2. Natural Resources Canada Ressources naturelles Canada Canadian Space Agency Agence spatiale canadienne Power Point Presentation adapted by Claude Brun del Re

3. Geomatics for Educators

4. Geomatics Term originally created in Canada Geomatics is the science and technology of gathering, analyzing, interpreting, distributing and using geographic information. Geomatics encompasses a broad range of disciplines that can be brought together to create a detailed but understandable picture of the physical world and our place in it. These disciplines include: –Mapping and Surveying –Geographic Information Systems (GIS) –Global Positioning System (GPS) –Remote Sensing

5. Canada’s Role in Geomatics Canada exports ~ $300 million worth of geomatics products and services. Growth rate of 15 to 20 per cent per year. Demand for GIS products and services is expected to exceed $10 billion per year. Geomatics is one of the fastest-growing technology sectors and Canada is a recognized leader, both in its development and in the provision of Geomatics software, hardware and value-added services. Natural Resources Canada - –Geomatics Canada Canada Centre for Remote Sensing Centre for Topographic Information Aeronautical Charts & Technical Services Legal Surveys & International Boundary Commission Geodetic Survey

7. List examples of remote sensing technology in your every day life Satellite weather maps Ultrasounds Speed radar Sonar (for ships, bats or dolphin) Photos CAT scans x-rays

8. REMOTE SENSING Definition and Process Target Sensor Platforms Electromagnetic Energy Interpretation RADARSAT

9. Remote Sensing - A Definition Indirect (remote) observations (sensing) Remote sensing is the science (and to some extent, art) of acquiring image data and deriving information about the Earth’s surface without actually being in contact with it. Remote sensing will give information about an object called a target

10. Who could give me two common sensors? Our eyesA camera

11. How does remote sensing work? Far away from the target, on what we call a platform. Here are some types of platform Satellite Space shuttle Aircraft Balloon Ground base tower

12. Remote Sensing Process Energy Source or Illumination (A) Radiation and the Atmosphere (B) Interaction with the Target or Surface (C) Recording of Energy by the Sensor (D) Transmission, Reception, and Processing (E) Interpretation and Analysis (F) Application (G)

13. Passive Sensor Passive sensors detect or “sense” reflected solar radiation What does a passive sensor need to sense the earth?

14. Active Sensors Active sensors produce and receive their own electromagnetic energy They produce their own illumination and they operate in the microwave region

15. Some Atmospheric Interactions Energy will interact with the atmosphere on its way in and out Ozone, nitrogen, CO2 and water vapour affect incoming energy Energy affected if wavelength is < or = the particle size Atmospheric windows are wavelengths not affected by the atmosphere

16. Absorption Some substances absorb certain wavelengths of energy UV rays absorbed by ozone LW IR and SW microwaves absorbed by water vapour These wavelengths are not suitable for remote sensing Scattering Occurs when molecules are larger or equal to wavelength Rayleigh scattering - selective scattering (UV, Blue sky) Non-selective - scatters all visible wavelengths (clouds)

17. Atmospheric Windows

18. Terrain Interactions Radiation that reaches the Earth’s surface can be: Absorbed (A); Transmitted (T); and Reflected (R). This will vary with the type of object. The type of interaction will depend on the wavelength of the energy and the material and condition of the feature. Look at different objects, for example an egg, a green apple and a tomato.

19. Diffuse and Specular Reflectors Diffuse Specular rough surfacesmooth surface

21. Electromagnetic Energy Electromagnetic energy is used to illuminate the target in remote sensing Electromagnetic spectrum: Shorter wavelengthLonger wavelength 0.003nm 0.03nm 0.3nm 3nm 30nm 0.3  m 3  m 30  m 300  m 0.3cm 3cm 30cm 3m 30m Gamma Ray X-ray Ultra-Violet Visible Infrared Microwave Radio

22. Visible Spectrum Visible Wavelegths  Violet: 0.4 - 0.446  m  Blue: 0.446 - 0.500  m  Green: 0.500 - 0.578  m  Yellow: 0.578 - 0.592  m  Orange: 0.592 - 0.620  m  Red: 0.620 - 0.7  m

23. The basic colours of light

24. IR and Microwaves  Reflected IR: 0.72  m to 3.0  m  Thermal IR: 3.0  m to 15  m  Microwaves: 1 mm to 1 m

26. Visible / Infrared (VIR) Colours we perceive are combinations of electromagnetic energy VIR (visible infrared) or optical sensors capture energy reflected by targets in the optical and IR wavelengths Each target reflects or emits these types of energy in different amounts

27. Spectral Response Different objects reflect, absorb and transmit energy in differing amounts An object also transmits, reflects, and absorbs each wavelength differently Spectral responses enable us to identify different objects on images An object’s spectral response may change over time

28. Spectral Response - Leaves Chlorophyll absorbs red and blue Reflects green Greenest in summer Internal leaf structure reflects near IR

29. Bands or Channels Each sensor has a purpose (vegetation, ocean, ice, weather) Certain wavelengths provide more information about certain targets To perform their tasks, sensors on satellites detect energy in very specific, narrow bands or channels of electromagnetic energy

33. Spatial Resolution Fine Resolution Coarse Resolution Fine Resolution Coarse Resolution

34. Swath Total field of view Width of the image in ground distance For satellites, varies between 10s to 100s of kilometres

35. Orbits Geostationary Near-polar sun-synchronous

36. GOES Geostationary Operational Environmental Satellite Operated by NOAA to for weather forecasting and monitoring 5 spectral bands (green-red to infrared) Geostationary above the equator at 75 degs E and W Resolution 1 to 4 kilometres

37. NOAA-AVHRR Advanced Very High Resolution Radiometer Used for meteorology and other applications (vegetation) Sun-synchronous, near-polar orbits (830-870 km above the Earth) Ensure that data for any region of the Earth is no more than six hours old visible, near, mid infrared, & thermal IR 3000 km swath, 1 to 4 km resoloution

38. Landsat Landsat-1 was launched by NASA in 1972 Landsat 7 was launched in 1999 ETM (Enhanced Thematic Mapper) 8 bands VIR and Thermal IR 30 metre resolution 185 kilometre swath width Lots of archived data Near-polar, sun-synchronous orbits - 705 km

39. SPOT Système Pour l’Observation de la Terre French commercial satellites SPOT 1 -1986 SPOT -2 operational, SPOT-4 just launched Sun-synchronous, near-polar orbits at altitudes around 830 km 2 Sensors MLA and PLA PLA - black and white MLA - 3 visible bands (blue-green-red) 60 to 80 km swath 10 to 20 m resolution

40. RADARSAT-1 Canada’s first earth observation satellite Launched November 4, 1995 Monitoring the Arctic (ice) is its main role Unique, flexible, “steerable” sensor Many swath width choices Many incidence angles available

41. RADARSAT-1 Repeat Cycle - 24 days - 14 orbits per day Coverage - Global: 4,5 days - North America: 3 days - Arctic: daily Altitude - 798 km Orbit Geometry - Circular, Near polar - Sun-synchronous Inclination - 98.6° (from the equator) -Passes to the right of the North Pole Period - 100.7 Minutes

42. New Small Sats 1 to 5 metre resolution All commercially built IKONOS Earlybird QuickBird

44. RADAR RADAR is an acronym for RAdio Detection And Ranging A microwave (radio) signal is transmitted towards the target The sensor detects the reflected (or backscattered) portion of the signal

45. RADAR Images Radar images “look” like black and white photographs Tones of gray correspond to the amount of radar energy that is returned to the sensor The stronger the backscatter or the more energy that is returned to the sensor, the lighter that area or object will appear on the final image

46. RADAR Reflection There are three general types of reflection: specular diffuse corner calm

47. Advantages Own energy source (images anytime of day) “Sees” through clouds (images anywhere) Provides good view of topography Sensitive to surface roughness Provides information on moisture content

48. Disadvantages Side-looking geometry creates distortions Radar speckle Excessive loss of data in mountainous areas due to shadows

49. Radar Sensors SEASAT - NASA 1978 –lasted only a few months ERS-1 - ESA 1991-95 –30 metre resolution ERS-2 - ESA 1994 –30 metre resolution JERS-1 - Japan 1992 –18 metre resolution

51. What is an Image? Image is a visual view of the energy reflected by the target Satellite images are digital: they are made up of numbers usually from 0 to 255 where 0 is black and 255 is white The numbers (radiance value) are arranged in rows and columns Each square is called a PIXEL A number or a value of reflected energy is stored for each pixel

52. Raster Data Images are stored as raster data - grid of cells or pixels Each pixel represents a certain amount of ground like 10 m x 10 m Each pixel is representative of the amount of energy backscattered by the target

53. Pixels and Lines Upper left corner is the origin X values are pixels or columns y values are lines or rows

54. Pixels and Lines PixelsLines X= Pixel 2 and Line 2 ( 2, 2) X

55. Bits and Bytes Bits are binary digits (0 or 1) Images are collected as 8, 16, 32 bit data Bit refers to the number of exponential levels a binary digit is taken to –single bit = 2 1 –8 bit = 2 8 or 256 levels of grey –16 bit = 2 16 or 65536 levels of grey

56. Image File Formats.pix = PCI or Eoscape.img = ERDAS Imagine.lan = ERDAS GeoTIFF.tiff = contains georeferencing info TIF = requires header file for georeferencing.bil,,bsq, raw = flat raster, common format, needs header file jpeg = common image format for the WWW, no georeferencing information GRID = ESRI raster format

57. VIR Images Usually 3 bands loaded One band loaded alone appears as a greyscale Each assigned a colour gun (Blue, green, red) Together, 3 bands form colour image