Cadastral Surveying - Data Capturing Techniques PDF

Summary

This document provides a comprehensive overview of various data capturing methods used in cadastral surveying, including traditional methods, total stations, and global positioning systems (GPS). It also details the advantages and disadvantages of each method, focusing on the accuracy, efficiency, and cost-effectiveness associated with different approaches. These data collection techniques are crucial for establishing and maintaining accurate property boundaries.

Full Transcript

CHAPTER 3
Data Capturing Techniques
 Data capture means entering information into the system.
 Data acquisition are also referred to as data capture, data
automation, data conversion, data transfer, and digitizing.
 When acquiring data, one must bear in mind: purpose,
scale, resolution, accuracy, completeness, content, costs, datum
transformation and map projection.
 A key success factor for any GIS or cadaster is acquisition of
data appropriate for the identified applications.
 Data acquisition traditionally is the most costly component of
a GIS and Cadastral project. (approx. 80%)
 Data availability and data quality requirements affect the time
taken and cost incurred in database development.
Data Capturing Techniques
 Data sources for cadastral map
preparation
 Traditional Methods
 Ground surveying
 Total station
 RTK GNSS (GPS)
 Chain
 Remote sensing
 Satelite emegery
 Arial photo
 1. Traditional Methods
 Traditional methods vary both between and within countries.
They typically consist of a relatively simple method for
measuring parcel boundaries and another for area estimation.
 Common examples would be to use ‘Kada’, ‘Timad’ and
the rope method which utilizes a rope of known length
(e.g., 50 m, 100 m) to measure boundaries of parcels.
 Areas are determined using simple mathematical methods
(areas of rectangles and triangles) with assumptions on
parcel shape.
 Ground Surveying Methods
1. Measurement Tape With
Compass
The standard surveyor’s compass is a
hand-held device which shows the
bearing of a line relative to magnetic
north. Reads bearing to 0.5°
 Simple, quick and inexpensive
 Calculation may be time consuming
 High accuracy
 Updating and maintenance surveys
 Inaccuracy in length of tape, slope,
temprarature, pressure, sag etc.
 2. Theodolites
 Optical/mechanical
 Measures angle
 Replaced with total stations
 3. Total Stations
 In the past, transit & theodolite were the most commonly
used surveying instruments for making angle observation.
These two devices were fundamentally equivalent and
could accomplish basically the same task.
 Today, the total station instruments have replaced transit
and theodolites.
 Total station can accomplish the entire task that could be
done with transit and theodolite and do much more
efficiently.
A total station is a combination of theodolite and electronic
distance measuring device (EDM).
 electronic angle and distance measurement
 built-in field computer to calculate positions
 has millimetre level accuracy
 demands line of sight to the objects, minimum of
two known points
 expensive
 In addition, they can also observe distance accurately and
quickly. Furthermore, they can make computation with angle
and distance observation and display the resulting real time. They
are used for all types of surveying include, topographic,
hydrographic, cadastral and construction survey.
 They combine three basic components;
 1) Electronic distance measuring instruments (EDM.)
 2) Electronic angle measurement instruments
 3) Computers or microprocessor....into one integral unit
 Total station do not use any signal from satellite to fix a position
on the ground. Hence it has high advantages in urban and forest
area than satellite methods.
 Total station is very accurate instrument. For example Leica
TPS1200+ model has a superb accuracy of 1 mm + 1.5 ppm for a
range of 3 km. And it has a choice of accuracy for angle from 1
to 5 seconds.
 Instrument Set Up
 Instrument Set Up: Mount the instrument onto the tripod and secure firmly. Level
and centre the instrument precisely to ensure the best performance. Use the tripod
with a 5/8” tripod screw.
 Operation Reference: Levelling and Centring the Instrument
1. Setting up the tripod: First extend the extension legs to suitable length and tighten the
screws, firmly plant the tripod in the ground over the point of beginning.
2. Attaching the instrument to the tripod: Secure the instrument carefully on the tripod
and slide the instrument by loosening the tripod mounting screw. If the optical plumb
site is positioned over the centre of the point tighten the mounting screw.
3. Roughly levelling the instrument by using the circular vial: Turn the levelling screw
A and B to move the bubble in the circular vial, in which case the bubble is located on a
line perpendicular to a line running through the centres of the two levelling screw being
adjusted. Turn the levelling screw C to move the bubble to the centre of the circular
vial. Recheck the position of the instrument over the point and adjust if needed.
4. Levelling by using the plate vial: Rotate the instrument horizontally by loosening the
Horizontal Clamp Screw and place the plate vial parallel with the line connecting
levelling screws A and B, then bring the bubble to the centre of the plate vial by turning
the levelling screws A and B. Rotate the instrument 90° (100g) around its vertical axis
and turn the remaining levelling screw or levelling C to centre the bubble once more.
 What does Total station does?
 Can observe horizontal and
vertical angles as well as slope
distance from a single setup;
 From these data, they
instantaneously compute
elevation and coordinates of
points sighted and display the
result;
 Can store data
 Averaging multiple angles and
distance measurement
 Calculating point elevation
 Computing coordinates from
horizontal angle and distance
 Detail Measurement
Traversing
 4. Global Positioning System (GPS)
 GPS is a satellite-based navigation system that was
developed by the U.S. Department of Defense in the early
1970s.
 Initially, GPS was developed as a military system to fulfill
U.S. military needs.
 GPS consists, nominally, of a constellation of 24 operational
satellites.
 To ensure continuous worldwide coverage, GPS satellites
are arranged so that four satellites areplaced in each of six
orbital planes.
 4. Global Navigation Satellite System (GNSS)
 Provides precise three dimensional
position, navigation, and time
information
 Different GNSS
 Global Positioning System (GPS) – America
 GLONASS - Russia
 GALILEO - European
 Compass - China
RTK GPS, can be used depending on the
project requirements, location, and other
factors.
The RTK surveying, however, seems to be
the most suitable method, especially in
unobstructed areas.
Inaccessible locations or obstructed areas
can be surveyed with integrated systems
such as GPS/total station.
 GNSS receivers …
4.1 Handheld GPS
Receive radio signals from
GPS satellites
Average accuracy 6m
Inapplicable for cadastral
surveying
Useful for reconnaissance
surveying, large investment
area
Navigation purpose
 4.2 Precision GPS/RTK GPS
 Two receivers (base and rover)
 Receives radio signals but with
advanced technique of measuring
the phase of the radio waves
 Few millimetre to cm accuracy
 much easier and quicker than total
station the combination of speed
and accuracy makes it the most
suitable tool for cadastral
surveying
 more expensive than total stations
 inefficient under shades (building
and trees)
 Advantages of Precision/RTK GPS
 Inter-visibility between the points is not required
with GPS. This means that extensive traversing is
eliminated, clear-cutting is not required, and intervening
private properties is avoided.
 GPS provides user-defined coordinates in a digital
format, which can be easily exported to any GIS system
for further analysis.
 The accuracy obtained with GPS is consistent over
the entire network; such accuracy is lacked by
conventional surveying methods.
 Also, with GPS, one reference station can support an
unlimited number of rover receivers.
 GPS Positioning
 Point positioning: employs one GPS receiver that measures
the code pseudo ranges to determine the user’s position
instantaneously, as long as four or more satellites are visible
at the receiver
 Relative positioning: employs two GPS receivers
simultaneously tracking the same satellites.
 Remote Sensing Materials
1. Satellite Images
 It is a convenient way of collecting cadastral data.
 This is comparatively new technique that makes it possible to
use georeferenced image and digitize features.
 Nowadays, satellite images with a resolution of less than one
meter are possible to obtain in Ethiopia.
Geo-referencing will be done by software such as ArcGIS.
 Using the tools of software, it is then possible to draw the
whole parcels from details that are marked in the image.
 Parcels drawn from images should therefore be regarded as a
helpful tool to collect data, but should always be followed by a
confirmation survey on the ground such as handheld GPS.
 Spatial resolution
 Spatial resolution of an
imaging system can be
measured in a number of
different ways.
It is the size of the smallest
object that can be
discriminated by the sensor.
 The greater the sensor's
resolution, the greater the data
volume and smaller the area
covered.
 Ortho-rectification
 Geo-referencing
 Digitizing features on
the image
 Resolution (pixel size)
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 Advantage of Satellite Image
 Generally, the image gives a very good overview of the
survey, making it easy to verify that all parcels and details in
an area are measured.
 Making a parcel is easier in satellite image than with ground
survey.
 It is easy to detect in the image if e.g. a parcel border line is
slightly bent, and digitize this with some extra points along
the line.
 This is often missed in ground surveys, where the bent
border is often only represented by a single line.
 Disadvantage of Satellite Images
 The image is describing the landscape as it looked like when
the image was taken. If e.g. two years have passed since
then, landscape might have changed considerably by
changed parcel shapes, new roads, etc.
 Clouds might obscure parts of the image.
 High initial cost
 To georeferencing the image, it is needed to find details in
the image that can be clearly identified in the field. This can
sometimes be difficult, and there is a risk of mixing.
 The accuracy depends on the ortho-rectification process
 Cont.…
Disadvantages
 Digitized parcel borders between
two parcels might be wrong for two
reasons.
 Firstly, two farmers might use the
same crops, making the border
invisible in the image.
 Secondly, one farmer might grow
two different crops on the same
parcel, making one parcel look like
two different parcels in the image.
 Sources of errors
 Errors in the geo-referencing
 optical errors in the camera used
 Errors in surveyed reference points
 High precision GPS or total stations are recommended for
the survey of the ground points for Georef.
 In General, satellite images are excellent tool to acquire a
general planning map, but confirmation in the field of each
parcel is necessary.
 It is also important to check the image accuracy regarding
both the resolution and the orthorectification.
 2. Aerial Images
 Aerial photogrammetry involves the use of photographs
taken in a systematic manner from air.
 Aerial photography is the taking of photographs of the
ground from an elevated position.
 They are then controlled by land survey and measured
by photogrammetric techniques.
 It deals with the photographs taken by an aerial camera
on board aircraft at different-altitude.
 Accuracies achieved are comparable with those obtained
by land survey and in many cases the work is carried out
more economically.
 Conti…
 Aerial photos are one commonly used form of raster
data, with only one purpose, to display a detailed
image on a map or for the purposes of digitization.
 Aerial photography may be classified according to
its scale:-
1) Small scale aerial photography: which cover a large area
but does not show detail data
2) Large scale aerial photography: which cover small area
but shows great detail.
Aerial photograph
 Advantages of Aerial over Satellite Images
 considerably lower height of exposures gives high resolution
often on decimeter level in ground coordinate system.
 From a stereo pair of images, a 3D model can be created
from the stereo perspective of the details in the images. This
will automatically give an accurate terrain model for the
rectification.
 The amount of needed ground control points is much lower
than terrain model needed for satellite image rectification.
 The use of ground control points for photogrammetric
calculations will give an accurate georeference of images.
 Therefore, an orthorectified aerial image is generally an
accurate tool for cadastral digitizing.
 The amount of needed ground control points is much
lower than terrain model needed for satellite image
rectification.
 It may be made for places that are inaccessible to
ground survey.
 It provides the current pictorial view of the ground.
Disadvantages of Aerial Images
 Detail variation in terrain features aren't readily
apparent without overlapping photography and
stereoscopic viewing.
 Recent aerial images of a given area are very
expensive.
 The method to capture the photograph is also
expensive.
 Comparison Results
RTK GNSS HH GPS Orthophoto HRSI
Accuracy in RMS (+m) 0 4.10 0.60 1.50

Labour (par/sur/day) 30 30 40 40

Cost per parcel ($) 12.5 7 8 10

Re-establishment possibility Excellent Poor/no V good Good

Connection to a grid Yes no yes yes

Multipurpose V good good Excellent Excellent

Combination possibility yes yes yes yes

Existing resources yes yes Going on no
 Question for Discussition
1. Did you know one traditional method used in Ethiopia for
measuring land?
2. Discuss the drawback of using traditional data capturing
methods for cadastral surveying?
3. Discuss the advantages of using total station for data capturing
in cadastral surveying?
4. What is the d/ce between Satellite and aerial Image?
5. Discuss the benefits of using satellite image for data capturing
in cadastral surveying?
6. Can you write something about Global Positioning System?
7. Discuss the application of GPS for cadastral surveying?
8. Which data capturing methods is more appropriate and
recommended for cadastral surveying? Put strong justification
Methods Recommendation
Combination of survey methods
Mainly ortho-photo for establishment
Mainly RTK GPs for maintenance

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Cadastral surveying Process for Imajery/Orthophoto

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 Land Holder Preparations
Boundaries
 Land holders must ensure that the boundaries of
their land are clearly marked on the ground.
Registration
 Registration will be in the names of those people
who are in the existing legal documents.
Therefore, these documents must be made
available. Besides, the existing registration in
ISLA will be used.
 Demarcation
 Landholders and neighbours must be present at their parcel
when demarcation and adjudication/verification is taking
place, so that he/she can show land boundaries to the Team
Surveyors and Kebele Committee.
 The absence of land holders is slowing down the process.
Inform them in time through LA committee!

18:34 35
 Demarcation continued...
 Any documents held – including 1st level certificates
(Green books) must be presented.
 Attribute/text information will be recorded in the
field on a field data sheet. A printout from ISLA with
information about the parcel will be brought to the
field to confirm or change the existing registered
information.
 The parcel boundaries will then be drawn on the
image, first with pencil, later with pen.
18:34 36
The parcel is given a unique parcel number which will
also be written on the image. Intervals are used to
avoid overlaps. The structure used in Amhara is
Region, Zone, Woreda, Kebele, Holding and Parcel ID
(e.g. AM/EE/7/23/12/2).

18:34 37
 Demarcation continued...
Where the boundaries are not clear or are not shown on
the image, landholders will assist the surveyors to
measure the land using taped measurements from objects
visible on the image, so that they can draw the boundaries
of that land on the image.

18:34 38
 Both agreed and disputed boundaries will be recorded on
hard copy prints of the relevant image using a pencil (later
with pen). The unique parcel ID is then written in the middle
of the parcel. An overlap between the images exist.

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18:34 40
Parcel map

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 THE END!!
THANK YOU FOR
YOUR
ATTENTION!!