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Fundamentals of Remote Sensing. The Interaction of Electromagnetic Radiation with Matter. Electromagnetic Radiation (EMR). “Light” Can originate from the sun (passive remote sensing) or from a man-made instrument (active remote sensing) Can behave like a particle or a wave
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Fundamentals of Remote Sensing The Interaction of Electromagnetic Radiation with Matter
Electromagnetic Radiation (EMR) • “Light” • Can originate from the sun (passive remote sensing) or from a man-made instrument (active remote sensing) • Can behave like a particle or a wave • Is a form of energy • Interacts with materials in unique ways
Interesting fact: • Light reaching the earth now was generated in the core of the sun ~100,000 years ago. It takes that long for the photons to work their way out to the sun’s surface and zoom off to earth at c = 298,000,000 m/s (takes about 8.5 minutes).
Remote Sensing Uses EMR!So…you need to understand: • Basic physics of EMR • Units used to describe EMR • Divisions of EMR spectrum • Behavior of EMR interacting with the atmosphere and other materials
All objects warmer than absolute zero emit EMR • Most objects reflect EMR emitted by other objects • Key basis of remote sensing because objects of interest interact in unique ways with EMR
How do we describe EMR? • Wavelength • Frequency • Energy λ (lamda) ν (nu)
Wavelength Units (Length!) • Meters (m) • Centimeters (cm) • Millimeters (mm) • Micrometers (µm) • Nanometers (nm) • Angstroms (Ǻ)
Frequency • The number of waves that pass through an imaginary plane in a specific amount of time (e.g., 1 second)
Frequency Units (A Rate!) • Hertz (Hz) (1 Hz = 1 cycle/sec) • Kilohertz (KHz) • Megahertz (MHz) • Gigahertz (GHz) • Etc.
c = wavelength x frequency (λν) c = 3 x 108 m/sec (the speed of light) = 186,000 miles/sec Velocity of Light (c)
Energy (Q) Q = h * ν Q = Energy of a quantum (joules) h = Planck’s constant (6.626 * 10-34 J s/cycle) ν= Frequency So… Energy is proportional to frequency Energy is inversely proportional to wavelength
Frequency-Wavelength-Energy Web Demo – Electromagnetic Waves
Visible Light • Wavelengths that dominate radiation given off by the sun • Most animals evolved to “see” these wavelengths • Captured by your digital camera
Additive Primaries (Color Theory) (Add together in different proportions to make all other colors) Red + Blue = Magenta Red + Green = Yellow Blue + Green = Cyan Red + Blue + Green = White
Why is Color Theory Important? • Your computer screen uses the 3 additive primaries to display all possible colors • To interpret remotely sensed imagery you must be able to interpret color
Infrared Radiation Near Infrared (NIR) 720 – 1300 nm Mid Infrared (MIR) 1300 – 3000 nm Far Infrared (FIR, aka thermal) > 3000 nm Thermal (far) IR images of Pacific Ocean
Other parts of the Spectrum UV Radar
Atmospheric Effects • Absorption • Scattering • The atmosphere affects sunlight coming to the ground and reflected light going back to the satellite.
Absorption Ozone Hole Thermal IR – Greenhouse Effect
Clouds! • Most EMR wavelengths can’t penetrate clouds • Big problem in remotely sensed imagery—tropics especially • Temporal compositing to get rid of clouds • Cloud shadows a problem too
Riverton Landsat Image July 15 1999 Cloudy!
Reflectance • Definition: The amount of reflected radiation divided by that amount of incoming radiation in a particular wavelength % Reflectance = 100*reflected/irradiance
Reflectance Spectra • Understanding reflectance spectra is fundamental to using remote sensing • Reflectance spectra are graphs of reflectance vs. wavelength.
Summary • All of this is important because it determines in part how objects of interest interact with EMR. The better we understand these interactions, the better we are at using the remote sensing tool!
