Spatial Information Technology PDF

Summary

This document provides an overview of Spatial Information Technology and Geographical Information Systems (GIS). It covers the principles, methods, and applications of spatial data handling, including data capture, storage, analysis, and display. The document explains the concepts and components of GIS, including hardware, software, and data.

Full Transcript

You know that the computers enhance our capabilities in data processing and
in drawing graphs, diagrams and maps. The disciplines that deals with the
principles and methods of data processing and mapping using a combination of
computer hardware and the application software are referred as the Database
Management System (DBMS) and the Computer Assisted Cartography,
respectively. However, the role of such computer applications is restricted to merely
processing of the data and their graphical presentation. In other words, the data
so processed or the maps and diagrams so prepared could not be used to evolve
46 a decision support system. As a matter of fact, there are several questions that
we normally encounter in our day-to-day life and look for satisfactory solutions.
These questions may be: What is where ? Why is it there ? What will happen if it
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is shifted to a new location? Who will be benefited by such a reallocation? Who
are expected to loose the benefits if reallocation takes place? In order to,
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understand these and many other questions, we need to capture the necessary
data collected from different sources and integrate them using a computer that
is supported by geo-processing tools. Herein lays the concept of a Spatial
Information System. In the present chapter, we will discuss basic principles of
the Spatial Information Technology and its extension to the Spatial Information
System, which is more commonly known as Geographical Information System.
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What is Spatial Information Technology?
The word spatial is derived from space. It refers to the features and the phenomena
distributed over a geographically definable space, thus, having physically
measurable dimensions. We know that most data that are used today have spatial
components (location), such as an address of a municipal facility, or the
boundaries of an agricultural holdings, etc. Hence, the Spatial Information
Technology relates to the use of the technological inputs in collecting, storing,
retrieving, displaying, manipulating, managing and analysing the spatial
information. It is an amalgamation of Remote Sensing, GPS, GIS, Digital
Cartography and Database Management Systems.

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What is GIS (Geographical Information System)?
The advance computing systems available since mid 1970’s enable the processing
of georeferenced information for the purpose of organising spatial and attribute
data and their integration; locating specific information in individual files and
executing the computations, performing analysis and evolving a decision support
system. A system capable of all such functions is called Geographic Information
System (GIS). It is defined as A system for capturing, storing, checking,
integrating, manipulating, analysing and displaying data, which are spatially
referenced to the Earth. This is normally considered to involve a spatially
referenced computer database and appropriate applications software. It is
an amalgamation of Computer Assisted Cartography and Database Management
System and draws conceptual and methodological strength from both spatial and
allied sciences such as Computer Science, Statistics, Cartography, Remote Sensing,
Database Technology, Geography, Geology, Hydrology, Agriculture, Resource
Management, Environmental Science, and Public Administration.
Forms of Geographical Information
Two types of the data represent the geographical information. These are spatial and
non – spatial data (Box 4.1). The spatial data are characterised by their positional,
linear and areal forms of appearances (Fig. 4.1).

Box 4.1 : Spatial and non-spatial data

Stock Register of a Cycle shop Literate Population in States 1981
Part No. Quantity Description State % Male % Female
101435 54 Wheel Spoke Kerala 75.3 65.7
47
108943 68 Ball Bearing Maharashtra 58.8 34.8
105956 25 Wheel Rim Gujarat 54.4 32.3

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123545 108 Tyre Punjab 47.2 33.7

Geographic Database : A database contains attributes and their value or class.
The non-spatial data on the left display cycle parts, which can be located
anywhere. The data record on the right is spatial because one of the attributes,
the name of different states, which have a definite locations in a map. This data
can be used in GIS.
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Fig. 4.1 : The Point, a Line and an Area Feature

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 These data forms must be geometrically registered to a generally accepted
and properly defined coordinate system and coded so that they can be stored in
the internal database structure of GIS. On the other hand, the data those describe
the spatial data are called as Non–spatial or attribute data. The spatial data are
the most important pre-requisite in a spatial or geographical information system.
In a GIS core, it could be built in several ways. These are :
Acquire data in digital form from a data supplier
Digitise existing analogue data
Carry out one’s own surveys of geographic entities.
The choice of a source of geographical data for a GIS application is, however,
largely governed by :
The application area in itself
The available budget, and
The type of data structure, i.e., vector/raster.
For many users, the most common source of spatial data is topographical or
thematic maps in hard copy (paper) or soft copy form (digital). All such maps are
characterised by :
A definite scale which provides relationship between the map and the
surface it represents,
Use of symbols and colours which define attributes of entities mapped,
and
An agreed coordinate system, which defines the location of entities on
48 the Earth’s surface.

antages of GIS oovv er MManual
dvantages
Adv anual MMethods
ethods
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The maps, irrespective of a graphic medium of communication of geographic
information and possessing geometric fidelity, are inherited with the following
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limitations :
(i) Map information is processed and presented in a particular way.
(ii) A map shows a single or more than one predetermined themes.
(iii) The alteration of the information depicted on the maps require a new
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map to be drawn.
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Contrarily, a GIS possesses inherent advantages of separate data storage
and presentation. It also provides options for viewing and presenting the data in
several ways. The following advantages of a GIS are worth mentioning :
1. Users can interrogate displayed spatial features and retrieve associated
attribute information for analysis.
2. Maps can be drawn by querying or analysing attribute data.
3. Spatial operations (polygon overlay or buffering) can be applied on
integrated database to generate new sets of information.
4. Different items of attribute data can be associated with one another
through shared location code.

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Components of GIS
The important components of a Geographical Information System include the
following:
(a) Hardware (b) Software (c) Data
(d) People (e) Procedures
The different components of GIS are shown in Fig. 4.2.
Hardware
As discussed in Chapter 4 the GIS has three major components :
Hardware comprising the processing, storage, display, and input and
output sub-systems.
Software modules for data entry, editing, maintenance, analysis,
transformation, manipulation, data display and output.
Database management system to take care of the data organisation.
Software
An application software with the following functional modules is important
prerequisite of a GIS :
Software related to data entry, editing and maintenance
Software related to analysis/transformation/manipulation
Software related to data display and output.
Data
Spatial data and related tabular data are the backbone of GIS. The existing data
may be acquired from a supplier or a new data may be created/collected
in-house by the user. The digital map forms the basic data input for GIS. Tabular
data related to the map objects can also be attached to the digital data. A GIS will
integrate spatial data with other data resources and can even use a DBMS. 49

People

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GIS users have a wide range from hardware and software engineers to resources
and environmental scientists, policy-makers, and the monitoring and
implementing agencies. These cross-section of people use GIS to evolve a decision
support system and solve real time problems.
Procedures
Procedures include how
the data will be retrieved,
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input into the system,
stored, managed,
transformed, analysed
and finally presented in
a final output.

Fig. 4.2 : Basic Components of GIS

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 Spatial DData
ata FFormats
ormats
The spatial data are represented in raster and vector data formats :

Raster Data Format
Raster data represent a graphic feature as a pattern of grids of squares, whereas
vector data represent the object as a set of lines drawn between specific points.
Consider a line
drawn diagonally
on a piece of paper.
A raster file would
represent this image
by sub-dividing the
paper into a matrix
of small rectangles,
similar to a sheet of
graph paper called
cells. Each cell is
assigned a position
in the data file and
given a value based
on the attribute at
that position. Its Fig. 4.3 : Generic Structure for a Grid
row and column
coordinates may identify any individual pixel (Fig. 4.3). This data representation
allows the user to easily reconstruct or visualise the original image.
The relationship between cell size and the number of cells is expressed as the
50 resolution of the raster. The effect of grid size on data in raster format is explained
in Fig. 4.4.
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Fig. 4.4 : Effect of Grid Size on Data in Raster Format

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 The Raster file formats are most often used for the following activities :
For digital representations of aerial photographs, satellite images,
scanned paper maps, etc.
When costs need to be kept down.
When the map does not require analysis of individual map features.
When “backdrop” maps are required.

Vector Data Format
A vector representation of the same diagonal line would record the position of
the line by simply recording the coordinates of its starting and ending points.
Each point would be expressed as two or three numbers (depending on whether
the representation was 2D or 3D, often referred to as X,Y or X,Y,Z coordinates)
(Fig. 4.5). The first number, X, is the distance between the point and the left side
of the paper; Y, the distance between the point and the bottom of the paper; Z,
the point’s elevation above or below the paper. Joining the measured points forms
the vector.

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Fig. 4.5 : The Vector Data Model is based around Coordinate Pairs

A vector data model uses points stored by their real (earth) coordinates. Here
lines and areas are built from sequences of points in order. Lines have a direction
to the ordering of the points. Polygons can be built from points or lines. Vectors
can store information about topology. Manual digitising is the best way of vector
data input.
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The Vector files are most often used for :

Highly precise applications

When file sizes are important

When individual map features require analysis

When descriptive information must be stored
The advantages and the disadvantages of the raster and vector data formats
are explained in Box 4.2.

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 Go through it once
more

Box 4.2 : Comparison of Raster and Vector Data Formats
Raster Model Vector Model
Advantages Advantages
Simple data structure Compact data structure
Easy and efficient overlaying Efficient for network analysis
Compatible with satellite Efficient projection
imagery transformation
High spatial variability is Accurate map output
efficiently represented
Simple for own programming
Same grid cells for several
attributes
Disadvantages
Disadvantages Complex data structure
Inefficient use of computer Difficult overlay operations
storage
High spatial variability is
Errors in perimeter and shape inefficiently represented
Difficult network analysis Not compatible with satellite
Inefficient projection imagery
transformations
Loss of information when using
large cells, Less accurate
(although interactive) maps

Raster entities Real world entities Vector entities

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Fig. 4.6 : Representation of Spatial Entities in Raster and Vector Data Formats

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S equen ce of GIS AActivities
equence ctivities
The following sequence of the activities are involved in GIS-related work :
1. Spatial data input
2. Entering of the attribute data
3. Data verification and editing
4. Spatial and attribute data linkages
5. Spatial analysis
Spatial Data Input
As already mentioned, the spatial database into a GIS can be created from a
variety sources. These could be summarised into the following two categories :
(a) Acquiring Digital Data sets from a Data Supplies
The present day data supplies make the digital data readily available, which
range from small-scale maps to the large-scale plans. For many local governments
and private organisations, such data form an essential source and keep such
groups of users free from overheads of digitising or collecting their own data.
Although, using such existing data sets is attractive and time saving, serious
attention must be paid to data compatibility when data from different sources/
supplies are combined in one project. The differences in terms of projection, scale,
base level and description in attributes may cause problems.
At a practical level, users must consider the following characteristics of the
data to ensure that they are compatible with the application:
The scale of the data
The geo-referencing system used
The data collection techniques and sampling strategy used
The quality of data collected 53
The data classification and interpolation methods used
The size and shape of the individual mapping units

Spatial Information T
The length of the record.
It must also be noted that where data are used from a number of sources,
and particularly where the area of study crosses administrative boundaries, the
difficulties in data integration are caused by different geographical referencing
systems, data classification and sampling. Hence, the user needs to be aware of
these problems, which are particularly prone when compiling inter-province,
and inter-district data sets. Once, the compatibility between the data acquired
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from different suppliers is established, the next stage involves the transfer of
data from a medium of transfer to the GIS. The use of DAT tapes, CD ROMS and
floppy disks is becoming increasingly common for the purpose. At this stage, the
conversion from encoding and structuring system of the source to that of GIS to
be used is important.
(b) Creating digital data sets by manual input
The manual input of data to a GIS involves four main stages :
Entering the spatial data.
Entering the attribute data.
Spatial and attribute data verification and editing.
Where necessary, linking the spatial to the attribute data.

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 The manual data input methods depend on whether the database has a vector
topology or grid cell (raster) structure. The most common ways of inputting spatial
data in to a GIS are through:
Digitisation
Scanning
With the entity model, geographical data are in the form of points, lines and/
or polygons (areas)/pixels which are defined using a series of coordinates. These
are obtained by referring to the geographical referencing systems of the map or
aerial photograph, or by overlaying a graticule or grid onto it. The use of digitisers
and the scanners greatly reduce the time and labour involved in writing down
coordinates. We shall, briefly, discuss how the spatial data are created in GIS
core using a scanner.
Scanners
Scanners are the devices for converting analogue data into digital grid-based
images. They are used in spatial data capture to convert a line map to high-resolution
raster images which may be used directly or further processed to get vector
topology. There are two basic types of scanners :
Scanners that record data on a step-for-step basis, and
Those that can scan whole document in one operation.
The first type of scanners incorporates a source of illumination on a movable
arm (usually light emitting diodes or a stabilised fluorescent lamp) and a digital
camera with high-resolution lamp. The camera is usually equipped with special
sensors called Charged Coupled Devices (CCDs) arranged in an array. These are
semi-conductor devices that translate the photons of light falling on their surface
into counts of electrons, which are then recorded as a digital value.
The movement of either the scanner or the map builds up a digital
54 two-dimensional image of the map. The map to be scanned can be mounted
either on a flat bed, or on a rotating drum. With flatbed scanners, the light source
is moved systematically up and down over the surface of the document. For
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large maps, scanners are used which are mounted on a stand and the illumination
source and camera array are fixed in a position. The map is moved past by a
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feeding mechanism. Modern document scanners resemble laser printers in reverse
because the scanning surface is manufactured with a given resolution of light
sensitive spots that can be directly addressed by the software. There are no
moving parts except a movable light source. The resolution is determined by the
geometry of the sensor surface and the amount of memory rather than by a
mechanical arm.
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The scanned image is always far from perfect even with the best possible
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scanners, as it contains all the smudges and defects of the original map. The
excess data, therefore, in a digital image must be removed to make it usable.

Entering the Attribute Data
Attribute data define the properties of a spatial entity that need to be handled in
the GIS, but which are not spatial. For example, a road may be captured as a set
of contiguous pixels or as a line entity and represented in the spatial part of the
GIS by a certain colour, symbol or data location. Information describing the type
of road may be included in the range of cartographic symbols. The attribute
values associated with the road, such as road width, type of surface, estimated
number of traffic and specific traffic regulation may also be stored separately

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either as spatial information in the GIS in case of relational databases, or input
along with spatial description with the object-oriented data bases.
The attribute data acquired from sources like published record, official
censuses, primary surveys or spread sheets can be used as input into GIS database
either manually or by importing the data using a standard transfer format.

Data Verification and Editing
The spatial data captured into a GIS require verification for the error identification
and corrections so as to ensure the data accuracy. The errors caused during
digitisation may include data omissions, and under/over shoots. The best way
to check for errors in the spatial data is to produce a computer plot or print of
the data, preferably on translucent sheet, at the same scale as the original. The
two maps may then be placed over each other on a light table and compared
visually, working systematically from left to right and top to bottom of the map.
Missing data and locational errors should be clearly marked on the printout.
The errors that may arise during the capturing of spatial and attribute data may
be grouped as under :

Spatial data are incomplete or double
The incompleteness in the spatial data arises through omissions in the input of
points, lines, or polygons/area of manually entered data. In scanned data the
omissions are usually in the form of gaps between lines where the raster vector
conversion process has failed to join up all parts of a line.

Spatial data at the wrong scale
The digitising at the wrong scale produces input spatial data at a wrong scale.
In scanned data, the problems usually arise during the geo-referencing process 55
when incorrect values are used.

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Spatial data are distorted
The spatial data may also be distorted if the base maps used for digitising are
not scale correct. The aerial photographs, in particular, are characterised by
incorrect scale because of the lens distortions, relief and till displacements. In
addition, paper maps and field documents used for scanning or digitising may
contain random distortions as a result of having been exposed to rain, sunshine
and frequent folding. Hence, transformation from one coordinate system to
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another may be needed if the coordinate system of the database is different from
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that used in the input document or image.
These errors need corrections through various editing and updating functions
as supported directly by most GIS software. The process is time-consuming and
interactive that can take longer time than the data input itself. The data editing is
usually undertaken by viewing the portion of map containing the errors on the
computer screen and correcting them through the software using the keyboard,
screen cursor controlled by a mouse or a small digitiser tablet.
Minor locational errors in a vector database may be corrected by moving the
spatial entity through the screen cursor. In some GIS, computer commands
may be used directly to move, rotate, erase, insert, stretch or truncate the graphical
entities are required. Where excess coordinates define a line these may be removed
using ‘weeding’ algorithms. Attribute values and spatial errors in raster data

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 must be corrected by changing the value of the faulty cells. Once, the spatial
errors have been corrected, the topology of vector line and polygon networks can
be generated.
Data Conversion
While manipulating and analysing data, the same format should be used for all
data. When different layers are to be used simultaneously, they should all be in
vector or all in raster format. Usually, the conversion is from vector to raster,
because the biggest part of the analysis is done in the raster domain. Vector data
are transformed to raster data by overlaying a grid with a user-defined cell size.
Sometimes, the data in the raster format are converted into vector format.
This is the case especially if one wants to achieve data reduction because the
data storage needed for raster data are much larger than for vector data.
Geographic Data : Linkages and Matching
The linkages of spatial and the attribute data are important in GIS. It must,
therefore, carefully be undertaken. Linking of attribute data with a non-related
spatial data shall lead to chaos in ultimate data analysis. Similarly, matching of
one data layer with another is also significant.
Linkages
A GIS typically links different data sets. Suppose, we want to know the mortality
rate due to malnutrition among children under 10 years of age in any state. If we
have one file that contains the number of children in this age group, and another
that contains the mortality rate from malnutrition, we must first combine or link
the two data files. Once this is done, we can divide one figure by the other to
obtain the desired answer.
56 Exact Matching
Exact matching means when we have information in one computer file about
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many geographic features (e.g., towns) and additional information in another file
about the same set of features. The operation to bring them together may easily
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be achieved using a key common to both files, i. e. name of the towns. Thus, the
record in each file with the same town name is extracted, and the two are joined
and stored in another file.
Hierarchical Matching
Some types of information, however, are collected in more detail and less frequently
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than other types of information. For example, land use data covering a large area
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are collected quite frequently. On the other hand, land transformation data are
collected in small areas but at less frequent intervals. If the smaller areas adjust
within the larger ones, then the way to make the data match of the same area is to
use hierarchical matching — add the data for the small areas together until the
grouped areas match the bigger ones and then match them exactly.
Fuzzy Matching
On many occasions, the boundaries of the smaller areas do not match with those
of the larger ones. The problem occurs more often when the environmental data
are involved. For example, crop boundaries that are usually defined by field
edges/boundaries rarely match with the boundaries of the soil types. If we want

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to determine the most productive soil for a particular crop, we need to overlay
the two sets and compute crop productivity for each soil type. This is like laying
one map over another and noting the combinations of soil and productivity.
A GIS can carry out all these operations. However, the sets of spatial
information are linked only when they relate to the same geographical area.
Spatial Analysis
The strength of the GIS lies in its analytical capabilities. What distinguish the
GIS from other information systems are its spatial analysis functions. The analysis
functions use the spatial and non-spatial attributes in the database to answer
questions about the real world. Geographic analysis facilitates the study of real-
world processes by developing and applying models. Such models provide the
underlying trends in geographic data and thus, make new possibilities available.
The objective of geographic analysis is to transform data into useful information
to satisfy the requirements of the decision-makers. For example, GIS may
effectively be used to predict future trends over space and time related to variety
of phenomena. However, before undertaking any GIS based analysis, one needs
to identify the problem and define purpose of the analysis. It requires step – by –
step procedures to arrive at the conclusions. The following spatial analysis
operation may be undertaken using GIS :
(i) Overlay analysis (ii) Buffer analysis
(iii) Network analysis (iv) Digital Terrain Model
However, under the constraints of time and space only the overlay and buffer
analysis operations will be dealt herewith.
Overlay Analysis Operations
The hallmark of GIS is overlay operations. An integration of multiple layers of
maps using overlay operations is an important analysis function. In other words, 57
GIS makes it possible to overlay two or more thematic layers of maps of the same
area to obtain a new map layer (Fig. 4.7). The overlay operations of a GIS are

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Fig. 4.7 : Simple Overlay Operation

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 Fig. 4.8 : Urban Land Use in Aligarh City, Uttar Pradesh during 1974 and 2001

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Fig. 4.9 : Urban Land Transformations in Aligarh City during 1974-2001

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similar to the sieve mapping, i.e., the overlaying of tracing of maps on a light
table to make comparisons and obtain an output map.
Map overlay has many applications. It can be used to study the changes in
land use/land cover over two different periods in time and analyse the land
transformations. For example, Fig. 4.8 depicts urban land use during 1974 and
2001. When the two maps overlaid, the changes in urban land use have been
obtained (Fig. 4.9) and the urban sprawl is mapped during the given time period
(Fig. 4.10). Similarly, overlay analysis is also useful in suitability analysis of the
given land use for proposed land uses.

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Fig. 4.10 : Urban Sprawl of Aligarh City, Uttar Pradesh during 1974-2001

Buffer Operation
Buffer operation is another important spatial analysis function in GIS. A buffer
of a certain specified distance can be created along any point, line or area feature
(Fig. 4.11). It is useful in locating the areas/population benefitted or denied of
the facilities and services, such as hospitals, medical stores, post office, asphalt
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roads, regional parks, etc. Similarly, it can also be used to study the impact of
point sources of air, noise or water pollution on human health and the size of the
population so affected. This kind of analysis is called proximity analysis. The
buffer operation will generate polygon feature types irrespective of geographic
features and delineates spatial proximity. For example, numbers of household
living within one-kilometre buffer from a chemical industrial unit are affected by
industrial waste discharged from the unit.
Arc View/ArcGIS, Geomedia Quantum GIS free opensoftware and all other
GIS softwares provide modules for buffer analysis along point, line and area
features. For example, by using appropriate commands of either of the available
software, one can create buffers of 2, 4, 6, 8 and 10 kilometres around the cities
having a major hospital located. As a case study, point location of Saharanpur,

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 Fig. 4.11 : Buffers of Constant Width Drawn around a
Point, Line and a Polygon

Muzaffarnagar, Meerut, Ghaziabad, Gautam Budh Nagar and Aligarh has been
mapped (Fig. 4.12) and the buffer have been created from the cities where major
hospitals are found. One can observe that the areas closer to the cities are better
60 served, people living away from the cities have to travel
long distances to utilise the medical services and their
areas that are least benefitted (Fig. 4.13).
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Fig. 4.12 : Location Map
of the Cities of Western Fig. 4.13 : Buffers of Specified Distances
Uttar Pradesh around Hospitals
Internet sources to learn more:
schoolgis.nic.in
bhuvan.nrsc.gov.in
www.iirs.gov.in
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Excercises
Excercises
1. Choose the right answer from the four alternatives given below :
(i) The spatial data are characterised by the following forms of appearance :
(a) Positional (b) Linear
(c) Areal (d) All the above forms
(ii) Which one of the following operations requires analysis module software?
(a) Data storage (b) Data display
(c) Data output (d) Buffering
(iii) Which one of the following is disadvantage of Raster data format ?
(a) Simple data structure
(b) Easy and efficient overlaying
(c) Compatible with remote sensing imagery
(d) Difficult network analysis
(iv) Which one of the following is an advantage of Vector data format ?
(a) Complex data structure
(b) Difficult overlay operations
(c) Lack of compatibility with remote sensing data
(d) Compact data structure
(v) Urban change detection is effectively undertaken in GIS core using:
(a) Overlay operations
(b) Proximity analysis
(c) Network analysis
(d) Buffering
2. Answer the following questions in about 30 words :
(i) Differentiate between raster and vector data models.
(ii) What is an overlay analysis? 61
(iii) What are the advantages of GIS over manual methods?
(iv) What are important components of GIS?

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(v) What are different ways in which spatial data is built in GIS core?
(vi) What is Spatial Information Technology?
3. Answer the following questions in about 125 words :
(i) Discuss raster and vector data formats. Give example.
(ii) Write an explanatory account of the sequence of activities involved in GIS
related work.
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Glossary
Bar Graph : A series of columns or bars drawn proportional in length to the quantities they
represent. They are drawn on a selected scale. They may be drawn either horizontally
or vertically.

Central Tendency : The tendency of quantitative data to cluster around some value.

Choropleth Maps : Maps drawn on quantitative areal basis, calculated as average values
per unit of area within specific administrative units, e.g. density of population and
percentage of urban to total population. Distribution of a given phenomenon is
shown by various shades of a colour or intensity.

Class Intervals : The difference between the lower and upper limits of any class of a frequency
distribution is known as its class interval.

Correlation Co-efficient : A measure of the degree and direction of relationship between
two variables.

Cumulative Frequency : The measurement of distribution of values in the different class
intervals expressed as a percentage of the total frequencies either above or below
specified value.

Dispersion : The degree of internal variations in the different values of a variable.

Flow Maps : Maps in which the “flow” or movement of people or commodities is represented
by riband whose thickness is proportional to the quantity of goods or the number of
people moving along different routes.

Histogram : A graphical representation of a frequency distribution, such as seasonal
frequencies of rainfall.

Mean Deviation : A measure of dispersion derives from the average of deviations from some
central value. Such deviations are taken absolutely, i.e., their signs are ignored.
The central value is generally mean or median.

Median : It is the value which divides the number of observations in such a way that half
the value are less than this value and half of them are more. If the values of a
variable are arranged in either ascending of descending order, the median is the
middle value.

Mode : The mode is that value of a variable which occurs maximum number of times.

Pie Diagram : A circular diagram in which a circle is divided into sectors for presenting data
in percentage.

Standard Deviation : The most commonly used measure of dispersion. The standard deviation
is the positive square root of the mean of the squares of deviations from the mean.

Tabulation : The process of putting raw data into a systematically arranged tabular form.

Variable : Any characteristic which varies. A quantitative variable is a characteristic which
has different values; the differences of which are quantitatively measurable. Rainfall,
for example, is a quantitative variables, because the differences in its different
values at different places or at different times are quantitatively measurable. A
qualitative variable on the other hand, is the characteristic; the different values of
which cannot be measured quantitatively. Sex, for example, is a qualitative variable,
it can be either male or female. A qualitative variable is also known as an attribute.

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 Notes
Q2. 1)Rastor data represents a graphic feature as a pattern of grids of squares, whereas vector data represents
the object as a set of lines drawn between specific points.
2)

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Spatial Information T
Technology
echnology

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Work
Practical W art-II
Part-II
ork in Geography, P

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Notes