The document provides an overview of remote sensing including:
1) Defining remote sensing as acquiring information about Earth's surface without physical contact using sensors to detect reflected or emitted energy.
2) Describing the basic components and processes of remote sensing including emission, transmission, interaction with the surface, and sensor data acquisition.
3) Detailing the interaction of electromagnetic radiation with Earth's surfaces and the information that can be derived from changes in magnitude, direction, wavelength and other properties.
4) Explaining the different types of remote sensing platforms, sensors, resolutions and wavelengths used in remote sensing from visible light to microwaves.
5) Providing an overview of Indian remote sensing satellites
On National Teacher Day, meet the 2024-25 Kenan Fellows
Iirs lecure notes for Remote sensing –An Overview of Decision Maker
1. CONTENT
S. No. Topics Faculty Page No.
1. Overview of Remote Sensing Ms. Shefali Agarwal 1
2. Terrain Analysis Ms. Shefali Agarwal 15
3. Geographic Information System Mr. P.L. N. Raju 27
4. Fundamental Concepts of GPS Mr. P. L. N. Raju 38
5. Geo informatics for Natural Dr. P.S. Roy 69
Resources Management Dean, IIRS
6. Applications in Agriculture and Soils Dr. S.K. Saha 104
7. Applications in Forest Management Dr. S. P.S. Kushwaha 117
8. Applications in Geosciences Dr. P.K. Champtiray 128
9. Applications in Human Settlement Dr. B.S. Sokhi 139
Studies and Management
10. Applications in Marine Sciences Dr. D. Mitra 143
11. Applications in Water Resources Dr. S.P. Aggarwal 154
2. 1
OVERVIEW OF REMOTE SENSING
Shefali Agrawal
Photogrammetry and Remote Sensing Division
1. Introduction
In recent times earth observation from aerospace media has gained significant
importance due to ever increasing demand for most authentic, timely and uniform
information of earth surface features and processes involved. Due to rapid development
and changing life style, the impact on environment and its effect on surface processes
and features have under gone sea change. The impact of development on the
environment is significant as the rapidly growing population; urbanization and other
development efforts have exerted tremendous pressure on natural resources and have
caused their depletion and degradation. Biodiversity is declining at an unprecedented
rate - as much as a thousand times what it would be without the impact of human
activity. Half of the tropical rainforests have already been lost. Land degradation affects
as much as two thirds of the world's agricultural land. As a result, agricultural
productivity is declining sharply. The conservation measures are far from satisfactory
and as development processes and interventions still continue, natural resources will be
subjected to greater damage in the future. Hence there is an urgent need to look for
alternative strategies and approaches for better and more efficient management of
natural resources in order to ensure their sustainable use. This is further compounded
by the ever increasing occurrences of natural hazards. Therefore, there is a greater
demand for most authentic timely information on a suit of geophysical parameters and
environmental indicators. Towards this space provides a vantage point where a large
number of sensors have been deployed onboard satellites providing geo spatial
information needed to understand the Earth system as a whole.
1.1. Definition of Remote Sensing
Remote sensing is the science of acquiring information about the Earth's surface
without actually being in contact with it. This is done by sensing and recording reflected
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or emitted energy and processing, analyzing, and applying that information (Lillesand
and Kiefer, 2004).Remote sensing, also called earth observation, refers to obtaining
information about objects or areas at the Earth’s surface by using electromagnetic
radiation (light) without coming in physical contact with the object or area. The basic
process involved in remote sensing is the interaction of the electromagnetic radiation
with the Earth's surface and detection at some altitude above the ground. Remote
Sensing Systems have four basic components to measure and record data about an
area from a distance, Fig1. These components include:
• Emission of electromagnetic radiation (EMR)
• Transmission of energy from the source to the surface of the earth, as well as
absorption and scattering
• Interaction of EMR with the earth's surface: reflection and emission
• Transmission of energy from the surface to the remote sensor
• Sensor data acquisition
• Data transmission, processing and analysis
Fig.1 Remote sensing process
With respect to the type of energy resources, the RS technology is defined as
passive or active, Fig 2. Passive Remote Sensing makes use of sensors that detect the
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reflected or emitted electro-magnetic radiation from natural sources. Active remote
Sensing makes use of sensors that detect reflected responses from objects that are
irradiated by artificially generated energy sources, such as radar.
Fig.2. Passive and active remote sensing
With respect to Wavelength Regions, the RS technology is classified as:
• Visible and reflective infrared RS operating at a range of 0.4μm to 2.5μm.
• Thermal infrared remote sensing operating at a range of 3μm to14μm.
• Microwave remote sensing operating at a range of 1mm to1m.
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‘Optical range’
Cosmic Gamma X- Radio Electric power
U-V Infrared Micro-waves TV
rays rays Rays
Visible spectrum
Ultraviolet Blue Green Red Infrared (IR)
0.3μ m 0.4 0.5μ m 0.6 0.7μ m 10.0 15.0
300nm 500nm 700nm
Wavelength
Fig.3. Electromagnetic spectrum
1.2 Interaction of EMR with the Earth's Surface
Radiation from the sun, when incident upon the earth's surface, is either reflected
by the surface, transmitted into the surface or absorbed and emitted by the surface. The
EMR, on interaction, experiences a number of changes in magnitude, direction,
wavelength, polarization and phase. These changes are detected by the remote sensor
and enable the interpreter to obtain useful information about the object of interest. The
remotely sensed data contain both spatial information (size, shape and orientation) and
spectral information (tone, color and spectral signature).
In the visible and reflective Infrared remote sensing region, the radiation sensed
by the sensor is that due to the sun, reflected by the earth's surface. A graph of the
spectral reflectance of an object as a function of wavelength is called a spectral
reflectance curve. Figure shows the typical spectral reflectance curves for three basic
types of earth feature vegetation, soil, and water in the visible and reflective Infrared
region Fig.4.The band corresponding to the atmospheric window between 8 μm and 14
μm is known as the thermal infrared band. The energy available in this band for remote
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sensing is due to thermal emission from the earth's surface. Both reflection and self-
emission are important in the intermediate band from 3 μm to 5.5 μm.
In the microwave region of the spectrum, the sensor is radar, which is an active
sensor, as it provides its own source of EMR. The EMR produced by the radar is
transmitted to the earth's surface and is reflected (back scattered) from the surface to
be recorded by the radar system again. The microwave region can also be monitored
with passive sensors, called microwave radiometers, which record the radiation emitted
by the terrain in the microwave region.
Fig. 4. Typical spectral reflectance curves for vegetation, soil and water.
In the microwave region of the spectrum, the sensor is radar, which is an active
sensor, as it provides its own source of EMR. The EMR produced by the radar is
transmitted to the earth's surface and is reflected (back scattered) from the surface to
be recorded by the radar system again. The microwave region can also be monitored
with passive sensors, called microwave radiometers, which record the radiation emitted
by the terrain in the microwave region.
1.3 Platforms and Sensors
In order to enable sensors to collect and record energy reflected or emitted from
a target or surface, they must reside on a stable platform away from the target or
surface being observed. As space provides one of the most vantage points for earth
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observation, two prominent orbits are considered for Earth observation: the geo-
stationary orbit and the polar orbit. The geo-stationary orbit is such a position that it
keeps pace with the rotation of the Earth. These platforms are covering the same place
and give continuous near hemispheric coverage over the same area day and night.
These are mainly used for communication and meteorological applications. This geo-
stationary orbit is located at an altitude of 36,000 km above the equator Fig 5.
Fig. 5 Geostationary and near polar orbits
The second important remote sensing orbit is the polar orbit. Satellites in a polar
orbit cycle the Earth from North Pole to South Pole. The polar orbits have an inclination
of approximately 99 degrees with the equator to maintain a sun synchronous overpass
i.e. the satellite passes over all places on earth having the same latitude at the same
local time. This ensures similar illumination conditions when acquiring images over a
particular area over a series of days. The altitude of the polar orbits varies from 600 to
900 km, approximately.
1.4. Resolutions
In general resolution is defined as the ability of an entire remote-sensing system,
including lens antennae, display, exposure, processing, and other factors, to render a
sharply defined image. It depends on large number of factors that can be grouped
under:
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a. Spectral resolution: The spectral band in which the data is collected.
b. Radiometric resolution: It is the capability of the sensor to differentiate two objects
based on the reflectance / emittance differences.
c. Spatial resolution: It is the capability of the sensor to discriminate the smallest
object on the ground. Higher the spatial resolution smaller the object that can be
identified Spatial resolutions vary from few kilometers to half a meter.
d. Temporal resolution: It is the capability to view the same target, under similar
conditions at regular intervals.
Today a large number of earth observation satellites provide imagery that can be
used in various applications.
2. Indian Remote Sensing Satellites
India is one of the major providers of the earth observation data in the world in a
variety of spatial, spectral and temporal resolutions. India has launched several
satellites including earlier generation IRS 1A, IRS 1B, IRS 1C, IRS 1D, IRS P2,IRS P3,
IRS P4 and latest P6 and Cartosat series for different applications, the details of these
are listed in Table 1.
Table 1: Indian Earth Observation Satellites.
Spectral Swath
Satellite No. of Resolution Revisit
Launch Sensors Types Range Width
Name Bands (m) (days)
(µ) (km)
March
Cartosat-1 PAN 1 2.5 m 25
2005
0.52 - 0.59
17th
0.62 - 0.68
IRS-P6 October LISS -III MSl 4 23 140 24
0.77 - 0.86
2003
1.55 - 1.70
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0.52 - 0.59
0.62 - 0.68
AWiFS MSl 4 56 740
0.77 - 0.86
1.55 - 1.70
0.52 - 0.59
0.62 - 0.68
LISS -IV MS 3 5.8 23.9 5
0.77 - 0.86
LISS -IV PAN 1 0.62 - 0.68 5.8 70 5
OCM MS 8 0.4 - 0.885 360 m 1420
IRS-P4 May 26,
6.6,10.65, 120, 80, 2
(Oceansat) 1999 MSMR RADAR 4 1360
18, 21 GHz 40 and 40
0.62-0.68
(red)
WiFS MS 2 189 774 5
0.77-0.86
(NIR)
0.52-0.59
(green)
September
IRS-1D 0.62-0.68
- 1997 3 23 142
(red)
LISS-III MS
0.77-0.86 24-25
(NIR)
1.55-1.70
1 70 148
(SWIR)
PAN PAN 1 0.50-0.75 6 70
0.62-0.68
IRS-1C 1995
(red)
WiFS MS 2 189 810 5
0.77-0.86
(NIR)
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0.52-0.59
(green)
0.62-0.68
3 23.6 142
(red)
LISS-III MS
0.77-0.86 24-25
(NIR)
1.55-1.70
1 70.8 148
(SWIR)
PAN PAN 1 0.50-0.75 5.8 70
450-520
0.52-0.59
LISS-I MS 4 0.62-0.68 72.5 148
IRS-1B 1991 0.77-0.86 22
(NIR)
(same as
LISS-II MS 4 36.25 74
LISS I)
Same as
LISS-I MS 4 72.5 148
above
IRS-1A 1988 22
Same as
LISS-II MS 4 36.25 74
above
3. Global Satellites
Global remote sensing satellites include Landsat, SPOT, ASTER, MODIS, MOS,
JERS, ESR, Radarsat, IKONOS, QuickBird etc (Table 2):
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Table 2: Earth Observation satellites from other countries
Spectral Swath
Satellite No. of Resolution Revisit
Launch Sensors Types Range Width
Name Channels (m) (days)
(µ) (km)
0.43-0.47
(blue)
0.61-
600 x
SPOT -5 May 2002 VMI MS 4 0.68(red) 1000 1
120
0.78-0.89(
NIR) 1.58-
1.75(SWIR)
0.5-0.59
(green)
HRS 0.61-0.68 10
(red) 10
MS 4 60 26
0.79-0.89 10
HRG (NIR) 20
1.58-1.75
(SWIR)
5 m,
combined
to
PAN 1 0.61-0.68 60
generate a
2.5-metre
product.
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10 m
(resampled
1 0.61-0.68 at every 60
PAN
5m along
track)
blue (0.45-
4 2.5 m 17 km
0.52)
green
(0.52-0.6)
MS
QuickBird- Oct. 18, red (0.63-
2 2001 0.69)
NIR.76-
0.89)
PAN 1 0.45-0.9 0.61 m
Dec. 5, 12.5
EROS 1 PAN 1 0.5-0.9 1.8 m 1-4
2000 km
Terra VNIR -
Dec. 18,
(EOS AM- 3 stereo (0.5- 15 m 16
1999
1) 0.9)
ASTER MS 60 km
SWIR (1.6-
6 30 m
2.5)
5 TIR (8-12) 90 m
SWIR, TIR,
CERES MS 3 20 km
Total
360
MISR MS 4 250-275 m
km
MODIS 2 0.4-14.4 250 m 2330
5 500 m km
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29 1000 m
640
MOPITT MS 3 2.3 (CH4) 22 km
km
0.45-0.52
(blue)
0.52-0.60
(green)
IKONOS- September MS 4
IKONOS 0.63-0.69 11
2 24, 1999
(red)
0.76-0.90
(NIR)
PAN 1 1M
Landsat7 16
TM As Landsat 4-5 30x30 185 705 km
15/04/1999 days
Band 6: 10,40 -
60×60
12,50
Panchromatic:
15×15
0,50 - 0,90
NOAA-K May - 1998 AVHRR MS 5 1100
0.5-0.59
VMI MS 4 1000
(green)
0.61-0.68
(red)
March 24, 26
SPOT-4 0.79-0.89
1998 MS 4 20 60
HRV (NIR)
1.58-1.75
(SWIR)
PAN 1 0.61-0.68 10 60
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4. Image Analysis and Interpretation
In order to take advantage of and make good use of remote sensing data, we
must be able to extract meaningful information from the imagery. Interpretation and
analysis of remote sensing imagery involves the identification and/or measurement of
various targets in an image in order to extract useful information about them. Much
interpretation and identification of targets in remote sensing imagery is performed
manually or visually by a human interpreter. It is also possible to apply digital
techniques for image analysis and information extraction.
9. Comparison of RS to Traditional Observations
RS data, with its ability for a synoptic view, repetitive coverage, observations at
different resolutions, provides a better alternative for natural resources management,
environmental monitoring and disaster management as compared to traditional
methods. It provides images of target areas in a fast and cost-efficient manner. While
air photos and fieldwork remain critical sources of information, the cost and time to carry
out these methods often make them unviable and the human ability of observation is
subjective and individual dependant, thereby making it even more unviable. RS
instrumentation makes it possible to observe the environment with EM radiation outside
the visible part of the EM spectrum; the invisible becomes visible. RS is flexible in that
there is a variety of RS observation techniques and a diversity of digital image
processing algorithms for extracting information about the earth's surface. The data can
be easily integrated into a Geographical Information System thus making it even more
effective in terms of solution offering.
6. Future Prospects
In near future large number of new satellites will be launched by India and other
countries with capabilities of providing high spatial, spectral and radiometric resolution
data for variety of applications like water security, disaster management, natural
resource management, food security, infrastructure development etc. The use of
geosynchronous orbit for providing high spatial resolution data will be a major break-
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through to receive bio-geophysical parameters in real time basis. Remote sensing
coupled with geographical information systems where the data can be integrated with
other information, will provide geo-spatial information that is critical for decision making
related to natural resource utilization, environmental monitoring and disaster
management.
References
Lillesand T.M. and Kiefer R. 2004: Remote Sensing and Image Interpretation (Third
Edition). John Wiley, New York.
Web Links
http://www.ccrs.nrcan.gc.ca/ccrs/learn/tutorials/fundam/chapter1/chapter1_2
www.planetary.brown.edu/arc/sensor.html
http://www.ersc.edu/resources/EOSC.html
www.isro.org
www.spaceimage.com
www.eospso.gfc.nasa.gov
www.landsat.org
www.spotimage.fr/home
www.space.gc.ca
www.esa.int/export/esasa/ESADTOMBAMC_earth_O.html
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TERRAIN ANALYSIS
Shefali Agrawal
Photogrammetry and Remote Sensing Division
1. Introduction
Terrain components play an important role in natural resource survey,
environmental monitoring and natural hazards survey and analysis. Terrain features are
the most common features that can be observed from EO systems. Most importantly the
3-D attribute/nature of the terrain can also be mapped and monitored using present
generation of EO systems using stereo viewing capability of Cartosat-1, SPOT ALOS
Prism etc. and InSAR (Interferometric SAR) capability of Envisat and Radarsat. Terrain
features such as elevation, slope, aspect, and curvature influence most of the surface
process including soil erosion, slope failures and vegetation composition. One of the
most important attributes of terrain, topography influences atmospheric, hydrologic and
ecologic processes, such as, microclimate, local wind circulations and precipitation-
runoff processes. Soil formation is also a function of relief, slope and geomorphology.
Topographical features such as drainage basins, stream networks and channels, peaks
and pits, drainage divides (ridges) and valleys play an important role in hydrological
modeling related to flooding, locating areas contributing pollutants to a stream,
estimating the effects of altering the landscape etc. Relief information is also required
for removal of terrain distortions in aerial and satellite images and for creation of
orthorectified image maps. Terrain visualization has also an important place in military
and civil engineering operations. Based on the above application requirements and EO
opportunities, a lot of emphasis is given on extraction of terrain features from using
optical, radar, and Lidar data sets.
2. Digital Elevation Model (DEM)
The most important aspect of the terrain is relief that can be represented as a
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continuous surface in the form of a Digital Elevation Model (DEM). In GIS, DEM is used
to refer specifically to a regular grid of spot heights. It is the simplest and most common
form of digital representation of topography. The term Digital Terrain Model (DTM) may
actually be a more generic term for any digital representation of a topographic surface.
DEM, can be generated from the following basic relief information.
a) Contour lines: Usually elevations on a topographic map are represented as a group
of contour lines with a discrete and constant contour interval.
b) Grid data: For convenience of computer processing, a set of grid data with elevation
are acquired from contour maps, aerial photographs or stereo satellite image data.
Terrain data other than the grid data are interpolated from the surrounding grid data.
c) Random point data: Terrain features are sometimes represented by a group of
randomly located terrain data with three-dimensional coordinates. For computer
processing, random point data are converted to triangulated irregular network (TIN). TIN
has the advantage of easy control of point density according to the terrain feature,
though it has the disadvantage of being time consuming in the random search for the
terrain point.
d) Surface function: Terrain surface can be expressed mathematically as a surface
function, for example, a Spline function
3. Elevation Data Sources
Elevation data can be obtained from the following sources
• Survey data: including ground-based leveling and satellite-based
GPS data;
• Remotely sensed data: including radar altimeter data, laser altimeter
data, optical and SAR stereoscopic image pairs, complex
interferometric SAR data, and shade information in single images;
and
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• Cartographic data: including contours, spot height points and
surface structural lines digitized from paper topographical map
sheets.
Each data source has its own inherent strengths and limitations in terms of the
availability, accuracy, sampling density and pattern, and the ground coverage.
4. Elevation Data Acquisition Techniques
At present a number of techniques are available for acquiring digital elevation
data. The ground survey and aerial photogrammetry represent the traditional elevation
extraction and measurement techniques. Contour-based topographical maps have long
been the primary storage media for terrain information throughout the world. GPS,
satellite image based stereoscopic technique, SAR interferometry, radar altimetry, and
laser altimetry are relatively new techniques for digital elevation acquisition. The advent
of new data capture technologies has increased the acquisition speed of elevation data,
improved the position and height measurements, extended their ground coverage, and
reduced the cost. Ground survey and satellite-based GPS technology tend to generate
very accurate positional and height measurements. Since both ground survey and GPS
techniques require physical visit of ground sampling points, the resulting measurements
are usually sparse. Often, they are utilized as GCPs (Ground Control Points) for
extracting more dense elevation data from stereo photogrammetric and InSAR
techniques or used as checking points for the DEM accuracy assessment.
5. Digitizing Topographic Maps
Due to the relatively low cost and the widest availability, the digitization of
topographical maps represents the practical method for gathering digital elevation data
for a large area, particularly for national and continental scale projects. Cartographic
data are the second hand topographical information source, in the sense that they are
originally derived from direct height measurements of some kind. The information
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content of a topographical map depends on not only the quality of original source data
but also map scale and contour interval. In addition to contours and spot heights,
topographical maps may also contain, implicitly or explicitly, many important terrain
features such as surface break lines, ridges and drainage lines.
6. Photogrammetry-Based Stereo Technique
The photogrammetry-based stereo technique derives the digital elevation data
based on parallax differences between a stereo image pair. The principle is simple; first,
two images are acquired of the same area with slightly different viewing perspectives
(stereo-overlap). These images are then aligned and geometrically matched so that a
mathematical (triangulation) model can be obtained. The analyst then has the
opportunity to view the modeled stereo pair in 3D to manually extract the terrain
information or use automated stereo correlation tools to extract a new DTM. The
automated process is typically used when the surface landscape needs to be extracted.
“Above-the-landscape” features (e.g., buildings) are typically derived manually (using
stereo extraction tools) and then “placed” on the DTM. The accuracy of the elevation
data derived from stereo technique is often influenced by mismatch of conjugate image
pixels, and errors of the sensor position and attitude. The current and future high-
resolution earth observation satellites (table 1) having a spatial resolution of 1m & less
and stereo capabilities will go a long way in the field of mapping in terms of cost, time
and accuracy.
Table 1: High resolution sensors
Sensor Launch Date Resolution
IRS-1C 28-DEC-95 Panchromatic: 5.8 m
IRS-1D 29-SEP-97 Panchromatic: 5.8 m
IKONOS 24-SEP-1999 Panchromatic: 1 m
Multispectral: 4 m
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QuickBird 18 October 2001 Panchromatic: .61 m
Multispectral: 2.44 m
EROS A1 05-DEC-2000 1.8m
CBERS 3 2003 Panchromatic: 5 m
EROS B1 2003 Panchromatic: .81 m
EROS B2 2003 Panchromatic: .81 m
Multispectral: 3.3 m
SPOT- 5 1985 Panchromatic: 2.5m from 2 x
5m scenes
Panchromatic: 5m (nadir)
Terra-ASTER December 1999 Multispectral (B1-B3) 15m
Cartosat-1 May 2005 (Panchromatic): 2.5 m
ALOS - PRISM January 2006 Panchromatic: 2.5 m
WorldView 1 September 2007 Panchromatic: 0.55 m
GeoEye-1 August 2008 Panchromatic – 0.41m
Multispectral : 1.65m
Fig. 1. Photogrammetric technique (www.univcalagary)
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7. Synthetic Aperture Radar (SAR) Interferometry
Incidence Revisit
Year of Ban Polarizatio Swath Resolut
SAR sensor angle (days)
launch d n (km) ion (m)
(deg.)
The interferometric SAR (InSAR) technique has emerged as a precise approach
to the extraction of high-resolution elevation data and measurement of very small
surface motion (displacement); InSAR technique is based on the phase information
derived from the complex radar images. SAR interferometry combines complex radar
signals (images) recorded by the antenna at slightly different locations to measure the
phase differences between the complex radar images. Relating two complex SAR
images of the same scene acquired at two orbital locations forms an interferogram. As
the radar signal transmitted by the SAR sensor is coherent, the complex SAR image
possesses both phase and magnitude (quantities) information. The constructive and
destructive interference of coherent SAR images respectively recorded at slightly
different locations produce an interferogram with a two-dimensional fringe pattern,
which can be unwrapped into the absolute measurement of elevation.
Fig. 2. Principle of SAR interferrometry (www.aerosensing.com)
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ERS-1 1991 C VV 23 100 30 35
JERS-1 1992 L HH 35 75 18 44
ERS-2 1995 C VV 23 100 30 35
Radarsat-1 1995 C HH 10 to 50 40-500 8-100 24
SRTM 2000 X, C VV Variable 30-350 20-30
HH/HV, 100- 30-
Envisat-1 2002 C 14 to 45 35
VV/VH 400 1000
VV, HH,
PALSAR 2004 L HH/HV, 18 to 55 70 10-100 44
VV/VH
TerraSAR-X 2006 X Quad-pol 10 to 100 15-60 2-16 11
Radarsat-2 2008 C Quad-pol 10 to 50 10-500 8-100 24
20 to 49
(qualified)
10 to 20
RISAT 2008 C Quad-pol 10-240 3 - 50 13
and 49-54
(unqualifie
d)
Table 2: SAR satellites and sensors
8. Radar Altimetry
Spaceborne radar altimeters have been deployed on board of Geosat, Seasat
and ERS-1 platforms for acquiring surface height measurements. A radar altimeter is a
nadir-pointing active microwave sensor designed to measure the surface height over
ocean and ice surfaces. The radar altimeter transmits a short duration Ku-band pulse
vertically downwards, and then tracks the returned radar pulse. The information of the
shape and timing of the returned signal is utilized to estimate the surface height.
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Radar altimeters can provide accurate elevation measurements regardless of
weather condition over ocean and relatively flat and low-slope ground surface, but are
prone to errors over highly sloped and rugged lands due to the relatively large footprint.
9. Laser Altimetry
A laser altimeter can provide height measurements of submeter level accuracy
with the aid of GPS and Inertial Navigation System (INS) in determining the position and
attitude of aircraft or spacecraft, but the data collection is usually time consuming due to
its narrow ground swath. Laser altimeter data may deteriorate in the condition of bad
weather, such as clouds and precipitation, it generally provides much more accurate
measurements than the radar altimeter due to the small footprint of the laser beam.
Fig. 3. Principle of laser scanning (www.terraimaging.com)
10. Derivation of Surface Parameter
10.1 Elevation
If the point of interest is exactly at a point in the raster, the elevation can be taken
directly from the database If the point of interest is between nodes of DEM grid, we
need to interpolate from neighboring grid points, e.g. bilinear, cubic, or fit a plane to the
nearby raster points.
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10.2 Slope
Measure the surface steepness; Slope is rise over reach (rise/reach), where rise
is the change in elevation, and reach is the horizontal distance. It is expressed as:
a ratio,
a simple fraction,
a percent,
an angle in degrees.
10.3 Aspect (azimuth orientation)
Aspect is azimuthal direction of maximum surface slope with reference to true
north. Aspect calculation is very sensitive to elevation errors, especially when the
surface slope is small. Without a slope, there is no topographic aspect. The aspect at
each location determines the direction of water flow over the terrain surface.
10.4 Surface Curvature (convergence/ divergence)
The surface curvature is the second derivative of the surface (i.e., the slope of
the slope); the curvature of a surface can be calculated on a cell-by-cell basis. For each
cell, a fourth-order polynomial of the form is fit to a surface composed of a 3x3 window.
10.5 Profile Curvature
The curvature of surface in the direction of slope is referred to as the profile
curvature. Profile curvature indicates where the surface is concave or convex, resulting
acceleration or deacceleration of flow. Where acceleration of flow occurs, the stream
gains energy and its ability to transport particles increases. Therefore, areas of convex
profile curvature indicate areas of erosion. Conversely, in areas of concave profile
curvature, the flow rate decreases, the stream loses energy, and deposition occurs.
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10.6 Planform Curvature
The curvature of a surface perpendicular to the direction of slope is referred to as
the planform curvature. Planform curvature indicates where the surface is concave or
convex, resulting in convergence or divergence of flow respectively; Convergent flow
indicates a concentration of runoff and would indicate a valley. Alternatively, divergent
flow would indicate a ridge.
10.7 Cut and Fill Calculation
Estimation of the volume of material related to cutting and filling. By subtracting
the upper (top) surface height values from the lower surface height, a variable thickness
(depth) value can be obtained. The thickness values over the entire area can be
integrated to obtain the volume. Engineers need to establish road or railroad routes and
gradients that minimize the movement of earth. It is generally most economical to
balance the amount of material removed from the high areas (cut) with the amount of
material required to fill low areas (fill). Also used in Reservoir capacity estimation, ice
volume, etc.
11. Viewshed Analysis
A viewshed is the region that is visible from a given vantage point in the terrain. It
assembles all the areas where the line of sight is rising as the rays move outwards. The
yes/no values can be summed to give a cumulative sense of how many times a place is
seen. Inter-visibility (what can be seen from where) can be computed based on a set of
rays radiating outwards from a vantage point. In a complex 3D situation, there are many
effects to calculate, but on a surface the surface can only obstruct a view by rising
above the line of sight. Applications of viewshed analysis include GPS signal
availability, scenic beauty evaluation, sitting television, radio, and cellular telephone
transmitter and receiver towers, locating towers for observing forest fires or enemy
movement.
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12. Watershed Analysis
The shape of a terrain determines the movement of water across the terrain
surface; Water will flow from higher locations downwards. A raster DEM contains
sufficient information to determine pattern and characteristics of a drainage basin, such
as, the upstream area contributing to a specific location and the downstream path water
would follow, the boundary of catchment area, flow line, ridges, the hierarchical stream
system, etc. The topology of terrain surface (skeleton of surface): peaks, pits, ridges,
courses (valleys), hills and dales, etc. The area upon which water falls, and the network
through which it travels to an outlet is referred to as a drainage system. The flow of
water through a drainage system is only a subset of the hydrologic cycle, which also
includes precipitation, evaporation, and groundwater; Watersheds tend to function
ecologically as single, uniform regions. Ecologists, hydrologists, engineers, pollution
and flood control experts need to be able to define these areas precisely.
13. Dem Visualization
There are number of techniques to enhance and display DEM data. Shaded relief
is also one of the techniques, which is considered to be one of the most effective
techniques for representing topography.
13.1 Shading
The gradation from dark to light in a single color according to specific principals for the
purpose of creating a three dimensional effect is called shading. In contrast to the metric
accuracy of contour lines, hill shading is primarily used for its visual effects. Slope
shading operates on the principal that the steeper the slope - the darker the shade.
Oblique shading or hill shading is based upon the effect of an oblique light source on a
terrain surface.
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13.2 Slope Shading
Slope shading, operates basically on the principal of the steeper - the darker.
13.3 Hill Shading
Hill shading is also known as a shaded relief or simply shading, it attempts to
simulate how the terrain looks with the interaction between sunlight and surface
features. It Helps viewers recognize the shape of landform features on a map.
14. Conclusions
Terrain analysis typically encompasses numerical methods of describing
landscape attributes such as terrain roughness, vegetation, urban features, 3D models
etc. To fully model the continuous terrain surface, a large number of points are required
and DEM and TIN are two commonly used models of representing the continuous
topographic surface in digital form with a finite number of sample points. Most of the
commercial GIS systems provide both raster DEM and TIN model that can be used in
spatial analysis and surface modeling. However, it is important to note that the most
critical aspect of any terrain analysis is the accuracy of the terrain model it uses or how
close the data model either DEM/TIN represents the actual surface with all attributes.
Web Links
www.isprs.org
www.terraimaging.com
www.aerosensing.com
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GEOGRAPHIC INFORMATION SYSTEM
P.L.N. Raju
Geoinformatics Division
1. Significance of GIS in the Present Day Scenario
Geographic Information System plays an important role in creation of
geospatial information from vast sources such as analogue and digital domains, and
aid the decision makers at various junctures of resource identification, assessment
and management. It can answer many simple questions like what, where, how as
well as complex situations of using models for estimation, prediction and dynamically
recreate real world situation to visualise and fly though the area for effective planning
and management. GIS is becoming quite popular in the recent past among the
general public with the introduction of Google earth (http://earth.google.com),
Microsoft Virtual earth (http://www.microsoft.com/virtualEarth/) and NASA’s
Worldwind (http://worldwind.arc.nasa.gov) for viewing rich Geographic content in the
form of satellite pictures/maps in 2D/3D, explore, locate, navigate etc. With the help
of these resources people can find their location, assess the present situation and
find them the route to reach the destination, overlay the new surveyed routes and
other information. World wide web has also become the source for viewing
Geographic information in the form of maps and location information like Maps of
India (http://mapsofIndia.com). All types of tools used to carry out these tasks are
part of GIS with the background of satellite image. The 3d view and animation that
we carry out on the images are carried out using GIS tools. Third Generation mobile
devices are integrated with (GPS) receiving capability are loaded with Geographic
information (i.e. GIS data) and used to find where you are located and giving
directions to reach the desired destination (i.e. house/office/tourist destination etc).
This summary note outlines status of GIS that includes importance of GIS and
its role for different application studies, journey of GIS from a mere a tool to science,
how important it is to create a geospatial database and its critical nature,
transformation of GIS from commercial nature to the present potential of having
many open source and free software for the user community, progress of GIS and its
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market potential as on today, where to look and find different GIS resources in World
Wide Web and finally summarising the technological trends and future of GIS.
2. GIS Application Potential
The strength of GIS depends upon how good is the geospatial database. It
can be used for natural resource application (i.e. forestry, agriculture and water
resources etc.) in combination with remote sensing and earth observation. In
addition it is used for infrastructure development (i.e. highways, railways etc.); utility
services like water supply distribution network, telephone network management, gas
supply distribution etc.; business application such as real estate, establishment of
new retailer shops; heath services; investigation services like crime incidences and
their distribution etc and geospatial information kiosks like Bhoomi project
(http://www.kar.nic.in/bhoomi.html) of Karnataka State. In addition GIS can be used
for research and scientific investigations, particularly for water budgeting,
atmospheric modelling, climatic studies and global warming.
3. GIS: Tool to Science
GIS has evolved from a mere tool into a spatial science covering broad
spectrum of fields starting from surveying, mapping, modelling, and management to
decision theory. A discussion forum was launched on “GIS is a tool or science?” was
initiated in 1993 brought out many views about GIS (Wright et al., 1997): some
strongly feel that it is considered merely a tool as it helps only in manipulation of
spatial data, combines elements of computer science, geography and enabling
technology in problem solving environment (Skelly, 1993); Petican,1990);
Groom,1993); Feldman,1993). At the same time, many others argue that it is not
only a tool but also it is definitely a science as it addresses vast issues such as
understanding of modelling spatial phenomena (Carlson, 1993), study of spatial data
uncertainty and error, data lineage and how GIS is adopted by agencies (Wright
1993 et al.,), spatial data representation and developing algorithms to solve a
problem and apply it to test a theory (Sandhu, 1993). According to some, GIS is
considered as part of a broader information science (Wright et al., 1993), an
environment as well as a method used to discover, explore, and test spatial theory
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(Laffey, 1993) and concepts that the tools seek facilitate, automate, and develop are
strongly rooted in science (Bartlett, 1993). Amidst diverse views, growth of GIS is
phenomenal and expanded to many areas like Environmental and Earth Sciences,
Urban Planning & Infrastructure Development, Socio- Economic outreach, business
enterprise and technological domains, covering them under geoinformatics umbrella
and making itself an inevitable scientific field.
4. Critical Part of GIS
Hardware, Software, Data and trained Manpower makes it to total GIS.
Though each component is important, the most critical part of GIS is data, i.e.
creation of data needs three forth of cost involved to develop the total GIS
application project, highly trained professional are required to be part of geospatial
database creation and three fourth’s time is spend to accomplish the task of creating
the geospatial database. All the users require the basic framework data like common
datum and projection, administrative, roads, topographical and land use / land cover
layer information. The issue is creation of the same by one and use it by many. All
countries are in the process of creating it and it takes lot of time. India is also in the
process of developing at national level (i.e. National Resource Repository (NRR)
under ISRO /NNRMS and National Spatial Data Infrastructure (NSDI) under DST
and many others are in the process of development which in turn helps for overall
development and progress of India.
5. GIS Software: Commercial vs. Open/Free
GIS software is one of the bottlenecks in GIS industry as the major junk
money (~50 per cent or so) is invested towards its procurement and maintenance
annually. Because of it many users have apprehensions to change from
conventional methods to GIS. In the recent past there is a paradigm shift in usage of
GIS software. There are many new and open/free software are launched into the
market. The free software where it is freely available and mostly through www but
the user do not have access to program coding, so not possible to modify or update
it. In case of open source, it is free as well as available with full access to program
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coding so user can modify/update it according to his requirements. Table 1 below
provides list of some of commercial, open and free GIS software.
Table 1: List of GIS software available commercially/as a open source/freely to the
user.
S.No. Software Functionality /Remarks
Commercial Software
1. ArcGIS Core modules,market leader but high cost, many more to be
bought for other applications
2. Geomedia Core modules of GIS, supports education and research
institutions
3. MapInfo Moderate cost
4. AutoCAD Map Better input and database creation facility
5. JTMaps Quite economical and works in vector model
(India)
Open Source
6. GRASS GIS Satellite data analysis & GIS (http://grass.itc.it/)
7. Quantum GIS Desktop GIS, supports all OS (http://qgis.org/)
8. ILWIS Satellite data analysis & GIS (www.itc.nl)
9. JUMP Read shp and gml format, display facility and support for
wms and wfs, limitations of working with large data files
(http://jump-project.org/)
10. PostGIS With spatial extensions for the open source. PostgreSQL
database, allowing geospatial queries
(http://postgis.refractions.net/)
11. Mapserver Web server GIS S/W (http://mapserver.gis.umn.edu/)
Free Software
12. ArcView Limited analysis functionality, old version
13. TNTMIPS Satellite data analysis and GIS but limited to window size
6. Indian Geospatial Market
Indian Geospatial market has matured well and growing at much higher rate
than normal growth. Geospatial market can divide into three categories such as:
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spatial data producing agencies, user organizations (government, private, and
research and academic setup) and industry (private entrepreneurs). As per the
market survey and compilation work done by GIS development (Indian Geospatial
Handbook 2008, published by GIS Development Pvt. Ltd.) the growth for the last
three years (i.e. 2005 to 2008) is phenomenal and it is more 45 per cent increase
from the previous years. The annual turnover increased from Rs. 760 crores in 2005
that includes GIS (540), photogrammetry (120) and Image Processing (100) to Rs.
1128 crores in 2006, i.e. an increase of 48 per cent. It is further increased to more
than double i.e. Rs. 1780 crores. The details of overall Geospatial Industry including
software, hardware and Services, are shown in Table 2.
Table 2: Status of GIS revenue during 2005-08 period (Crores of rupees) (source:
GIS 540 800 1250
Photogrammetry 120 188 350
Image Processing 100 140 180
Total 760 1128 1780
Increase (%) - 48 58
Indian Geospatial Handbook, 2008).
There are many institutions / organizations which generate Remote Sensing
and Geo-Information products and provide services such as (SOI, NRSA, NATMO,
GSI, FSI, CGWB, CWC, IMD, Census & ANTRIX etc.) and the products and services
are used by many user organizations like Highways, Railways, Airways, Waterways,
Telecom, Power, Water resources & Irrigation, Health, Education, Environment &
Forest, Agriculture, Urban Development and Land Resources and Rural
Development etc. Geospatial entrepreneurs mainly owned by private provide value
added services to the above said user organizations. There are around 120
companies are involved in Geospatial industry, majority of contribution i.e. 85 per
cent of the revenue is generated by 15 per cent of companies. The top four
companies are Infotech Geospatial India (30 per cent), RMSI (4 per cent ), Wapmerr
India (0.6 per cent) and Pixel Group (0.6 per cent). The manpower required for
geospatial industry is met with many who had acquired their higher education /
professional qualifications from more than forty programs in geospatial education,
range from P.G. Diploma, and graduate in engineering to Masters in
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Engineering/Technology/Science, are presently being run across the country at
university/ institutions level.
7. GIS Web Resources
World Wide Web has become an important source for accessing resources of
remote sensing, GIS and GPS in which one can even download the satellite data,
GIS metadata, GIS themes, access to reading material, latest developments in the
form of articles from newsletters, journals. One can access to online resources on
payment basis and many cases freely as well. Table 3 provide summary of few GIS
resources, emphasizing more in Indian context.
Table 3: GIS web resources
S.No. Hosted by and Website link Nature of resources
Web access to Geospatial Information in India
1. National Natural Resources Natural Resource Repository (NRR)
Information System generated under NNRMS, ISRO/DOS
http://www.nnrms.gov.in
National Remote Sensing Centre Browsing Indian Remote Sensing
2 http://www.nrsc.gov.in (IRS) data and buying for anywhere
in India
National Informatics Centre RS & GIS basic reading material
3. http://gis.nic.in/ National level spatial information
search facility
Indian National Centre for Ocean Provide ocean information and
4. Information Service (INCOIS) advisory services to the society,
http://www.incois.gov.in/ industry, government, and scientific
community
Meteorological and Oceanographic Meteorological and Oceanographic
5. Satellite Data Archival Centre geophysical data products
http://www.mosdac.gov.in/
Web Access to Geospatial Information World over
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1. USGS Education material Common place to refer for education
http://education.usgs.gov/ material on RS, GIS and GPS
CGIAR consortium for spatial Site for downloading SRTM DEM
2. information data at 90 m resolution
http://srtm.csi.cgiar.org/
GIS Reading Material
1. GIS Development monthly GIS reading material and published
magazine articles in the magazine for more than
http://gisdevelopment.net ten years
My Coordinates monthly magazine GPS, GIS and RS reading material
2. http://www.mycoordinates.org/ with more emphasis on positioning
technology
3. Indian Society of Geomatics Newsletter (quarterly) on RS, GIS
http://www.isgindia.org/ and GPS
NNRMS Bulletin Biannual technical publication from
4. ISRO/NNRMS bringing out RS & GIS
application project outputs
Geospatial Today Monthly magazine on Geospatial
5. http://www.geospatialtoday.com/ technologies
Geo Place Website of multiple GIS and business
6. http://www.geoplace.com/ related publications
8. Technological Trends and Future of GIS
Information and Communication Technology (ICT) has revolutionized and
helped GIS to great extend. According to Peter Croswell (2005) five important trends
have exerted profound influence on geo-technology industry and user community:
• Pervasive high-performance computing
• Digital connectivity
• Geographic data capture and compilation
• Geographic data management and visualization
• Standards and open system
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Moore (Moore’s law) has predicted more than 25 years back that the
processing power of computers doubles every 18 months for the same cost and this
is true even today. Increase in processing speed, availability of computers at
affordable cost, increase of analysis functionalities, and availability of web resources
made it possible in expanding the scope of GIS. In the last five years, hardware
advances have offered GIS users a growing array of realistic and effective solutions
for field and mobile computing needs as well. The Internet has been a driver for
overall IT development, and it forced the trend in digital connectivity. It has lead to
the development of Internet GIS (also called web GIS), that has played a major role
in expanding the GIS usage, helping the users to access the geoinformation at low
cost in client-server environment and it will continue to further with standards and
better services. GIS technology has always been a tool for data visualization-
portraying complex spatial data and patterns through the use of 2-D and 3-D maps
and displays. Technology for the visualization of geographic information has taken
significant leaps in the last 25 years. During this time, GIS users have seen
tremendous advances in graphic display and large-format plotting. Realistic 3-D city
models as well as 3-D environment data; atmosphere and ocean in individual
horizontal layers can be investigated. Open standards and specifications has
become an issue due to the diverse formats and structures from different software
have complicated the integration efforts. Over the last ten years major developments
have taken place for the open standards and specifications. OCC (Open Geospatial
Consortium), ISO-TC 211, GSDI and many others at worldwide and country level
played a key role in development of these standards and it is continuing to expand
along with the ICT technological trends. As indicated above, the technological trends
can be categorized into five and summarized in the following Table 4 ( Dadhwal and
Raju, 2006).
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Table 4: Technological trends
S.No. Category Technological Trends
1. Data • Multispectral to Hyper-spectral
• Low Spatial resolution to High Spatial resolution
• Mono imaging to Stereo Imaging
• Workstation to PC based
2. Hardware • Workstation to PC based
• PCs to Mobile / pocket PCs
3. Software • Desktop level to web based GIS/Image
• analysis to Mobile GIS
4. Internet • Low bandwidth – Broad brand based
• Web services (Google Earth / Wekemepia etc.)
5. Standards • Proprietary based standards to Open
• Standards
As a whole the technological developments in geoinformatics lead to branch out
to many areas. They are:
• spatial multimedia
• open GIS/ Free GIS
• GIS Customization
• spatial Modelling
• geo-Visualization
• data Warehouse and large database handling
• knowledge discovery and Data mining
• geo-Computation
• mobile GIS /Fleet Management / Location Based Services
• web GIS /Distributed GIS
• spatial Data Infrastructure and Geo-Information Management
• sensor Web enablement
• metadata and clearing houses
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• interoperability/Open standards and specifications
References
Bartlett, D. 1993. Geography Department, Cork University, Ireland. Re: GIS as a
Science [Discussion]. GeographicInformation Systems Discussion List
[Online]
Carlson, C. L. 1993. Northern Illinois University. Re: Value of Peer Review
[Discussion]. Geographic Information Systems Discussion List [Online]
Feldman, M. 1993. Community Planning, University of Rhode Island. Re: GIS as a
Science & Value of Peer Review [Discussion]. Geographic Information
Systems Discussion List [Online].
Groom, A. 1993. Christchurch City Council, New Zealand. Re: Tool or Science?
[Discussion]. Geographic Information SystemsDiscussion List [Online].
Laffey, S. C. 1993. Department of Geography, Northern Illinois University. Re: GIS
as a Science [Discussion]. GeographicInformation Systems Discussion List
[Online].
Petican, D. J. 1993. University of Waterloo, Canada. Re: GIS as a Science
[Discussion]. Geographic Information SystemsDiscussion List [Online].
Sandhu, J. 1993. Environmental Systems Research Institute, Redlands. Re: GIS as
a Science [Discussion]. Geographic Information Systems Discussion List
[Online].
Skelly, C. W. 1993. James Cook University, Australia. GIS & Remote Sensing
Research [Discussion]. Geographic Information Systems Discussion List
[Online]
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Dadhwal,V.K and Raju,P.L.N. 2006. Geoinformatics technological trends –
expanding to diversified application areas, National Conference on Geo Informatics,
V.P.M’s Polytechnic, Thane, Maharastra, December 8-10, 2006.
Wright, D. J. 1993a. Department of Geography, UC-Santa Barbara. Re: Value of
Peer Review [Discussion]. Geographic InformationSystems Discussion List
[Online]
Wright, Dawn J., Goodchild, Michael F and Proctor, James D. 1997. “Demystifying
the Persistent Ambiguity of GIS as “Tool” Versus “Science””Annals of the
Association of American Geographers, 87(2): 346-362, 1997.
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Fundamental Concepts of GPS
P.L.N. Raju
Geoinformatics Division
Introduction:
Traditional methods of surveying and navigation resort to tedious field and
astronomical observation for deriving positional and directional information. Diverse field
conditions, seasonal variation and many unavoidable circumstances always bias the
traditional field approach. However, due to rapid advancement in electronic systems,
every aspect of human life is affected to a great deal. Field of surveying and navigation is
tremendously benefited through electronic devices. Many of the critical situations in
surveying/navigation are now easily and precisely solved in short time.
Astronomical observation of celestial bodies was one of the standard methods of
obtaining coordinates of a position. This method is prone to visibility and weather condition
and demands expertise handling. Attempts have been made by USA since early 1960`s to
use space based artificial satellites. System TRANSIT was widely used for establishing
network of control points over large regions. Establishment of modern geocentric datum
and its relation to local datum was successfully achieved through TRANSIT. Rapid
improvements in higher frequently transmission and precise clock signals along with
advanced stable satellite technology have been instrumental for the development of global
positioning system.
The NAVSTAR GPS (Navigation System with Time and Ranging Global Positioning
System) is a satellite based radio navigation system providing precise three- dimensional
position, course and time information to suitably equipped user. GPS has been under
development in the USA since 1973. The US Department of Defence as a worldwide
navigation and positioning resource for military as well as civilian use for 24 hours and all
weather conditions primarily develops it.
In its final configuration, NAVSTAR GPS consists of 21 satellites (plus 3 active
spares) at an altitude of 20200 km above the earth’s surface (Fig.1). These satellites are
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so arranged in orbits to have at least four satellites visible above the horizon anywhere on
the earth, at any time of the day. GPS Satellites transmit at frequencies L1=1575.42 MHz
and L2=1227.6 MHz modulated with two types of code viz. P-code and C/A code and with
navigation message. Mainly two types of observable are of interest to the user. In pseudo
ranging the distance between the satellite and the GPS receiver plus a small corrective
term for receiver clock error is observed for positioning whereas in carrier phase
techniques, the difference between the phase of the carrier signal transmitted by the
satellite and the phase of the receiver oscillator at the epoch is observed to derive the
precise information.
The GPS satellites act as reference points from which receivers on the ground
resect their position. The fundamental navigation principle is based on the measurement
of pseudoranges between the user and four satellites (Fig.2). Ground stations precisely
monitor the orbit of every satellite and by measuring the travel time of the signals
transmitted from the satellite four distances between receiver and satellites will yield
accurate position, direction and speed. Though three-range measurements are sufficient
but fourth observation is essential for solving clock synchronization error between receiver
and satellite. Thus, the term "pseudoranges" is derived. The secret of GPS measurement
is due to the ability of measuring carrier phases to about 1/100 of a cycle equaling to 2 to
3 mm in linear distance. Moreover the high frequencies L1 and L2 carrier signal can
easily penetrate the ionosphere to reduce its effect. Dual frequency observations are
important for large station separation and for eliminating most of the error parameters.
There has been significant progress in the design and miniaturization of stable
clock. GPS satellite orbits are stable because of the high altitudes and no atmosphere
drag. However, the impact of the sun and moon on GPS orbit though significant can be
computed completely and effect of solar radiation pressure on the orbit and tropospheric
delay of the signal have been now modeled to a great extent from past experience to
obtain precise information for various applications.
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Comparison of main characteristics of TRANSIT AND GPS reveal technological
advancement in the field of space based positioning system (Table 1)
Details TRANSIT GPS
Orbit Altitude 1000 Km 20,200 Km
Orbital Period 105 Min 12 Hours
Frequencies 150 MHz 1575 MHz
400 MHz 1228 MHz
Navigation data 2D : 4D : X,Y,Z, t velocity
Availability 15-20 minute per pass Continuously
Accuracy ñ 30-40 meters ñ15m (Pcode/No. SA
(Depending on velocity 0.1 Knots
error)
Repeatability ------- ñ1.3 meters relative
Satellite Constellation 4-6 21-24
Geometry Variable Repeating
Satellite Clock Quartz Rubidium, Cesium
GPS has been designed to provide navigational accuracy of ±10m to ±15 m.
However, sub meter accuracy in differential mode has been achieved and it has been
proved that broad varieties of problems in geodesy and geodynamics can be tackled
through GPS.
Versatile use of GPS for a civilian need in following fields have been successfully
practiced viz. navigation on land, sea, air, space, high precision kinematics survey on the
ground, cadastral surveying, geodetic control network densification, high precision aircraft
positioning, photogrammetry without ground control, monitoring deformations,
hydrographic surveys, active control survey and many other similar jobs related to
navigation and positioning,. The outcome of a typical GPS survey includes geocentric
position accurate to 10 m and relative positions between receiver locations to centimeter
level or better.
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Various Segments:
For better understanding of GPS, we normally consider three major segments viz.
space segment, Control segment and User segment. Space segment deals with GPS
satellites systems, Control segment describes ground based time and orbit control
prediction and in User segment various types of existing GPS receiver and its application
is dealt (Fig.3).
Table 2 gives a brief account of the function and of various segments along with input and
output information.
Segment Input Function Output
Space Navigation message Generate and P-Code
Transmit code and C/A Code
carrier phases and L1,L2 carrier
navigation message Navigation message
Control P-Code Observations Produce GPS time Navigation message
Time predict ephemeris
manage space
vehicles
User Code observation Carrier Navigation solution Position velocity
phase observation Navigation Surveying solution time
Message
GLONASS (Global Navigation & Surveying System) a similar system to GPS is being
developed by former Soviet Union and it is considered to be a valuable complementary
system to GPS for future application.
Space Segment:
Space segment will consist 21 GPS satellite with an addition of 3 active spares.
These satellites are placed in almost six circular orbits with an inclination of 55 degree.
Orbital height of these satellites is about 20,200 km corresponding to about 26,600 km
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from the semi major axis. Orbital period is exactly 12 hours of sidereal time and this
provides repeated satellite configuration every day advanced by four minutes with respect
to universal time.
Final arrangement of 21 satellites constellation known as "Primary satellite
constellation" is given in Fig.4. There are six orbital planes A to F with a separation of 60
degrees at right ascension (crossing at equator). The position of a satellite within a
particular orbit plane can be identified by argument of latitude or mean anomaly M for a
give epoch. GPS satellite are broadly divided into three block (Table 3) Block-I satellite
pertains to development stage, Block II represent production satellite and block IIR are
replenishment/spare satellite.
Table 3 Status of GPS satellite (July 1992)
Launch Satellite PRN Code Launch date Orbit Plan Status
Sequence Vertical
BLOCK I
I-1 01 04 02/78 --- Unusable
7/85
I-2 02 07 05/78 --- Unusable
7/81
I-3 03 06 10/78 Marginal Use
I-4 04 08 12/78 Unusable
10/89
I-5 05 05 02/80 Unusable
11/83
I-6 06 09 04/80 Unusable
3/91
I-7 07 -- -- Launch
Failure
I-8 08 11 07/83 C3 Operational
I-9 09 13 06/84 C1 Operational
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I-10 10 12 09/84 A1 Operational
I-11 11 03 10/85 C4 Operational
BLOCK II
II-1 14 14 02/89 E1 Operational
II-2 13 02 06/89 B3 "
II-3 16 16 08/89 E3 "
II-4 19 19 10/89 A4 "
II-5 17 17 12/89 D3 "
II-6 18 18 01/90 F3 "
II-7 20 20 03/90 B2 "
II-8 21 21 08/90 E2 "
II-9 15 15 10/90 D2 "
BLOCK-II R
II-10 23 23 11/90 E4 Operational
II-11 24 24 07/91 D1 "
II-12 25 25 02/92 A2 "
II-13 28 28 04/92 C2 "
II-14 26 26 -7/92 "
II-15 "
Under Block-I, NAVSTAR 1 to 11 satellites were launched before 1978 to 1985 in
two orbital planes of 63 degree inclination. Design life of these prototype test satellites
was only five years but as indicated in Table 2 the operational period has been exceeded
in most of the cases. The first Block-II production satellite was launched in February 1989
using channel Douglas Delta 2 booster rocket. A total of 28 Block-II satellites are planned
to support 21+3 satellite configuration. Block-II satellites have a designed lifetime of 5-7
years.
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To sustain the GPS facility, the development of follow-up satellites under BLock-II
R has already started. Twenty replenishment satellite will replace the current block-II
satellite as and when necessary. These GPS satellites under Block-IIR will have additional
ability to measure distances between satellites and will also compute ephemeris on
board for real time information.
Fig.5 gives a schematic view of Block-II satellite Electrical power in generated
through two solar penal covering surface area of 7.2 square meter each. However,
additional battery backup is provided to provide energy when the satellite moves into
earth`s shadow region. Each satellite weighs 845kg and has a propulsion system for
positional stabilization and orbit maneuvers. GPS satellites have very high performance
of frequency standard with an accuracy of between 1X10-12 to 1X10-13 and are thus
capable of creating precise time base. Block-I satellites were partly equipped with only
quartz oscillators but Block-II satellites have two cesium frequency standards and two
rubidium frequency standards. Using fundamental frequency of 10.23 MHz, two carrier
frequencies are generated to transmit signal codes.
Observation principle and signal structure:
NAVSTAR GPS is a one-way ranging system i.e. signals are only transmitted by
the satellite . Signal travel time between the satellite and the receiver is observed and the
range distance is calculated through the knowledge of signal propagation velocity. One
way ranging means that a clock reading at the transmitted antenna is compared with a
clock reading at the receiver antenna. But since the two clocks are not strictly
synchronized hence the observed signal travel time is biased with systematic
synchronization error. Biased ranges are known as pseudoranges. Simultaneous
observations of four pseudoranges are necessary to determine X, Y, Z coordinates of user
antenna and clock bias.
Real time positioning through GPS signals is possible by modulating carrier
frequency with Pseudorandom Noise (PRN) codes. These are sequence of binary values
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(zeros and ones or +1 and -1) having random character but identifiable distinctly. Thus
pseudoranges are derived from travel time of an identified PRN signal code. Two different
codes viz. P-code and C/A code are in use. P means precision or protected and C/A
mean clear/acquisition or coarse acquisition.
P- code has a frequency of 10.23 MHz. This refer to a sequence of 10.23 million
binary digits or chips per second. This frequency is also referred to as the chipping rate of
P-code. Wavelength corresponding to one chip is 29.30m. The P-code sequence is
extremely long and repeats only after 266 days. Portions of seven days each are
assigned to the various satellites. As a consequence, all satellite can transmit on the
same frequency and can be identified by their unique one week segment. This technique
is also called as Code Division Multiple Access (CDMA). P-code is the primary code for
navigation and is available on carrier frequencies L1 and L2.
The C/A code has a length of only one millisecond, its chipping rate is .023 MHz
with corresponding wave length of 300 meters. C/A code is only transmitted on L1 carrier.
GPS receiver normally have a copy of the code sequence. For determining the signal
propagation time. This code sequence is phase-shifted in time step by step and
correlated with the received code signal until maximum correlation is achieved. The
necessary phase-shift in the two sequence of codes is a measure of the signal travel time
between the satellite and the receiver antennas. This technique can be explained as code
phase observation. For precise geodetic applications, the pseudoranges should be
derived from phase measurements on the carrier signals because of much higher
resolution. Problems of ambiguity determination is vital for such observations. The third
type of signal transmitted from a GPS satellite is the broadcast message sent at a rather
slow rate of 50 bits per second (50 bps) and repeats every 30 seconds. Chip sequence of
P-code and C/A code are separately combined with the stream of message bit by binary
addition ie the same value for code and message chip gives 0 and different values result
in 1. The main features of all three signal types used in GPS observation viz carrier, code
and data signals are given in Table 4.
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Table 4 GPS Satellite Signals
Atomic Clock (G, Rb) fundamental 10.23. MHz
frequency
L1 Carrier Signal 154 X 10.23 MHz
L1 Frequency 1575.42 MHz
L1 Wave length 19.05 Cm
L2 Carrier Signal 120 X 10.23 MHz
L2 Frequency 1227.60 MHz
L2 Wave Length 24.45 Cm
P-Code Frequency (Chipping Rate) 10.23 MHz (Mbps)
P-Code Wavelength 29.31 M
P-Code Period 267 days : 7 Days/Satellite
C/A-Code Frequency (Chipping Rate) 1.023 MHz (Mbps)
C/A-Code Wavelength 293.1 M
C/A-Code Cycle Length 1 Milisecond
Data Signal Frequency 50 bps
Data Signal Cycle Length 30 Seconds
The signal structure permits both the phase and the phase shift (Doppler effect) to
be measured along with the direct signal propagation. The necessary band width is
achieved by phase modulation of the PRN code as illustrated in Fig 6.
Structure of the GPS Navigation Data:
Structure of GPS navigation data (message) as shown in fig. 7. The user has to
decode the data signal to get access to the navigation data. For on line navigation
purposes, the internal processor within the receiver does the decoding. Most of the
manufacturers of GPS receiver provide decoding software for post processing purposes.
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With a bit rate of 50 bps and a cycle time of 30 seconds, the total information
content of a navigation data set is 1500 bits. The complete data frame is subdivided into
five subframes of six second duration comprising 300 bits information. Each subframe
contains the data words of 30 bits each. Six of these are control bits. The first two words
of each subframe are the Telemetry Work (TLM) and the C/A-P-Code Hand Over Work
(HOW). The TLM work contains a synchronization pattern which facilitates the access to
the navigation data.
The navigation data record is divided into three data blocks:
Data Block I appears in the first subframe and contains the clock coefficient/bias.
Data Block II appears in the second and third subframe and contains all necessary
parameters for the computation of the satellite coordinates.
Data Block III appears in the fourth and fifth subframes and contains the almanac
data with
clock and ephemeris parameter for all available satellite of the GPS
system. This data block includes also ionospheric corrections
parameters and particular alphanumeric information for authorized
users.
Unlike the first two blocks, the subframe four and five are not repeated every 30 seconds.
International Limitation of the system accuracy:
Since GPS is a military navigation system of US, a limited access to the total
system accuracy is made available to the civilian users. The service available to the
civilians is called Standard Positioning System (SPS) while the service available to the
authorized user is called the Precise Positioning Service (PPS) under current policy the
accuracy available to SPS users is 100m, 2D-RMS and for PPS users it is 10 to 20 meters
Remote Sensing: An Overview for Decision Makers IIRS/LN/DMC/2010