3. Globe Positioning System (GPS) • GPS is a Satellite Navigation System • GPS is funded and controlled by the U. S. Department of Defense (DOD). While there are many thousands of civil users of GPS world-wide, the system was designed for and is operated by the U. S. military. • GPS provides specially coded satellite signals that can be processed in a GPS receiver, enabling the receiver to compute position, velocity and time. • At least 4 satellites are used to estimate 4 quantities: position in 3-D (X, Y, Z) and GPSing time (T) 20,000 km http://maic.jmu.edu/sic/glossary.htm#Projection

  4. Space Segment • The nominal GPS Operational Constellation consists of 24 satellites that orbit the earth. There are often more than 24 operational satellites as new ones are launched to replace older satellites. The satellite orbits repeat almost the same ground track (as the earth turns beneath them) once each day. The orbit altitude is such that the satellites repeat the same track and configuration over any point approximately each 24 hours (4 minutes earlier each day). There are six orbital planes, with nominally four SVs (Satellite Vehicles) in each, equally spaced (60 degrees apart), and inclined at about fifty-five degrees with respect to the equatorial plane. This constellation provides the user with between five and eight SVs visible from any point on the earth.

  5. 55°

  6. Control Segment • The Master Control facility is located at Schriever Air Force Base (formerly Falcon AFB) in Colorado. These monitor stations measure signals from the SVs which are incorporated into orbital models for each satellites. The models compute precise orbital data (ephemeris) and SV clock corrections for each satellite. The Master Control station uploads ephemeris and clock data to the SVs. The SVs then send subsets of the orbital ephemeris data to GPS receivers over radio signals.

  7. User Segment • The GPS User Segment consists of the GPS receivers and the user community. GPS receivers convert SV signals into position, velocity, and time estimates. GPS receivers are used for navigation, positioning, time dissemination, and other research.

  8. Coordinate system and height • GPS use the WGS 84 as datum • Various coordinate systems are available for chosen • GPS height (h) refers to WGS84 ellipsoid surface, so it is a little difference from the real topographic height (H), which refers to the geoid surface, the approximate Mean Sea Level. Some newer GPS units now provide the H by using the equation H=h-N (N from a globally defined geoid, or Geoid99) H: topographic height or orthometric height h: ellipsoid height N: geoid height H = h - N http://www.esri.com/news/arcuser/0703/geoid1of3.html

  9. GPS positioning services specified in the Federal Radionavigation Plan • PPS (precise positioning service) for US and Allied military, US government and civil users. Accuracy: - 22 m Horizontal accuracy - 27.7 m vertical accuracy - 200 nanosecond time (UTC) accuracy • SPS (standard positioning service) for civil users worldwide without charge or restrictions: - 100 m Horizontal accuracy - 156 m vertical accuracy - 340 nanosecond time (UTC) accuracy • DGPS (differential GPS techniques) correct bias errors at one location with measured bias errors at a known position. A reference receiver, or base station, computes corrections for each satellite signal. - Differential Code GPS (navigation): 1-10 m accuracy - Differential Carrier GPS (survey):1 mm to 1 cm accuracy

  10. DGPS • The idea behind differential GPS: We have one receiver measure the timing errors and then provide correction information to the other receivers that are roving around. That way virtually all errors can be eliminated from the system • Because if two receivers are fairly close to each other, say within a few hundred kilometers, the signals that reach both of them will have traveled through virtually the same slice of atmosphere, and so will have virtually the same errors • http://www.trimble.com/gps/dgps-how.shtml • real time transmission DGPS or post-processing DGPS • reference stations established by The United States Coast Guard and other international agencies often transmit error correction information on the radio beacons that are already in place for radio direction finding (usually in the 300kHz range). Anyone in the area can receive these corrections and radically improve the accuracy of their GPS measurements. Many new GPS receivers are being designed to accept corrections, and some are even equipped with built-in radio receivers. • http://www.trimble.com/gps/dgps-where.shtml • if you don't need precise positioning immediately (real time). Your recorded data can be merged with corrections recorded at a reference receiver (through internet) for a later clean-up. • http://www.nps.gov/gis/gps/gps4gis/postprocess.html • http://www.fs.fed.us/database/gps/cbsalpha.htm

  11. http://www.trimble.com/gps/dgps-how.shtml

  12. http://www.geoplane.com/gpsneeds.html

  13. Project tasks can often be categorized by required accuracies which will determine equipment cost.

  14. Remote Sensing Basics • Using electromagnetic spectrum to image the land, ocean, and atmosphere. http://imagers.gsfc.nasa.gov/ems/waves3.html When you listen to the radio, or cook dinner in a microwave oven, you are using electromagnetic waves. When you take a photo, you are actually doing remote sensing

  15. Remote sensing platforms

  16. Passive: source of energy is either the Sun or Earth/atmosphere Sun - wavelengths: 0.4-5 µm Earth or its atmosphere - wavelengths: 3 µm -30 cm Active: source of energy is part of the remote sensor system Radar - wavelengths: mm-m Lidar - wavelengths: UV, Visible, and near infrared Types of remote sensing Camera takes photo as example, no flash and flash

  17. Passive Remote Sensing Active Remote Sensing E. transmission, reception, and pre-processing F. processing, interpretation and analysis G. analysis and application A. the Sun: energy source C. target D. sensor: receiving and/or energy source

  18. NASA ResearchSpacecraft

  19. Busy Traffic Data acquisition

  20. The greatest canyon on Mars: Valles Marineris

  21. Four types of resolution • Spatial resolution • Spectral resolution • Radiometric resolution • Temporal resolution

  22. Spatial resolution and coverage • Spatial resolution • Instantaneous field-of-view (IFOV) • Pixel: smallest unit of an image • Pixel size • Spatial coverage • Field of view (FOV), or • Area of coverage, such as MODIS: 2300km or global coverage, weather radar (NEXRAD): a circle with 230 km as radius

  23. 1 meter, spatial resolution UTSA campus, red polygon is the Science Building 30 meter, spatial resolution Northwest San Antonio

  24. Spatial Resolution Jensen, 2000

  25. Spectral resolution (Dl ) and coverage (lmin to lmax) • Spectral resolution describes the ability of a sensor to define fine wavelength intervals • The finer the spectral resolution, the narrower the wavelength range for a particular channel or band

  26. Radiometric resolution and coverage • Sensor’s sensitivity to the magnitude of the electromagnetic energy, • Sensor’s ability to discriminate very slight differences in (reflected or emitted) energy, • The finer the radiometric resolution of a sensor, the more sensitive it is to detecting small differences in energy

  27. Comparing a 2-bit image with an 8-bit image

  28. Temporal resolution and coverage • Temporal resolution is the revisit period, and is the length of time for a satellite to complete one entire orbit cycle, i.e. start and back to the exact same area at the same viewing angle. For example, Landsat needs 16 days, MODIS needs one day, NEXRAD needs 6 minutes for rain mode and 10 minutes for clear sky mode. • Temporal coverage is the time period of sensor from starting to ending. For example, • MODIS/Terra: 2/24/2000 through present • Landsat 5: 1/3/1984 through present • ICESat: 2/20/2003 to 10/11/2009

  29. Remote Sensing Raster (Matrix) Data Format Y axis Jensen, 2000

  30. Soil moisture Surface temperture and albedo ET Rainfall Snow and Ice Water quality Vegetation cover Land use Image processing and modeling The size of a cell we call image resolution, depending on… Such as 1 m, 30 m, 1 km, or 4 km Image processing and modeling

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