Remote Sensing PDF

Summary

This document presents an overview of electromagnetic radiation, its interaction with the atmosphere and objects. It also discusses different types of remote sensing, including passive and active methods, with a focus on the principles and applications of various sensors.

Full Transcript

Fig. 2

Electromagnetic remote sensing of earth
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 REMOTE SENSING
(LIGHT SOURCES, LIGHT INTERACTION WITH
ATMOSPHERE & OBJECTS, SPECTRAL
SIGNATURE & SENSORS)
ELECTRO MAGNETIC RADIATION
ELECTROMAGNETIC RADIATION:
❖ Two diff. models – Wave model & Particle Model
1. WAVE MODEL:
❖ James Clark Maxwell in 1860 conceptualized that EMR or electromagnetic
radiation as wave that travels in the space at the speed of light (299792.46 km/s)
❖ EM wave consists – 2 fluctuating fields – Electric & Magnetic
❖ 2 fields are perpendicular to each other and also perpendicular to the direction of
propagation
❖ Both have same amplitudes (strength) – reach their maxima & minima at the
same time.
❖ EMR can transmit through space & generated wherever electric charge is
accelerated
❖ 2 imp. Characteristics – Wavelength & Frequency
WAVELENGTH – length of one complete wave cycle, measured as the distance
between 2 successive crests/troughs
❖ Represented by λ, & measured by meters/Km/cm/micrometer etc.
 Electromagnetic wave, E-Electrical Component, M-Magnetic
Component
E

Crest
E

C
Velocity of Light
M
M
Trough

ν = Frequency
(No. of cycles passing per second of a fixed point

Electromagnetic wave (comprising both magnetic and electric
fields at 90° to each other)
FREQUENCY – No. of cycles a wave passing a fixed point per unit
time
❖ Represented by ν, & measured by Hertz/KHz/MHz/GHz etc.
❖ A wave completing one cycle per second is having a frequency of 1
Hz.
Relationship between wavelength & frequency:
λ = c/ν
❖ Frequency is inversely proportional to wavelength
❖ Longer the wavelength, lower the frequency

λ
Longer wavelength

Shorter frequency

Longer frequency

λ
Shorter wavelength
PARTICLE MODEL –
❖ Light is a stream of particles called ‘PHOTONS’ – similar to
subatomic particles like neutrons.
❖ Quantum theory applicable to this type of motion describes that
light is transferred in discrete pockets called ‘quanta’ or ‘photons’.
❖ Photons – physical form of quantum, subatomic massless particles -
basic particle for EM force.
❖ Comprise radiation emitted by the matter when it is excited
thermally.
❖ Energy in photons - represented in terms of electron volts
❖ Rate of energy from one place to another – Flux & measured by
‘Watts’
❖ Amount of energy by a photon is determined by Plank’s equation:
Q=hν
❖ Q – energy measured in watts
❖ h – Plank’s constant (6.6260×10-34 J)
 Light: Dual Wave & Particle nature

❖ We have, λ = c/ν = hc / hν = hc / Q
i. e., Q = hc / λ
❖ Quantum energy is inversely proportional to its wavelength

❖ Photons with shorter wavelengths (at higher frequency) – more
energetic)
ELECTROMANGETIC SPECTRUM

The electromagnetic spectrum is the range of
frequencies of electromagnetic radiation and their
respective wavelengths and photon energies.
 Electromagnetic Spectrum – Useful
Wavelength Bands

❖ Visible range - Blue - 0.4 - 0.5 m
Green - 0.5 – 0.6 m
Red - 0.6 – 0.7 m

❖ Infrared (IR) Near IR (NIR) 0.7 – 1.3 m
Mid IR 1.3 – 3.0 m
Thermal IR - beyond 3 m to 14 m

❖ Micro wave 1 mm – 1 m

❖ Earth's atmosphere absorbs energy in  rays, x rays and
ultraviolet bands – hence, not used in Remote Sensing 12
Electromagnetic Radiation
Ultraviolet Radiation - 0.4 micrometers
❖ Not much RS activities are done with UV since these
shorter wavelengths are easily scattered by the
atmosphere
Electromagnetic Radiation

Visible Radiation
❖ BLUE (.4-.5 micrometers)

❖ GREEN (.5-.6 micrometers)

❖ RED (.6-.73 micrometers)
Electromagnetic Radiation
Infrared Radiation - 0.72 - 15 micrometers
1. Near Infrared - reflected, can be recorded on film
2. Mid Infrared - reflected, can be detected using electro-optical
sensors.
3. Thermal Infrared - emitted, can only be detected using
electro-optical sensors
Electromagnetic Radiation

Microwave Radiation - radar sensors, wavelengths range from
1mm to 1m
❖ Sun – main source of EMR for remote sensing.
❖ However, all matter at temperature above absolute zero (0 K or - 273C) emits
EMR.
❖ Amount of energy emitted from an object is a function of temperature of the
object;
M=  t4 (Boltzmann Law)

where M= total energy from the surface of a matter
watts m-2
 = Stefan – Boltzmann Constant
5.669710-8 W m-2 W M-2 K-4
T= absolute temperature (K) of the emitting material

This law is expressed for an energy source that behaves as a blackbody.

Blackbody is a hypothetical, ideal radiator that totally absorbs and re-emits all
energy incident on it.
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Spectral distribution of energy radiated from black bodies at
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various temperatures
Dominant Wavelength
LIGHT INTERACTION WITH
THE ATMOSPHERE
Atmosphere has profound effect mainly on:
❖the intensity
❖ the spectral composition of radiation available to sensors

Net effect of Atmosphere varies with
❖ differences in path length
❖ magnitude of energy signal being sensed
❖ the atmospheric conditions present
❖ wave lengths involved

Atmospheric modification of incoming and outgoing EM
radiation includes scattering, refraction and absorption

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Absorption
❖ Caused primarily by three atmospheric gases: ozone, carbon
dioxide and water vapour
❖ Process by which radiant energy is absorbed and converted into
other forms of energy.
❖ May take place at atmosphere & by the targets
❖ An absorption band is a range of wavelengths in which radiant
energy is absorbed by the particles
❖ Atmosphere can close down RS activity in these bands due to
cumulative effect of these wavelengths.
no attenuation attenuation
❖ Thus, atmospheric gases absorb EMR in different specific regions
of the spectrum
❖ They influence where in the spectrum we can ‘look’ for RS
purpose.
❖ Those areas in the spectrum which are not severely affected by
absorption & useful for RS activities – ATMOSPHERIC
WINDOWS.
❖ These regions are less affected by absorption & nearly transparent.
Atmospheric transmittance and atmospheric windows (Note that wave
length scale is logarithmic.)
Scattering
- Unpredictable, diffusion of radiation by particles in
the atmosphere
- Depends on relative size of particles and the radiation
wavelength

Adverse effects in remote sensing
- Reduces image contrast
- Changes spectral signature of ground objects as
seen by sensor

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Rayleigh scattering
- Atmosphere molecules and particle size 8 
❖ diffuse reflection – (Lambertian)
❖ reflection is scattered and equal in all direction (uniform)
❖ - contains information on the colour of reflecting surface
In remote sensing “diffuse reflectance” properties of terrain
are measured
❖ energy is reflected equally in all directions
❖ many natural surfaces act as a diffuse reflector to some
extent.

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Specular vs diffuse reflectance

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 CONCEPT OF SPECTRAL SIGNATURE

Reflectance characteristics of earth surface features are quantified by
measuring the portion of the incident energy that is reflected

Energy of wave length () reflected
Spectral reflectance = -------------------------------------------- x 100
Energy of wave length () incident

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SPECTRAL REFLECTANCE CURVES

❖ These curves show the relationship between EM spectrum with
the associated % reflectance for any given material.
❖ Plotted as a chart that represents wavelength on horizontal axis &
percent reflectance on the vertical axis.
❖ Spectral reflectance - responsible for color or tone in visible
band
❖ Signatures are not deterministic , but statistical in nature
Spectral Signatures
 SPECTRAL SIGNATURES
❖ Signal received by sensor depends on land cover

50

50
50 Spectral Signature

% Reflectance
unique to healthy
vegetation
0
0 Water
Bare Earth

0.4.6.8 1.0 1.2 1.4

Green - Highest reflectance
hence we see green trees
SPECTRAL REFLECTANCE OF VEGETATION:

Visible band 0.4 m - 0.7 m
❖ At wave length bands 0.45 m and 0.67 m chlorophyll in plant absorbs
energy
❖ Human eye perceive healthy vegetation as green
Infrared band – 0.7 m to 1.3 m
❖ 40 to 50 % energy reflects – Rest is transmitted , absorption is minimal
(5%)
❖ Reflectance is mainly due to the internal structure of the plant leaves.
Hence discrimination among the species is possible in this band.
❖ Beyond Infrared band –1.3 m, Energy absorbed or reflected, but no
transmission
❖ Dips at 1.4 m, 1.9 m and 2.7 m – because of water presence in the
leaf absorbs energy
❖ Reflectance is inversely proportional to the total water present
Typical vegetation reflectance spetrum
Soil
❖ Less peak and valley variations in reflectance
❖ Factors effecting soil reflectance
- moisture content
- soil texture (sand, silt and clay)
- surface roughness
- presence of iron oxide
- organic matter content

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Water:

❖ Little reflectance in only blue and green wave band.
❖ Presence of turbidity increase the reflectance
❖ Absorbs most of the radiation in the near IR
❖ Middle infrared region - helps in delimiting even small
water bodies.
❖ Dissolved gases and many inorganic salts do not
manifest any change in the spectral response of
water.

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Comparison of reflectance spectra of a few land covers
❖ Spatial effects
- same type of features have different characteristics
at different geographic location at given point of
time
- identified by - shape, size & texture of objects

❖ Temporal effects
– changes in reflectivity or emissivity of a feature over
time
- helps in the study of changes in the growing cycle of
a crop

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Polarization
– refers to the changes in polarization of radiation
reflected or emitted by an object
- helps to distinguish the objects – useful in
microwave remote sensing

50
 Wayanad Floods-2024

Source: NRSC
SENSORS
Sensors – Mounted on the platform – capture the reflected
energy from the objects

Classification 1. Based on the type of illumination:
Two types - Active or passive sensors
❖ Passive: sensors measure the amount of energy reflected from the
earth’s surface
❖ Active: sensor emits radiation in the direction of the target, it then
detects and measures the radiation that is reflected or
backscattered from the target.
❖ Most systems rely on the sun to generate all the EM energy
needed to image terrestrial surfaces - passive sensors.
❖ Other sensors generate their own energy, called active sensors,
transmits that energy in a certain direction and records the portion
reflected back by features within the signal path.
 Active Remote Sensing

❖ Transmit their own signal and
measure the energy that is
reflected or scattered back from
the target
❖ Advantages: ability to “see”
regardless of time of day or
season; use wavelengths not part
of solar spectrum; better control
of the way target is illuminated
Ex. of active RS - Satellite Radar Altimetry
❖ Satellite radar altimeters work on the principle of active remote
sensing.
❖ Transmit very 'sharp' electromagnetic pulses of a predetermined
wavelength and frequency (a typical radar altimeter operates at
13.5 GHz)
❖ The satellite's altitude (i.e. absolute height above the surface) is
obtained by measuring the time required for the pulse to travel
from the altimeter antenna to the earth's surface and back to the
satellite's receiver.
 Passive Remote Sensing

❖ Measure natural radiation emitted by target or/and radiation
energy from other sources reflected from the target
❖ examples: passive microwave radiometers, LandSat, SPOT
Examples of Passive Sensors:
❖ Advanced Very High Resolution Radiometer (AVHRR)
Sea Surface Temperature
❖ Sea-viewing Wide Field-of-View Sensor (SeaWiFS) Ocean
Color
Classification 2. Based upon the process of
scanning:
whiskbroom scanner:
❖visible / NIR / MIR / TIR
❖point sensor using rotating mirror,
build up image as mirror scans
❖Landsat MSS, TM
Pushbroom scanner:
❖mainly visible / NIR
❖array of sensing elements (line)
simultaneously, build up line by line
❖SPOT (Satellite Pour l’Observation de
la Terre)
Classification 3. Based upon the EMR range:
1. Optical Sensors:
❖ Sensors that operate in the optical portion of spectrum,
which extends from approximately 0.3 to 14 mm.
❖ Can do more with these data because \.
❖ look at differences in colors
❖ look at differences over time
❖ Applications: meteorological, ocean monitoring (i.e.
chlorophyll absorption).
Optical Sensors
❖ show how much energy from the sun was being reflected or
emitted off the Earth's surface when the image was taken.
❖ Clear water reflects little radiation, so it looks black.
❖ Pavement and bare ground reflect a lot of radiation, so they
look bright.
❖ Urban areas usually look light blue-grey.
❖ Vegetation absorbs visible light but reflects infrared, so it
looks red
2. Microwave Sensors
❖ sensors that operate in the microwave portion of the spectrum
❖ advantages: capable of penetrating atmosphere under virtually
all conditions, different view of the environment.
❖ disadvantage: Radar instruments have a hard time identifying
water bodies because the wavelength is much longer than the
general character of the surface roughness
❖ applications: sea ice and snow, geologic features, ocean
bottom contours, other planets.
Satellite orbits
 Characteristics of Satellite Orbits
1. Orbital period

2. Altitude

3. Apogee and perigee

4. Inclination

5. Nadir, zenith and ground track

6. Swath

7. Side lap and overlap
 Orbital Period

Time taken by a satellite to complete one revolution around the earth

Spatial and temporal coverage of the imagery depends on the
orbital period

It varies from around 100 minutes to 24 hours
 Altitude

The height of the satellite in a orbit from the point directly beneath it on

the surface of the earth

Low altitude ( altitude < 2000 km)

Moderate altitude

High altitude (altitude ~36000 km)
 Apogee and Perigee
Apogee: The point at which the satellite is at the farthest distance
from the earth in an orbit is defined as the apogee.

Perigee: The point at which the satellite is at the closest distance
from the earth in an orbit is defined as the perigee.
 Inclination
Inclination of an orbit is its deviation from the equator measured in
the clockwise direction.

This is usually 99 degrees for remote sensing satellites.
 Nadir, Zenith and Ground Track
Nadir
– It is the point on the earth’s surface where the
imaginary radial line between the center of the
earth and the satellite meet.
 Nadir, Zenith and Ground Track
Zenith: It is the point directly opposite to the
nadir point above the satellite
Ground Track: The projection of a satellites
orbit on the earth’s surface.
 Swath
The width of the area on the earth’s surface
which has been ‘sensed’ by a satellite during a
single pass.
 Overlap
Areas of the earth’s surface which are
common in two consecutive images along the
flight path.
 Sidelap
Overlapping areas in the images of the earth’s
surface on two adjacent flight paths.
Sensors in Indian remote sensing satellites
❖ Linear Self-scanning Sensors (LISS) – for multi spectral
scanning. This scanner has four generations – LISS-I, LISS-II,
LISS-III, & LISS-IV.
❖ Panchromatic (PAN) sensors to collect data in single Band
❖ Wide Field Sensors (WiFS) – to collect data in a wide swath with
two bands
❖ Advanced Wide Field Sensors (AWiFS) - to collect data in a wide
swath with four bands
❖ Ocean Color Monitor (OCM) – Operating in 8 narrow spectral
bands for oceanographic applications
❖ Multispectral Optoelectronic Scanner (MOS) – in 3 & 19 bands
for oceanographic applications
❖ Multi-frequency Scanning Microwave Radiometer (MSMR) – for
passive RS in 4 different frequencies
❖ Synthetic Aperture Radar (SAR) for active microwave RS
 PAN

LISS III

WiFS

IRS 1C Sensors overview
 Sun Synchronous Orbits

Earth observation satellites usually follow the sun synchronous
orbits.
A sun synchronous orbit is a near polar orbit whose altitude is
such that the satellite will always pass over a location at a given
latitude at the same local solar time. In this way, the same solar
illumination condition (except for seasonal variation) can be
achieved for the images of a given location taken by the satellite.
POLAR ORBITING SATELLITES

❖ Polar-orbiting satellites are those in which the position of the
satellite’s orbital plane is kept constant relative to the sun.
❖ Landsat satellite series, IRS Series
 Geostationary Orbit (appr.36.000 km)

❖ Geostationary orbiting satellites are those that remain stationary
relative to a point on the surface of the earth
❖ Communications and meteorological satellites
Satellite Remote Sensors: TYPES OF ORBITS
Sun-synchronous polar orbits
❖Circle the planet in a roughly north-south ellipse while the earth
revolves beneath them - a particular place is imaged
❖Global coverage, fixed crossing, repeat sampling
❖Typical altitude 500-1,500 km
Ex: Terra/Aqua, Landsat

Non-Sun-synchronous orbits
❖Tropics, mid-latitudes, or high latitude coverage, varying sampling
❖Typical altitude 200-2,000 km
Ex: TRMM, ICESat

Geostationary orbits
❖Regional coverage, continuous sampling
❖Over low-middle latitudes, altitude 35,000 km
Ex: GOES, INSAT
Thank you
Optical image of Montreal area during ice storm of 1998. Ice
snow and clouds appear as various colors of white, vegetation
is green.