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1 Lecture 17 Ocean Remote Sensing 9 December 2008
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2 Final Exam Friday – December 19 1:30-3:30 2/3 from lectures 12-17, 1/3 from previous lectures (focusing on topic areas covered in the first 2 exams)
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3 Office Hours Not available this afternoon – Office hours on Thurs, Dec 11 Can meet Thurs/Fri, Dec 11/12 by appointment Not available Mon-Thurs, Dec 15-19
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4 Ocean Chlorophyll/Production SAR Ocean Observations
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5 Lecture Topics 1.Geographic perspectives on importance of oceanic processes 2.SAR Ocean Observations 3.Global SST data products 4.Sea surface topography 5.Monitoring El Nino with satellite data 6.Monitoring ocean productivity
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6 Geographic perspectives on importance of oceanic processes Influences of oceans on continental climates Large-scale oceanic circulation
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8 http://orbit-net.nesdis.noaa.gov/arad/gpcp/colormaps.html
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11 Geographic perspectives on importance of oceanic processes Influences of oceans on continental climates Large-scale oceanic circulation
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13 1.Ocean current drivers 2.Ocean current modifiers –Continents –Coriolis effect
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16 Thermocline
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17 Currents are also influenced by the rotation of the earth This rotation causes a natural deflection of currents Clockwise in the Northern Hemisphere Counter clockwise in the Southern Hemisphere This is called the coriolis effect
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18 Lecture Topics 1.Geographic perspectives on importance of oceanic processes 2.SAR Ocean Applications 3.Global SST data products 4.Sea surface topography 5.Monitoring El Nino with satellite data 6.Monitoring ocean productivity
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19 Microwave backscatter from water surfaces results from Bragg Scattering from small surface waves – Many processes alter the Bragg wavelength, and thus cause changes in EM energy detected by SARs
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20 SAR Ocean Applications Detection of oil slicks Monitoring surface gravity waves Monitoring internal waves Detection of bottom features
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21 Airborne SAR Imagery of Oil Spills Oil on water surface dampens formation of short wavelength Bragg Waves
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22 Seasat SAR (L-band) image of an oil spill U.S. Coast Guard deploys airborne SAR systems for detection of oil spills in coastal waters
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23 Tilt and hydrodynamic modulation by gravity waves
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24 Airborne SAR imagery of gravity waves
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25 Monochromatic light Monochromatic light is diffracted as it passes through a narrow slit Degree of diffraction ~ 1 / slot width
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26 SAR Image of gravity waves digital
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27 SAR Image of gravity waves In a fourier transform, the distance between the peaks of energy is proportional to the wavelength of the imaged gravity waves, and a line connecting the peaks represents the direction of the waves
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29 Seasat SAR image of gravity waves
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30 Internal Wave Formation
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31 Internal Wave Formation
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32 Surface Hydrodynamic Modulation by Internal Waves
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33 Internal Waves
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34 Airborne SAR Images of Internal Waves
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35 ERS C-VV SAR image collected off of west African Coast
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36 ERS C-VV SAR image collected off of Galopagos Islands showing internal waves
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37 Seasat SAR Image of Natucket Shoals
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39 Hydrodynamic Modulation by Bottom Feature/Current Interactions
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42 Hydrodynamic Modulation Current slows downCurrent speeds up
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43 Current Direction
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44 Lecture Topics 1.Geographic perspectives on importance of oceanic processes 2.SAR Ocean Applications 3.Global SST data products 4.Sea surface topography 5.Monitoring El Nino with satellite data 6.Monitoring ocean productivity
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45 Figure 4 in Njoku and Brown, Sea Surface Temperature, pages 237-249
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47 Global Sea Surface Temperature Products Data are compiled over a weekly or monthly period Algorithms to remove cloud-contaminated pixels are applied to data Average SST for the remaining pixels are calculated Data are resampled to a coarse resolution (e.g, 36 km) Data are interpolated to fill in missing pixels http://www.osdpd.noaa.gov/PSB/EPS/SST/ al_climo_mon.html
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49 AVHRR Sea Surface Temperature Map
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50 MODIS Sea Surface Temperature Map
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51 SST Map SST Anomaly Map
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53 Lecture Topics 1.Geographic perspectives on importance of oceanic processes 2.SAR Ocean Applications 3.Estimating Sea Surface Temperature (SST) with AVHRR 4.Global SST data products 5.Sea surface topography 6.Monitoring El Nino with satellite data 7.Monitoring ocean productivity
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54 Altimeters Altimeters measure round-trip travel time of microwave radar pulse to determine distance to sea surface! From this (and additional info) we can determine the dynamic sea surface topography
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55 Spaceborne Scatterometer Resolution = 50 km Obtains measurements looking upwind, cross- wind, and downwind Empirical Algorithms used to estimate wind speed and direction
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57 Lecture Topics 1.Geographic perspectives on importance of oceanic processes 2.SAR Ocean Applications 3.Global SST data products 4.Sea surface topography 5.Monitoring El Nino with satellite data 6.Monitoring ocean productivity
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58 Thermocline
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59 Thermocline
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60 Movies of SST and Elevation Anomalies
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61 Lecture Topics 1.Geographic perspectives on importance of oceanic processes 2.SAR Ocean Applications 3.Estimating Sea Surface Temperature (SST) with AVHRR 4.Global SST data products 5.Sea surface topography 6.Monitoring El Nino with satellite data 7.Monitoring ocean productivity
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62 SeaWiFs Launched 1997 2800 km swath 1.1 x 1.1 km pixel
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63 Example SeaWifs Chlorophyll Algorithms Chl = 10 (a + bR) Algorithm 1 - R = log (R443/R550) Algorithm 2 – R = log [(R520 + R565)/R490]
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67 Data obtained from ORBIMAGE at: http://seawifs.gsfc.nasa.gov/cgibrs/seawifs_ browse.pl?dy=11627&tp=MO&lev=2&hp=
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68 Monthly Composite
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