earthobservation.wordpress.com

Dirty REMOTE SENSING earthobservation.wordpress.com Stuart Green Teagasc Stuart.Green@Teagasc.ie 1

Purpose Give you a very basic skill set and software training so you can: find free satellite image data. process and analyse the data. produce a classified habitat map. use RS in the field map flooding 10-11pm Lecture 11-12.30pm Practical 2

8 weeks Week 1- Introduction & and how to find images Week 2- How to interpret Images Week 3- How to assess & process images before use Week 4- How to classify an image Week 5 Classification part 2 Week 6 RS and field work Week 7 how to map flooding Week 6 Map production and validation 3

Software ArcGIS both free, download and use on your own computer https://engineering.purdue.edu/~biehl/multispec/ http://www.esri.com/software/arcgis/explorer Other free remote sensing software GRASS SAGA GIS InterImage ESA BEAM ESA STEP http://step.esa.int/main/download/ 4

Basically we will look at how the images we see on google earth are made and how we can convert them from a web-toy to serious pieces of analytical kit. Remember this Remote sensing technology is a multi billion industry that supports trillions of spending from agriculture to the military, from real estate to mining. 5

6 http://googlesightseeing.com/

Remote Sensing is What? The science of telling something about an object without touching it 7

It s the use of images taken from above, to tell us about the world. We are all used to these images now Google earth is a great example but also weather forecasting Evelyn Cussak et al show us satellite pictures every day http://gisgeography.com/100-earthremote-sensing-applications-uses/ 8

Satellite Images Drones Laser Scanning (LIDAR) RADAR satellite images 9

What benefits does RS bring Wide overview Complete access Repeatability A different perspective http://staff.aub.edu.lb/~webeco/rs%20lectures.htm 10

High Resolution Imagery 11

What benefits does RS bring Wide overview Complete access Repeatability A different perspective http://staff.aub.edu.lb/~webeco/rs%20lectures.htm 12

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What benefits does RS bring Wide overview Complete access Repeatability & timeliness A different perspective http://staff.aub.edu.lb/~webeco/rs%20lectures.htm 14

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What benefits does RS bring Wide overview Complete access Repeatability & timeliness A different perspective http://staff.aub.edu.lb/~webeco/rs%20lectures.htm 16

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In short A new perspective Information that s not available in other ways A synoptic view The data is directly useable in GIS mapping systems 18

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Remote sensing is used routinely in these areas Agronometrics Environmental resource mapping Policy monitoring/evaluation Landuse issues Pollution control Hazard mapping Disaster reflief Policy development Planning 21

Some examples from my lab, some of which we ll see in more detail later A hedgerow map from aerial photography Maps of landcover from satellites Measuring grass growth from satellites Identifying High Nature Value Farms with GIS&RS Measuring economic impact of environmental legislation on farming using GIS Measuring 3D biomass with laser scanners Phenology from multi-temporal low res satellites 22

https://earthobservation.wordpress.com/201 5/11/04/remote-sensing-uplands-mountains/ 23

The Physics of Light 24

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We will look at different remote sensing technologies over the coming weeks but, for now, just image all we will be doing for the next few lectures is looking at photographs! But how are photographs, either film or digital, formed? 26

Taking a Picture from Space 27

We Rely upon Electromagnetic Energy We are all familiar with EMR (even if we don t realise it!) Light, radio, microwaves are all EMR and part of the Electromagnetic Spectrum 28

The spectrum 29

Properties of EMR EMR can be thought of as little packets, or quanta, or Energy called Photons Or as energy propagating as a wave 30

Psst..dont mention this to any physics heads but.. You can chose to think of light as either model: The machine gun model: Image the sun (or a laser pointer or a lamp) firing out little packets of energy that shoot through the sky and bounce of, or through or are scattered by objects Or The radio model: Imagine the sun broadcasting waves of energy like a radio antenna that reflect, or transmit or are diffracted by objects In both cases the amount of energy is determined by the wavelength of the light involved and we can only see stuff because some of that energy is bounced or reflected of an object into our eyes (or our camera or our satellite imaging device) 31

All Electromagnetic radiation (EMR) travels at the speed of light C=l.n C speed measured in meters per second n frequency measured in Hertz λ wavelength measured in meters 1 E E is energy, measured in Joules and λ is wavelength measured in meters E=n.h E is energy, measured in Joules and h is Planks constant 32

Wave length is measured in nanometers nm Blue light has a wave length of Green Red ~450nm ~550nm ~700nm 33

What happens when a photon meets an object? Absorption (A) occurs when radiation (energy) is absorbed into the target while transmission (T) occurs when radiation passes through a target. Reflection (R) occurs when radiation "bounces" off the target and is redirected. In remote sensing, we are most interested in measuring the radiation reflected from targets. 34

Spectral Properties of Objects Everything in nature has it s own unique distribution of reflected, emitted and absorbed radiation. These spectral characteristics can if ingeniously exploited- be used to distinguish one thing from another or to obtain information about shape, size, and other physical and chemical properties (Parker and Wolf, 1965, p21). Colour! 35

Color as Light (Spectral Color) The Electromagnetic spectrum consists of the spectral hues of light. Hue is the specific color, identified by a name, (e.g., red, blue, green, etc.) as they are the component wavelengths of white light.when combined together in equal amounts, they form white light. Color as Light is translucent, that is, we can see through the colors and can project colors over one another to form other colors 36

Reflected Color Most surfaces are opaque (not transparent). These surfaces absorb and reflect different amounts of color from white light. Most of the colored objects we see on earth are made up of combinations of reflected wavelengths. Surfaces or objects illuminated by white light absorb differing proportions of visible wavelengths and reflect the remainder. 37

Bet you didn t realise you d be doing quantum mechanics Before we go any further we need to mention that these processes are generally quantised (not always so in the case of scattering). What this means is that the processes occur a fixed discrete energy levels. In the macro world we live in filling a jug with water is a non-quantised process. If you need to fill a litre jug, then you can poor 100ml, then 50 then 600 and then the rest in order to fill the jug or if you have a 2l Jug you can poor half in to fill your 1l jug. In a quantised world you can only fill a 1l jug with water from another 1 l jug in one go you can t use small amounts to make up the total and you can t use just some of a bigger amount. 38

KEY CONCEPTS OF REMOTE SENSING. Spectral Differentiation. Remote sensing depends on observed spectral differences in the energy reflected or emitted from features of interest. Radiometric Differentiation. Remote sensing also depends on the ability to determine differences in the brightness of objects and features.. Spatial Differentiation. Every sensor is limited in respect to the size of the smallest area that can be separately recorded as an entity on an image. Geometric Transformation. Remote sensing does not immediately produce images with accurate, consistent geometric relationships between points on the ground and their corresponding representations on the image. Role of the Atmosphere. All energy reaching the remote sensing instrument must pass through a portion of the earth s atmosphere. In doing so, the sun s energy is altered in intensity and wavelength by particles and gases in the earth s atmosphere. These changes appear on the image in ways that degrade image quality or influence the accuracy of interpretations. 39

What Is A Digital Image? DigitalPixel Number (DN) 70 53 41 64 84 85 81 88 91 87 77 45 38 59 77 84 86 85 85 80 82 69 44 32 45 72 86 82 78 88 86 87 65 40 41 75 78 93 86 93 106 106 84 56 43 58 75 104 104 100 101 95 91 83 51 39 56 105 110 97 88 84 85 87 77 59 44 96 103 89 75 77 74 72 87 93 97 90 82 76 70 67 61 71 81 88 97 93 85 78 74 70 72 81 75 78 85 94 97 92 84 80 72 What your What computer you see sees Digital numbers (DNs) typically range from 0 to 255; 0 to 511; 0 to 1023, etc. These ranges are binary scales: 28=256; 29=512; 210=1024. 40

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rows (y) What Is A Digital Image? 70 53 41 64 84 85 81 88 91 87 70 77 53 45 41 38 64 59 84 77 85 84 81 86 88 85 91 85 87 80 82 77 70 69 45 53 44 38 41 32 59 64 45 77 84 72 84 85 86 86 81 82 85 88 78 85 91 87 88 80 82 86 69 77 87 44 45 65 32 38 40 45 59 41 72 77 75 86 84 82 86 78 78 85 85 93 88 86 80 93 86 82 106 87 69 106 65 44 84 40 32 56 41 45 43 75 72 58 86 75 78 82 78 104 93 104 86 88 100 93 101 106 86 95 106 87 91 84 65 83 56 40 51 43 41 39 58 75 56 75 78 105 104 110 104 93 97 100 86 88 101 93 84 95 106 85 91 106 87 83 84 77 51 56 59 39 43 44 56 58 75 96 105 103 110 104 89 97 104 88 100 84 101 75 85 95 77 87 91 77 83 74 59 51 72 44 39 56 87 96 93 103 105 97 89 110 90 97 82 88 76 75 84 70 77 85 67 87 61 74 77 71 72 59 44 87 81 93 96 88 97 103 97 90 89 93 82 85 76 78 70 75 74 67 77 70 61 72 71 74 72 81 75 81 87 78 88 93 85 97 97 94 93 90 97 85 82 92 78 76 84 74 70 80 70 67 72 72 61 71 81 75 78 81 85 88 94 97 97 93 92 85 84 78 80 74 72 70 72 81 75 78 85 94 97 92 84 80 72 columns (x) 42

Greyscale vs. RGB Greyscale is typically used to display a single band while RGB ( Red, Green, Blue ) images can display 3 bands, corresponding to the red, green and blue phosphors on a monitor. Computer monitor colors are additive, meaning true red + green + blue = white. 43

Data Visualization A digital number in a satellite image has no intrinsic visual display meaning to the computer. Based on some predefined algorithm, the computer adjusts the brightness on the screenas a function of the pixel value. This function can take a wide range of forms. Typically, lower pixel values are displayed as dark and higher pixel values are displayed as bright. Important to remember: while there is no limit to the number of image bands, there is a limit to the number a monitor can display at once. 44

Finding sources of satellite information https://earth.esa.int/web/guest/data-access http://www.resmap.com/imagery.aspx http://glovis.usgs.gov/ http://landsatlook.usgs.gov/viewer.html https://earthdata.nasa.gov/labs/worldview/ http://www.gis4biologists.info/free_satellite_images.htm http://earthexplorer.usgs.gov/ http://www.nesdis.noaa.gov/imagery_data.html 45

http://www.flashearth.com/ http://earthexplorer.usgs.gov/ http://glovis.usgs.gov/ http://reverb.echo.nasa.gov/reverb/#utf8= %E2%9C%93&spatial_map=satellite&spat ial_type=rectangle https://earthdata.nasa.gov/labs/worldview/ 46

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Practical Find the Lat/Long of your place of birth (POB) Go to the GLOVIS satellite web site Find a Landsat 8 image for your area, and ADD scene to list. Click send to cart then register for an account Process your scene- you will get an email confirming your image is ready for download. Select the Natural look image and download. Examine the image 49

https://earthobservation.wordpress.com/20 15/12/18/my-first-experiences-withsentinel-2a-data/ 50