This presentation is about the raster and vector data in GIS which is important and costly as well, through the presentation we will learn about both type of data.
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Raster data and Vector data
1.
2. OVERVIEW:
One of the most important topic in GIS(Geographic information
system), which is types of data.
In this presentation, we will introduce types of Geographic data in
order to define them and differentiate between them.
Their characteristics and the usage of each one.
Their definition and how they is stored and used in geographic
database, also their format.
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3. WHAT IS DATA MODELING?
As well as, we know the importance of data and how the representation of data
should be understood in order achieve better results.
The definition from GIS perspective, will be divided into three sections:
Data model:
In information theory, a description of the rules by which data is defined, organized,
queried, and updated within an information system (usually a database management
system).
In ArcGIS, a set of database design specifications for objects in a GIS application. A data
model describes the thematic layers used in the application (for example, hamburger
stands, roads, and counties); their spatial representation (for example, point, line, or
polygon); their attributes; their integrity rules and relationships (for example, counties
must nest within states); their cartographic portrayal; and their metadata requirements.
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4. WHAT IS DATA MODELING? – CONT.
Vector data model:
A representation of the world using points, lines, and polygons. Vector
models are useful for storing data that has discrete boundaries, such as
country borders, land parcels, and streets.
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5. WHAT IS DATA MODELING? – CONT.
Raster data model
A representation of the world as a surface divided into a regular grid of
cells. Raster models are useful for storing data that varies continuously,
as in an aerial photograph, a satellite image, a surface of chemical
concentrations, or an elevation surface
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6. DATA FORMAT:
Shape-file:
A shape-file stores non-topological geometry and attribute information for the
spatial features in a data set. The geometry for a feature is stored as a shape
comprising a set of vector coordinates.
Because shape-files do not have the processing overhead of a topological data
structure, they have advantages over other data sources such as faster drawing
speed and edit ability. Shape-files handle single features that overlap or that are
noncontiguous. They also typically require less disk space and are easier to read
and write.
Shape-files can support point, line, and area features. Area features are
represented as closed loop, double-digitized polygons. Attributes are held in a
dBASE® format file. Each attribute record has a one-to-one relationship with
the associated shape record.
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VECTOR DATA FORMATS
7. CHARACTERISTICS:
Characteristic Raster Vector
Data structure Usually simple Usually complex
Storage requirements large for most data sets without
compression
small for most data sets
Coordinate conversion may be slow due to data volumes, and
may require resampling.
simple
Analysis easy for continuous data, simple for
many layer combinations.
preferred for network
analyses, many other spatial
operations more complex.
Positional precision floor set by cell size. limited only by quality of
positional measurements.
Accessibility easy to modify or program, due to
simple data structure.
often complex.
Display and output good for images, but discrete features
may show “stair-step” edges.
map-like, with continuous
curves, poor for images
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8. DATA FORMAT-CONT.
Coverage:
A coverage is a geo-relational data model that stores vector data—it contains both the
spatial (location) and attribute (descriptive) data for geographic features. Coverages
use a set of feature classes to represent geographic features. Each feature class stores
a set of points, lines (arcs), polygons, or annotation (text). Coverages can have
topology, which determines the relationships between features.
A coverage is stored as a directory within which each feature class is stored as a set of
files. For example, a coverage appears in ArcCatalog with the icons as shown below.
In this example, you can see that the streams coverage is a line coverage containing
an arc (line) file, annotation for the line, and a tic file. There are also two versions of
coverage files.
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9. DATA FORMAT-CONT.
GeoDatabase:
Geodatabases have a comprehensive information model for
representing and managing geographic information. This
comprehensive information model is implemented as a series of
tables holding feature classes, raster datasets, and attributes. In
addition, advanced GIS data objects add GIS behavior; rules for
managing spatial integrity; and tools for working with numerous
spatial relationships of the core features, raster, and attributes.
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10. DATA FORMAT-CONT.
CAD files:
AutoCAD and MicroStation each use a proprietary file-based
vector format. Both formats are capable of supporting 2D and
3D information.
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11. DATA FORMAT-CONT.
Grids
Grids are an ESRI file format used to store both discrete features such as buildings, roads, and
parcels, and continuous phenomena such as elevation, temperature, and precipitation.
Recall that the basic unit of the raster data model is the cell. Cells store information about what
things are like at a particular location on the earth's surface. Depending on the type of data being
stored, cell values can be either integers (whole numbers) or floating points (numbers with
decimals). There are two types of grids: one stores integers and the other stores floating points.
A discrete grid contains cells whose values are integers, often code numbers for a particular
category. Cells can have the same value in a discrete grid. For example, in a discrete grid of land
use, each land use type is coded by a different integer, but many cells may have the same code.
Discrete grids have an attribute table that stores the cell values and their associated attributes.
A continuous grid is used to represent continuous phenomena; its cell values are floating points.
Each cell in a continuous grid can have a different floating point value. For example, in a
continuous grid representing elevation, one cell might store an elevation value of 564.3 meters,
while the cell to the left might store an elevation value of 565.1 meters. Unlike discrete grids,
continuous grids don't have an attribute table.
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Raster Data Formats:
12. DATA FORMAT-CONT.
The term "image" is a collective term for rasters whose cells, or pixels, store brightness
values of reflected visible light or other types of electromagnetic radiation, such as emitted
heat (infrared) or ultraviolet (UV). Aerial photos, satellite images, and scanned paper maps
are examples of images commonly used in a GIS.
Images can be displayed as layers in a map or they can be used as attributes for vector
features. For example, a real estate company might include photos of available houses as an
attribute of a homes layer. To be displayed as a layer, however, images must be referenced to
real-world locations.
For example, an aerial photo as it comes from the camera is just a static picture, like a
picture of a house. There's no information about what part of the world the photo has
captured, and the photo may contain distortion and scale variations caused by the angle of
the camera. To display properly with other map layers, the aerial photo must be assigned a
coordinate system and some of its pixels must be linked to known geographic coordinates.
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Images
13. DATA FORMAT-CONT.
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Figure 1.0
Now, we can make conclusion
according to data type as
mentioned through the
presentation, we all knew that and
image is a set of pixels with
columns and rows defined by
RGB, as shown at right hand side
in figure 1.0, or could be satellite
imagery, while the vector data is
presented either by point, line or
polygon.
14. SOURCES OF DATA:
As well as all we know that gathering data is important, the data should be
meaningful, accurate, to the point, so when collecting real time GIS data, or to
store data, should be from trusted resources.
Where to get data?
1. From internet.
2. GeoServer.
3. Remote Sensing.
4. Scanned photos.
5. Digital orthophotos.
6. Collector for ArcGIS.
7. Point data samples from surveys.
List of GIS data sources.
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15. ADVANTAGES & DISADVANTAGES:
Advantages :
1. Good representation of reality
2. More efficient data storage
3. Topology can be described in a network
4. Accurate graphics
Disadvantages :
1. Complex data structures.
2. Simulation may be difficult.
3. Some spatial analysis operations are difficult or impossible to perform.
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Vector Data
16. ADVANTAGES & DISADVANTAGES - CONT.:
Advantages :
1. Simple data structure.
2. Easy overlay.
3. Various kinds of spatial analysis.
4. Uniform size and shape.
5. Cheaper technology.
Disadvantages :
1. Large amount of data.
2. Less “pretty”.
3. Projection transformation is difficult.
4. Different scales between layers can be a nightmare.
5. May lose information due to generalization.
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Raster Data