Satellite basics Estelle de Coning South African Weather Service

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Presentation transcript:

Satellite basics Estelle de Coning South African Weather Service Most slides taken from EUMETSAT training events, Jochen Kerkmann

CONTENT 1. Introduction 2. Satellite orbits 3. Meteorological satellites 4. The EM spectrum 5. Satellite Image Interpretation VIS, IR, WV, 3.9 – 10.8 6. Summary

1. INTRODUCTION Remote sensing is the science and art of acquiring information about an object, area or phenomena without actually being in contact with it. The sensor is usually mounted on moving platforms such as balloons, aircraft and satellites

1. INTRODUCTION (cont) Platforms of remote sensing are: Land based (surface or ground observation) Airborne based (from 100 m to 40 km) Space based (from 150 km to 36000 km)

2. SATELLITE ORBITS GEO LEO Located along the equatorial plane. About 36000 km above the earth Has Geo-synchronous orbit Period of 1436 minutes Good coverage from remote areas Has wide field of view ~ 50 degrees Has low resolution Provides continuous data ~ 15-30 min. Not very suitable for vertical soundings Near polar orbiting 800 -900 km above the earth Has Sun-synchronous orbit Period of 101 minutes Excellent coverage at the poles Has relatively narrow field of view Has high resolution Passes vary with latitude Very suitable for vertical soundings

2. SATELLITE ORBITS (cont) GEO satellites

2. SATELLITE ORBITS (cont)

3. METEOROLOGICAL SATELLITES Many types of satellites have been launched for various purposes. For monitoring the environment, there are three types namely the: Meteorological (weather) satellites Earth Resource satellites (ERS) Research and Development satellites (R&D).

4. THE EM SPECTRUM AND RESOLUTION The Electromagnetic (EM) spectrum is defined as a spectrum of all types of EM radiation in which each type of radiation is ordered according to its wavelength

Electromagnetic Spectrum The electromagnetic spectrum is a representation of the continuum of wavelengths, from long radio waves to the short x-rays and gamma rays. Note that the portion of the electromagnetic spectrum we can detect with our eyes (the visible portion) constitutes a very small portion of the electromagnetic spectrum. The microwave region (1mm-30cm) is also important in remote sensing of atmospheric temperature and moisture, as well as surface properties.

4. THE EM SPECTRUM (cont) In the visible portion features are observed by virtue of reflected solar energy In the infrared portion, sensing of emitted energy predominates Remote sensing data acquisition of surface features is limited to the non-blocked spectral regions of the EM referred to as atmospheric windows Atmospheric windows define wavelength ranges in which the atmosphere is particularly transmissive of energy

7 MSG Window Channels Window Band (um) Airmass Band (um) VIS 0.6 0.56 - 0.71 WV 6.2 5.35 - 7.15 VIS 0.8 0.74 - 0.88 WV 7.3 6.85 - 7.85 NIR 1.6 1.50 - 1.78 IR 9.7 9.38 - 9.94 MIR 3.9 3.40 - 4.20 IR 13.4 12.40 - 14.40 IR 8.7 8.30 - 9.10 IR 10.8 9.80 - 11.80 High Res VIS IR 12.0 11.00 - 13.00 HRV 0.4 - 1.1 3 km data sampling intervals, except HRV (1 km) Images each 15 minutes (5 minutes Met-8 rapid scan) 20/04/2017

4. THE EM SPECTRUM (cont) The atmospheric constituents like gases, aerosols and water vapour are selective absorbers of radiation depending on their wavelength, pressure and temperature In a clear atmosphere gas molecules such as carbon dioxide absorb radiation in selective wavebands creating a complicated pattern of atmospheric absorption bands An absorption band is defined as a range of wavelengths in the EM spectrum within which radiation is absorbed by a substance

4. THE EM SPECTRUM (cont) NON-ATMOSPHERIC WINDOWS Around 4.3 m, carbon-dioxide Around 6.7 m, water vapour Around 9.7 m, ozone Around 15 m, carbon-dioxide Around 5 mm, oxygen

So much for very basic background information… Let us look at more practical examples of how to use satellite images…

5. Satellite image interpretation 5.1 VIS 5.2 IR 5.3 WV 5.4 NIR

MSG SEVIRI CHANNELS

5.1 VIS IMAGES Low clouds are less bright since they do not have large amount of ice. Their droplets contain more water that absorbs VIS rather than reflect High clouds consist of more ice crystals than water and are very bright Clouds physical properties of high albedo are: large depth, high cloud water (ice) content, small average cloud-droplet size Cloud physical properties of low albedo are: shallow depth, low cloud water (ice) content, large average cloud-droplet size VIS imagery shows shadows and helps to identify cloud structure when sun is at an angle.

Channel 02 (VIS0.8): Optical Thickness Thick Cb Cloud Thin Cirrus Anvil Maputo Thin Cirrus Anvil MSG-1, 6 November 2004, 12:00 UTC, Channel 02 (VIS0.8) Range: 0 % (black) to 100 % (white), Gamma = 1.0

5.2 IR IMAGES IR imagery indicates the Temperature of the radiating surface. Low cloud and fog can not be observed at night since their temperature is similar or near to that of surface. During the day such low clouds are detectable with VIS. Special properties of 3.9 micron radiation help in detecting low clouds at night

Channel 09 (IR10.8): Top Temperature Warm Tops Maputo Cold Tops MSG-1, 6 November 2004, 12:00 UTC, Channel 09i (IR10.8i) Range: +50°C (black) to -70°C (white), Gamma = 1.0

Channel 09 (IR10.8): Top Temperature Warm Tops Maputo Coldest Tops Cold Tops MSG-1, 6 November 2004, 12:00 UTC, Channel 09 (IR10.8)

5.3 WV IMAGES (cont) Regions with high upper trop. Humidity appear white or light(cold) and regions with low humidity appears warm(dark) For moist atmosphere most WV radiation comes from middle layers. Very little moisture from lower layers is detected on the WV radiation. It is good tracer of atmospheric motions Cold and humid Warm and dry

Channel 05 (WV6.2): Upper Level Moisture High UTH Maputo Low UTH MSG-1, 6 November 2004, 12:00 UTC, Channel 05i (WV6.2i) Range: -20°C (black) to -70°C (white), Gamma = 1.0

Channel 06 (WV7.3): Mid Level Moisture Maputo MSG-1, 6 November 2004, 12:00 UTC, Channel 06i (WV7.3i) Range: +10°C (black) to -70°C (white), Gamma = 1.0

MSG Channel Differences Useful to Monitor Convection

Difference IR3.9 - IR10.8: Cloud Particle Size Maputo Large Ice Particles (+26/+35 K) Small Ice Particles (+65/+73 K) MSG-1, 6 November 2004, 12:00 UTC, Difference IR3.9 - IR10.8 Range: -5 K (black) to +70 K (white), Gamma = 0.5

6. Summary VIS good for day time usage HRV to see fine-scale details IR108 good for vertical extent of clouds (Cloud top temp) WV6.2: shows high level moisture WV7.3 shows mid-level moisture (early convection) IR3.9 - IR10.8 best for particle size