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Electromagnetic Radiation and Remote Sensing

Electromagnetic Radiation and Remote Sensing. Remote Sensing Definition. Remote Sensing --Making measurements from a distance. Passive remote sensing makes measurements of naturally-occurring radiation at a distance from the objects being observed.

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Electromagnetic Radiation and Remote Sensing

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  1. Electromagnetic RadiationandRemote Sensing

  2. Remote Sensing Definition • Remote Sensing--Making measurements from a distance. • Passive remote sensing makes measurements of naturally-occurring radiation at a distance from the objects being observed. • Active remote sensing sends out pulses of electromagnetic radiation and measures radiation that bounces back to the sensor from the object.

  3. Satellite vs. Radar Remote Sensing • Weather satellites generally make passive radiation measurements at a distance from the earth and atmosphere. • Weather radars make active radiation measurements of precipitation suspended in the air.

  4. Advantages of Remote Sensing • Remote sensing from satellites and weather radars provides several advantages over conventional (surface and radiosonde) observations: • Data over oceans and other areas not well covered by conventional obs. • Data between conventional observation stations, even in well covered areas. • More frequent observations.

  5. Fundamentals of Electromagnetic (EM) Radiation

  6. Radiation--Transfer of energy through space by electromagnetic waves. • Electromagnetic waves are up and down fluctuations in the energy levels of electromagnetic fields.

  7. Characteristics of EM Radiation • All substances with a temperature above absolute zero emit electromagnetic (EM) radiation. • [Exception is so-called dark matter which has been theorized to provide the unobserved mass needed to account for observed motions of astrophysical bodies such as galaxies • “Dark matter” does not emit radiation, so we cannot detect it directly, only by its gravitational effect]. • EM radiation travels at the speed of light (co = 2.99792458 x 108 m s-1 in a vacuum, slightly slower in air).

  8. EM Radiation can be characterized by: • 1. Wavelength ( ): distance measured from wave crest to wave crest.

  9. Units of Wavelength • Measured in different distance units depending on the type of radiation. • Infrared (IR) usually given in micrometers. • 1 micrometer = 10-6 m = 1/1,000,000 m • Microwave often given in centimeters, e.g. NEXRAD is a 10 cm radar.

  10. 2. Frequency • frequency ( f )--no. wavecrests passing a certain point over a given period of time. Wavelength is related to frequency  by where c is the speed of light. • Usually given in some multiple of Hertz (Hz) which are cycles per second. • Note: Wavelength is inversely proportional to frequency--longer wavelength radiation has lower frequency; shorter wavelength radiation has higher frequency.

  11. 3. Amplitude • amplitude--magnitude of the wave, i.e., maximum displacement from the "zero" energy level to the peak energy level; it is a measure of the intensity (i.e. the strength) of the electromagnetic radiation.

  12. [4. Wavenumber] • An additional way of characterizing EM radiation is the wavenumber. • It is the number of wavecrests per unit distance. • Often given in units of cm-1, i.e, no. of wavecrests per centimeter.

  13. Electromagnetic Spectrum • EM Spectrum--all the different wavelengths of observed radiation from very short to very long.

  14. The shorter the wavelength of the radiation, the higher is its energy level "per wave".  Thus X-Rays carry much more energy than microwaves, for example. • Visible light is the portion of the spectrum of wavelengths from 0.4-0.7 micrometers. • Ultraviolet (UV) radiation is at wavelengths from 0.1 -0.4 micrometers. • Near Infrared (IR) is 0.7-4.0 micrometers. • IR is roughly 4.0-1000 micrometers. • For weather satellites we we will be mainly concerned with the visible and IR portions of the spectrum up to about 20 micrometers. For weather radar we will be concerned with the microwave part of the spectrum at wavelengths 3-10 cm.

  15. Radiation Concepts and Definitions Consider what can happen to a beam of radiation as it traverses a medium or encounters an object.

  16. Radiation Emission • Emission -- Radiant energy emanating from an object. At a given wavelength, we represent emission by where the lambda subscript denotes a single wavelength.

  17. Absorption • Removal of radiant energy from a beam incident on an object and conversion into internal energy (heat) of the absorbing object, where is the absorptivity, or fractional amount of the incident radiation that is absorbed.

  18. Scattering • Continuous removal of energy from a beam of radiation incident on an object and reradiation of that energy in all directions.

  19. Reflection ( ) • Reflection (backscattering) occurs with that portion of an incident beam of radiation that is turned back rather than continuing in a forward direction, where is the reflectivity or fractional amount of the incident radiation that is reflected.

  20. Transmission • That portion of a radiation beam that is neither absorbed nor scattered and continues unimpeded through a translucent medium, where is the transmissivity or fractional amount of the incident radiation that is transmitted.

  21. Total amount of beam must be accounted for, i.e., sum of fractional amounts =1 or 100% of incident beam.

  22. Albedo • Ratio of the total reflected to total incoming solar radiation averaged across all the solar wavelengths

  23. Blackbody • An object that absorbs and emits the maximum possible radiation at its given temperature across all wavelength bands.  • It is a theoretical concept, but does not actually occur in nature.  However, the radiative behavior of  many objects approaches that of a blackbody.  • For example, the sun emits radiation with nearly 100% efficiency for its temperature.  The earth's surface emits with nearly 100% efficiency for its temperature.

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