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FACULTY OF MINERAL RESOURCES TECHNOLOGY

Environmental & Safety Engineering Department

Lecture Notes On

Land Surveying
(ES/PE 256)

Compiled by:

Eric Stemn

January, 2015
Lecture Notes on Land Surveying 2014/2015 Academic Year

COURSE OUTLINE (SYLLABUS) 2014/2015 Academic Year

1. Overview of Surveying - definitions, types and procedure for surveying.

2. Measuring of Horizontal Distances - Chain Surveying

3. Angular Measurement - Compass Surveying and Applications

4. Traversing and Traverse Computation – Theodolite and Applications

5. Vertical Control – Levelling and Application

6. Area and Volume Computation

7. Modern Positioning Systems

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COURSE OBJECTIVES 2014/2015 Academic Year

The purpose of this course is to provide student with the fundamental
understanding of Land Surveying. Therefore, the following are the objective of
the course, the student will among other things;

1. Obtain a general overview of surveying including its purpose, principles
and general operations.

2. Be familiar with the methods of measuring horizontal distances

3. Be familiar with the determination of angular measurement and
direction of survey lines

4. Be able to perform traverse and conduct all necessary computations

5. Be able to perform levelling and determine the RLs of points using both
the Rise and Fall and Height of Collimation Methods

6. Be able to determine the area of a closed traverse using the coordinate
method.

7. Obtain an understanding of the satellite positioning and be able to use
handle GPS to determine position of points.

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COURSE PLAN (SCHEDULE) 2014/2015 Academic Year

Calendar
Week Month Activity
1 REGISTRATION
Course Plan and Overview of Surveying I
2
Course Plan and Overview of Surveying II
Field Work 1 (Survey Instrument Identification)
3
February Course Plan and Overview of Surveying III
Measurement of Horizontal Distance I
4
Quiz 1, Measurement of Horizontal Distance II
Field Work 2 (Basic Survey Measurement - Linear Surveys)
5
Angular Measurement and Direction I
Angular Measurement and Direction II
6
Field Work 3 (Basic Survey Measurement - Direction/Angular Surveys)
Traversing and Traverse Computation I
7
Quiz 2, Traversing and Traverse Computation II
March
Traversing and Traverse Computation III
8
Levelling I
Levelling II
9
Field Work 4 (Basic Survey Measurement - Level and Staff Usage)
Quiz 3, Area and Volume Computation I
10
Area and Volume Computation II
Satellite Positioning II
11
Field Work 5 (Basic Survey Measurement - GPS Surveys)
April
Quiz 4, Satellite Positioning II
12
Field Work (Semester Project)
Field Work (Semester Project)
13
Revision Week, Report and Group Presentation
14
15 May End of Semester Examination
16

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COURSE ASSESSMENT 2014/2015 Academic Year

ASSESSMENT OF STUDENTS

The student‘s assessment will be in two forms:

 Continuous Assessment [40%] (Quizzes, Class Attendance, Assignments
and Group Work)
 End of Semester Examination [60%].

The results of the Continuous Assessment shall be made known to students at
least one week before the start of the Semester Examinations. The End of
Semester shall be marked over 60.

ASSESSMENT OF LECTURER

At the end of the course each student will be required to evaluate the course
and the lecturer‘s performance by answering a questionnaire specifically
prepared to obtain the views and opinions of the student about the course and
lecturer. This exercise is schedule to take place from Monday, April 20, 2014
to Friday, April 24, 2014. Please be sincere and frank!

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TABLE OF CONTENTS

COURSE OUTLINE (SYLLABUS) i
COURSE OBJECTIVES ii
COURSE PLAN (SCHEDULE) iii
COURSE ASSESSMENT iv
TABLE OF CONTENTS v
LIST OF FIGURES ix
LIST OF TABLES ix

CHAPTER 1 OVERVIEW OF SURVEYING 1
1.1 Definition of Surveying 1
1.2 Classification of Surveying 2
1.2.1 Classification Based on Accuracy of Work 2
1.2.2 Classification Based on Used or Purpose 2
1.2.3 Classification Based on Instrument Used 2
1.2.3 Classification Based on Position Instrument 3
1.3 Object and Purposes of Surveying 3
1.4 Importance of Surveying 3
1.5 Principles of Surveying 4
1.5.1 Principle of Working from Whole to Part 4
1.5.2 Principles of Controls 4
1.5.3 Principle of Economy of Accuracy 5
1.5.4 Principle of Independent Check 6
1.5.5 Principle of Safeguarding 6
1.6 Stages of Survey Operation 7
1.6.1 Field Work 7
1.6.3 Office Work 8
1.6.4 Care of Instrument 8
1.7 Errors in Surveying 8
1.8 Classification of Errors 9
1.8.1 Accidental/Random Errors 9
1.8.2 Systematic Errors 9
1.8.3 Gross Errors or Mistakes 10
1.9 Units of Measurements 10
1.10 Kinds of Measurements 10
1.10.1 Linear Measures 10
1.10.2 Angular Measurements 11
1.11 Plan Scales 11
1.12 Types of Map Scales 13
1.12.1 Verbal Scale 13

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1.12.2 Graphical Scale 13
1.12.3 Representative Fraction 13
1.13 Study and Review Questions 14

CHAPTER 2 MEASUREMENT OF HORIZONTAL DISTANCES 15
2.1 Introduction 15
2.2 Methods of Measuring Horizontal Distances 15
2.3 Ranging 15
2.3.1 Direct Ranging 16
2.3.2 Indirect Ranging 16
2.4 Distance Measurements by Chaining 16
2.4.1 Introduction to Chaining 16
2.4.2 Principle of Chain Surveying 17
2.4.3 Suitability and Unsuitability of Chain Surveying 17
2.4.4 Shape, Size and Arrangement of Triangles 17
2.4.5 Terminologies in Chain Surveying 18
2.4.6 Field Work in Chain Surveying 19
2.4.7 Obstacles in Chain Survey 21
2.4.8 Errors in Chain Surveying 21
2.5 Distance Measurement by Taping 22
2.5.1 Introduction to Taping 22
2.5.2 Taping on Level Ground 22
2.5.3 Horizontal Measurement on Sloping Ground 22
2.5.4 Slope Measurement 23
2.5.5 Sources of Error in Taping 24
2.6 Electronic Distance Measurement (EDM) 24
2.6.1 Introduction to EDM 24
2.6.2 Principles of EDM 24
2.7 Study and Review Questions 25

CHAPTER 3 ANGULAR MEASUREMENT AND DIRECTION 27
3.1 Introduction 27
3.2 Units of Angular Measurement 27
3.3 Kinds of Horizontal Angles 28
3.4 Direction of a Line 29
3.5 Azimuth 29
3.6 Bearing 30
3.7 Comparison of Bearing and Azimuth 30
3.8 The Compass and the Earth Magnetic Field 31
3.8 Introduction 31
3.8.2 Surveying Compass 32

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3.8.3 Magnetic Declination 33
3.8.4 Local Attraction 33
3.9 The Theodolite 34
3.9.1 Introduction 34
3.9.2 Basic Definitions 35
3.9.3 Instrumental Errors 36
3.9.4 Sources of Error 38
3.12 Study and Review Questions 39

CHAPTER 4 TRAVERSING AND TRAVERSE COMPUTATIONS 41
4.1 Introduction 41
4.2 Selecting a Traverse Station 42
4.4 Referencing Traverse Stations 42
4.5 Angular Misclosure 43
4.6 Sources of Error and Mistakes in Traversing 43
4.7 Traverse Computations 44
4.7.1 Introduction 44
4.7.2 Balancing Angles 44
4.7.3 Computation of Preliminary Bearing or Azimuth 47
4.7.4 Computation of Departures and Latitudes 48
4.7.5 Departure and Latitude Closure Condition 49
4.7.6 Traverse Linear Misclosure and Relative Precision 49
4.7.7 Traverse Adjustment 51
4.7.8 Rectangular Coordinates 53
4.7.9 Mistakes in Traverse Computations 54
4.8 Study and Review Questions 54

CHAPTER 5 LEVELLING 56
5.1 Introduction 56
5.2 Basic Definitions 56
5.3 Instruments for Levelling 58
5.3.1 Categories of Level 58
5.3.2 Telescope 58
5.3.3 Tilting Level 58
5.3.4 Automatic Level 59
5.3.5 Digital Level 60
5.3.6 Tripods 60
5.3.7 Levelling Staff 61
5.4 Fieldwork in Levelling 61
5.4.1 Making Readings 61
5.4.2 Levelling Between Two Points 61

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5.4.3 Field Booking and Reduction of Levels 63
5.5 Precision of Levelling 65
5.6 Errors in Levelling 66
5.7 Uses of Levelling 66
5.7.1 Contouring 66
5.8 Study and Review Questions 67

CHAPTER 6 AREA AND VOLUME COMPUTATION 68
6.1 Introduction 68
6.2 Methods of Measuring Area 68
6.3 Area by Coordinates 68
6.4 Method of Volume Measurement 71
6.5 Contour Area Method 71
6.6 Study and Review Questions 73

CHAPTER 7 SATELLITE POSITIONING 74
7.1 Introduction 74
7.2 GPS Segments 75
7.3 Types of GPS 76
7.3.1 Hand-held GPS 76
7.3.2 Differential Code-Phase GPS (DGPS) 76
7.3.3 Carrier-Phase GPS 77
7.4 GPS Measuring Techniques 77
7.4.1 Static 77
7.4.2 Rapid Static 77
7.4.3 Real Time Kinematic 78
7.5 Study and Review Question 78

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LIST OF FIGURES

Figure 1.1 Example of Graphical Scale 13
Figure 2.1 Ranging a Line 16
Figure 2.2 Types of Triangle in Chain Surveying 18
Figure 2.3 Layout of a Chain Surveying 19
Figure 3.1 Basic Requirement in Determining an Angle 27
Figure 3.2 Closed Loop (Polygon) Traverse 28
Figure 3.3 Deflection Angle 29
Figure 3.4 Example of Azimuth 29
Figure 3.5 Bearing of Lines 30
Figure 4.1 Examples of Closed Traverses 41
Figure 4.2 Example of an Open Traverse 42
Figure 4.3 Example of a Traverse 45
Figure 4.4 Departure and Latitude of a Line 48
Figure 5.1 Diagram Showing Basic Levelling Terms 56
Figure 5.2 Parts of a Precise Tilting Level 59
Figure 5.3 Parts of an Automatic Level 59
Figure 5.4 Electronic Digital Level 60
Figure 5.5 Examples of Tripods 61
Figure 5.6 Principles of Levelling 62
Figure 5.7 Levelling and booking sequence 63
Figure 6.1 Area Computation by Coordinate Method 69
Figure 6.2 Traverse for Computation of Area by Coordinates 70
Figure 6.3 Illustration of the Contour-Area Method 72
Figure 8.1 GPS Segments 76

LIST OF TABLES

Table 1.1 Recommended scales for use with the metric system 12
Table 3.1 Comparison of Bearing and Azimuth 31
Table 4.1 Adjustment of Angles 46
Table 4.2 Computation of Preliminary Azimuth 48
Table 4.3 Computing of Departures and Latitudes 50
Table 4.4 Balancing Departures and Latitudes by Bowditch Rule 52
Table 5.1 Rise and Fall Method 63
Table 5.2 Height of Collimation method 64
Table 6.1 Traverse for the Computation of Area by Coordinates 71
Table 6.2 Volume Computation by Contour-Area Method 73

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CHAPTER 1

1 OVERVIEW OF SURVEYING

1.1 Definition of Surveying

Surveying is basic to engineering. Before any engineering work can be started,
there is the need to prepare a plan or map of the area showing topographical
details. This involves both horizontal and vertical measurements. Surveying is
defined as the science of determining the position, in three dimensions, of
natural and man-made features on or beneath the surface of the Earth. These
features may be represented in analogue form as a contoured map, plan or
chart, or in digital form such as a digital ground model (DGM or DTM or DEM).
Surveying therefore refers to those activities involved in the planning and
execution of surveys for the location, design, construction, operation and
maintenance of civil and other engineering projects. Surveying activities may
involve the following:

1. Preparation of surveys and related mapping specifications
2. Execution of field surveys for the collection of required data including
topographic and hydrographic data.
3. Calculation, reduction and plotting of survey data for use in engineering
design.
4. Design and provision of horizontal and vertical control survey networks.
5. Provision of line and grade and other layout work for construction and
mining activities

Therefore the scope of surveying is very wide and interdisciplinary in nature.
Basically it involves accurate measurements and accurate computations. In
surveying we use modern sophisticated instruments, example, electronic
instruments for measurements and modern computational tools, example,
computers for accurate mathematical computations. Hence thorough
knowledge of basic science such as, physics and mathematics is required in
grasping modern surveying.

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1.2 Classification of Surveying

Surveying is a very old profession and can be classified in many different ways.
Classification can be based on the following:

1.2.1 Classification Based on Accuracy of Work

Two general classifications of surveys are geodetic and plane. In geodetic
surveying the curvature of the earth is taken into account. Surveys are
conducted with a high degree of accuracy. However in plane surveying except
for levelling, the reference base for field work and computations is assumed to
be a flat horizontal surface. The errors introduced by assuming the earth to be
a plane area is not serious if the area measured is small (≤ 250 km2).

1.2.2 Classification Based on Used or Purpose

Surveying can be classified based on the use and purpose of the results
obtained. This classification includes the following:

1. Control surveys establish a network of horizontal and vertical points that
serve as a reference framework for other surveys.
2. Topographic surveys show the natural features of a country such a river,
stream, lakes, forest, hills, mountains, valleys and so on.
3. Hydrographic surveys define the shore lines and depth of water bodies
such as ocean, lakes and reservoirs
4. Land, boundary or cadastral surveys establish property lines and corners
5. Route surveys are done as a preliminary to construction of roads 'and
railways
6. Mine Surveys are done on, above and below ground to guide mining
operation both underground and on surface.

1.2.3 Classification Based on Instrument Used

In chain, theodolite, plane table, tacheometric surveys, the equipment or
instrument named is the major equipment or instrument used in the survey
work.

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1.2.3 Classification Based on Position Instrument

When measurement is done on the ground, for instant by chain, tape or
electronic distance measuring instruments, it is a ground/land survey;
however when photographic and remotely sensed data are taken from the air,
it is an aerial survey.

1.3 Object and Purposes of Surveying

The object of surveying is the preparation of plans and maps of the areas. Or is
the representation of tracts of land in the form of a plan ―drawn to scale‖ upon
a sheet of drawing paper, also to facilitate the calculation of areas of land.

Surveying is done to locate the positions of points on or near the surface of the
earth. This involves measurements of distances and angles to determine
horizontal positions of arbitrary points on the earth‘s surface, heights of
arbitrary points above or below a reference datum and the configuration of the
ground. It also involves setting-out distances, angles and grid lines to locate
construction lines for buildings, bridges, highways, drill holes and other
engineering works and establishing the positions of boundary lines on the
ground. Surveying, which is the art of determining the relative positions of
distinctive features on the surface of the earth, by means of measurements of
distances, directions and elevations are used for two distinct purposes. These
are:
1. The determination of the relative positions of points (natural or artificial
features) on the surface of the earth so that they may be correctly
represented on maps or plans.
2. The setting-out on the ground of the positions of proposed construction
or engineering works.

1.4 Importance of Surveying

Surveying continues to play an extremely important role in many braches of
engineering. For example, surveys are required to plan, construct, and
maintain highways, railroads, rapid-transit systems, buildings, bridges,
missile ranges, lunching sites, tracking stations, tunnels, canals, irrigation
ditches, dams, drainage works, urban land subdivisions, water supply and
sewage systems, pipelines, and mine shafts. Surveying methods are commonly
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employed in laying out industrial assembly lines. These methods are also used
for guiding the fabrication of large equipment, such as airlines and ships,
where separate pieces that have been assembled at different locations must
ultimately be connected as a unit. Surveying is important in many related
tasks in agronomy, archeology, astronomy, forestry, geography, geology,
geophysics, landscape architecture, meteorology, paleontology, and
seismology, but particularly in military and civil engineering.

1.5 Principles of Surveying

Every profession must be founded upon sound practice and in this surveying
is no different. Practice in turn must be based upon proven principles. The
fundamental principles upon which various survey methods are based are
themselves of a very simple nature.

1.5.1 Principle of Working from Whole to Part

In most types of survey the ruling principle is to work from the whole to the
part. Thus, in fairly extensive surveys, such as those of a large estate or of a
town, the first-thing to be done is to establish a system of control points. The
positions of these points are fixed with a fairly high standard of accuracy, but,
between them the work may be done by less accurate and consequently, by
less expensive methods. The main idea of working from whole to the part is to
prevent accumulation of errors and to localize minor errors within the frame
work of the control points. On the other hand, if survey is carried out from the
part to the whole, the errors would expand to greater magnitudes and the scale
of the survey will be distorted beyond control. In general practice the area is
divided into a number of large triangles and the positions of their vertices are
surveyed with greater accuracy, using sophisticated instruments. These
triangles are further divided into smaller triangles and their vertices are
surveyed with lesser accuracy.

1.5.2 Principles of Controls

A control network is the framework of survey stations whose coordinates have
been precisely determined and are often considered definitive. The stations are
the reference monuments, to which other survey work of a lesser quality is
related. By its nature, a control survey needs to be precise, complete and
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reliable and it must be possible to show that these qualities have been
achieved. This is done by using equipment of proven precision, with methods
that satisfy the principles and data processing that not only computes the
correct values but gives numerical measures of their precision and reliability.

Since care needs to be taken over the provision of control, it ought to be
planned to ensure that it achieves the numerically stated objectives of
precision and reliability. It must also be complete as it will be needed for all
related and dependent survey work. Other survey works that may use the
control will usually be less precise but of greater quantity. Examples are
setting out drill holes, detail surveys of a site or of an as-built development and
monitoring many points on a structure suspected of undergoing deformation.

The practice of using a control framework as a basis for further survey
operations is often called working from the whole to the part.

1.5.3 Principle of Economy of Accuracy

Surveys are carried out for a specific purpose and so should be as accurate as
they need to be. In spite of modern equipment, automated systems, and
statistical data processing the business of survey is still a manpower intensive
one and needs to be kept to an economic minimum. Once the requirement for
a survey or some setting out exists, then part of the specification for the work
must include a statement of the relative and absolute accuracies to be
achieved. From this, a specification for the control survey may be derived and
once this specification has been achieved, there is no requirement for further
work.

While control involves working from the whole to the part the specification for
all survey products is achieved by working from the part to the whole. The
specification for the control may be derived from estimation based upon
experience using knowledge of survey methods to be applied, the instruments
to be used and the capabilities of the personnel involved. Such a specification
defines the expected quality of the output by defining the quality of the work
that goes into the survey. Alternatively a statistical analysis of the proposed
control network may be used and this is the preferable approach. In practice a
good specification will involve a combination of both methods, statistics

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tempered by experience. The accuracy of any survey work will never be better
than the control upon which it is based. You cannot set out drill holes to 5 mm
if the control is only good to 2 cm.

1.5.4 Principle of Independent Check

The independent check is a technique of quality assurance. It is a means of
guarding against a blunder or gross error and the principle must be applied at
all stages of a survey. Failure to do so will lead to the risk, if not probability of
‗catastrophic failure‘ of the survey work. If observations are made with optical
or mechanical instruments, then the observations will need to be written
down. A standard format should be used, with sufficient arithmetic checks
upon the booking sheet to ensure that there are no computational errors. The
observations should be repeated, or better, made in a different manner to
ensure that they are in sympathy with each other. For example, if a
rectangular building is to be set out, then once the four corners have been set
out, opposite sides should be the same length and so should the diagonals.
The sides and diagonals should also be related through Pythagoras‘ theorem.
Such checks and many others will be familiar to the practising surveyor.

Checks should be applied to ensure that stations have been properly occupied
and the observations between them properly made. Data abstraction,
preliminary computations, data preparation and data entry are all areas where
transcription errors are likely to lead to apparent blunders. Ideally all these
activities should be carried out by more than one person so as to duplicate the
work and with frequent cross-reference to detect errors. Every human activity
needs to be duplicated if it is not self-checking. Wherever there is an
opportunity for an error there must be a system for checking that no error
exists. If an error exists, there must be a means of finding it.

1.5.5 Principle of Safeguarding

Since survey can be an expensive process, every sensible precaution should be
taken to ensure that the work is not compromised. Safeguarding is concerned
with the protection of work. Observations which are written down in the field
must be in a permanent, legible, unambiguous and easily understood form so
that others may make good sense of the work. Observations and other data

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should be duplicated at the earliest possible stage, so that if something
happens to the original work the information is not lost. This may be by
photocopying field sheets, or making backup copies of computer files.
Whenever the data is in a unique form or where all forms of the data are held
in the same place, then that data is vulnerable to accidental destruction. In
the case of a control survey, the protection of survey monuments is most
important since the precise coordinates of a point which no longer exists or
cannot be found are useless.

1.6 Stages of Survey Operation

The entire work of a survey operation may be divided into three district stages,
namely:
1. Field work
2. Office work
3. Care of the instrument

1.6.1 Field Work

The fieldwork involve the measurement of distances and angles required for
plotting to scale and also keeping a systematic record of what has been done in
the form of a field book or measurement book. In survey operation, field work
involves the following:

1. Reconnaissance: Here the surveyor goes to the area to fix a number of
stations, ensuring necessary intervisibility to establish a system of
horizontal control. It is just a familiarization tour of the area. A
preliminary inspection of the area is Recce.
2. Observations: The surveyor makes necessary observations with survey
instruments for linear and angular measurements.
3. Field Records: All the measurements made are recorded in a field book.
Every care is made to ensure correct entries of all the observations
otherwise the survey may be useless.

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1.6.3 Office Work

The field notes are brought to the office and necessary drafting, computing,
adjustment and designing work are done manually or electronically using a
computer.

1.6.4 Care of Instrument

A great care is required to handle survey instruments. A beginner should
always be made familiar with care and adjustment of the instruments and its
limitation. Precision instruments such as theodolite, level, and prismatic
compass need more care than the equipment such as chains, arrows, ranging
rods, etc.

1.7 Errors in Surveying

The basic task in land surveying is establishment of three-dimensional
controls using linear and angular measurements and more recently through
the use of satellites (GPS). Such measurements contain errors, since no
measurement is free of errors. True value of a measurement can therefore,
never be found, even though such a value exist. The true value is determined
statistically after repeated measurements. Since the true value of a
measurement is not known it follows that exact error will also never be known.
It must be understood that no measurement in a survey is ever exact – every
measurement, whether linear or angular, contains errors. There are basically
three main sources of errors, namely natural, instrumental and personal.

1. Natural Sources of error may be caused by adverse or variable weather
conditions examples of which are; expansion or contraction of steel tapes
due to temperature changes, refraction of light rays, variation in the
speed of electromagnetic waves through the atmosphere, etc.
2. Instrumental errors are caused by imperfect construction and
adjustment of equipment used in surveying
3. Personal errors results from the inability of the individual to make exact
observations due to limitations of human sight, touch and hearing.

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1.8 Classification of Errors

Errors can be classified into the following:
1. Accidental Errors
2. Systematic Errors
3. Gross Errors or Mistakes

1.8.1 Accidental/Random Errors

This does not mean errors arising from accidents in the field. Accidental errors
are those small errors about which nothing can be done – variations in the
eyesight of persons using instrument telescopes, sudden changes in
temperature altering the length of a steel tape, slight imperfections in
instruments, and so on. The surveyor‘s efforts should be directed principally at
eliminating mistakes and keeping systematic errors to the minimum,
according to the type of survey and the accuracy required. Random Errors are
associated with the skill and vigilance of the surveyor. They are introduced
into each measurement mainly because no human can perform perfectly. Thus
equipment and our observations are imperfect. They represent the residual
error after all other errors have been eliminated. They are compensating and
generally unavoidable. They are usually conforming to the law of probability.
Taking the mean of repeated observations minimizes their effects.

1.8.2 Systematic Errors

These are errors which always recur in the same instrument or operation, and
they are cumulative, that is to say, their effect will increase throughout the
survey. As an example, if a nominal 20 m chain has been stretched (by hard
usage) by an amount of 0.05 m, then every time it is laid on the ground there
will be an error in distance measurement of 0.05. If, in measuring the length of
a line, the chain is laid down ten times, the length of the line will be noted as
200 m, but the true length will be 20.05 m. The error will have accumulated to
10 x 0.05 m = 0.5m. These errors may be guarded against by using suitable
operational methods, by standardizing equipment, and by applying appropriate
corrections to the actual measurements.

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1.8.3 Gross Errors or Mistakes

These are serious mistakes made by the surveyor, such as reading a level staff
as 2.415 m instead of 3.415m, or noting a distance measured with the chain
as 5.45 m instead of 15.45 m. These can only be eliminated by the use of
suitable methods of observing and booking and checking both operations.
Mistakes can be detected and eliminated by repeated or check measurements.
This also improves the precision.

1.9 Units of Measurements

Several systems of units of measurement have been in use throughout the
world, including the metric system, the imperial (British) system and American
units. The American units are basically the same as the British, with some
differences in weight and volume. The republic of Ghana and many other
countries have adopted the international system of units, abbreviated to SI. In
the metric system, the unit of measurement of distance is recommended in
metre and centimetre for the execution of surveys whilst that of the imperial
system is in feet and inches. It must be noted that the Survey and Mapping
Agency of Ghana still have survey data in feet.

1.10 Kinds of Measurements

There are two kinds of measurements in plane surveying:
1. Linear measurement, i.e. Horizontal or vertical distances
2. Angular measurement, i.e. Horizontal or vertical angles.

1.10.1 Linear Measures

The basic length unit in S.I. is the metre.

Basic units of length, S. I.
10 millimetres = 1 centimetre (cm)
10 centimetre = 1 decimetre (dm)
10 decimetres = 1 metre (m)
10 metres = 1 decametre (dam)
10 decametre = 1 hectometre

Basic units of area

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The accepted units are the square kilometre (Km2), the hectare (ha) and the
square metre (m2). All of these may be used in surveying as appropriate.
10 000 m2 = 1 hectare
1 000 000 m2 = 1 Km2
100 ha = 1 Km2

Volume Units

Quantities of materials, such as excavation, rock, sand, and so on, are
expressed in cubic metres (m3) liquid volumes are stated in litres. 1 litre =
0.001 m3 (Note that 0.001 m3 is actually one cubic decimetre). The sub-
multiple of the litre is the millilitre (ml), and 1000 ml = 1 litre = 0.001 m3. The
millitre was formerly known as ―Cubic centimetre‖ and was often indicated by
the symbol ―cc‖ instead of the international symbol ―cm3‖.

1.10.2 Angular Measurements

An angle may be defined as the difference in directions of two intersecting
lines, or it is the inclination of two straight lines. The agreed angle unit in S.I.
is the radian (rad). A radian is the angle subtended at the centre of a circle by
an arc of length equal to the radius of the circle. Then, 2 π radians = 1
revolution = 4 right angles. The radian is useful in many branches of
mathematics and in some survey calculations. The practical unit of angle
measure in Ghana is degree and its sub-divisions, the minutes and the
second. Then,
60 seconds = 1 minutes
60 minutes = 1 degree
360 degree = 1 revolution
Angles may be expressed in degrees, minutes and seconds; example
273˚25'30" or in degrees and minutes and decimals of a minutes or decimal
degree; example 273.425. For the conversions between degrees and radians,
1 rad = 57.29 degrees = 206265 seconds

1.11 Plan Scales

A map scale is the ratio between a distance on a map and the corresponding
distance in the terrain. Or it is also an expression of how much the area
represented has been reduced on the map. Scale is considered to be the single

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most critical mathematical feature of any map and, because of its importance,
scale is often used as a primary means of categorising maps - from large-scale
maps of 1: 10,000 to atlases of 1:1,000,000. The scales recommended by the
international organization for standardization (I.S.O) are shown Table
Table 1.1 Recommended scales for use with the metric system

USE SCALE
1: 1 000 000
1: 500 000
Maps 1: 200 000
1: 100 000
1: 50 000
1: 50 000
1: 20 000
Town Surveys 1: 10 000
1: 5 000
1: 2 500
1: 2 500
1: 2 000
Surveys and Layouts 1: 1 250
1: 1 000
0.388888889
1: 1 250
Site Plan 1: 1 000
0.388888889
0.180555556
Location drawings 0.111111111
1:50
1:20
Components and assembly detail drawings 1:10
1:05
1:01

Scales may be said to be large or small, but there is no definite dividing point.
One scale may be said to be larger than another, if the numerical value of the
first scale‘s R.F is greater than that of the second scale, e.g. comparing scales
of 1: 100 and 1: 200,
1 1
 0.01 and  0.005
100 200
Since 0.01 is greater numerically than 0.005, the 1:100 scale is said to be
larger than the 1:200 scale. The distinction between maps and plans should be
understood. A plan is a true to scale representation. A map is drawn to such a

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small scale that some of the features shown on it cannot be drawn to scale. It
must be noted that scales are also generally grouped into two, namely;
1. Numerical scales
2. Graphical

1.12 Types of Map Scales

We can relate map and ground with three different types of scale;
3. Verbal scale
4. Graphical scale
5. Representative fraction

1.12.1 Verbal Scale

Verbal scale expresses in words as the relationship between a map distance
and a ground distance. Usually it is along the lines of: One inch represents 16
miles. Here it is implied that the one-inch is on the map, and that one-inch
represents 16 miles on the ground. Verbal scales are commonly found on
popular atlases and maps.

1.12.2 Graphical Scale

The second type of scale is a graphic scale, or bar scale. This shows directly on
the map the corresponding ground distance. Figure 1.1 Is an example of a
graphical scale.

Figure 1.1 Example of Graphical Scale

The main drawback of bar scales is that they are usually short compared to
the map itself, and hence measuring longer distances is difficult.

1.12.3 Representative Fraction

The third type of scale is a representative fraction, or ratio scale. Compared to
the first two, it is the most abstract, but also the most versatile. A
representative fraction, or RF, shows the relationship between one of any unit
on the map and one of the same unit on the ground. RFs may be shown as an
actual fraction, for example 1/24,000, but are usually written with a colon, as
in 1:24,000. In this example, one unit of any length (one mm, one cm, one

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inch, one foot, etc.) on the map represents 24,000 of those same units on the
ground (24,000 mm, 24,000 cm, 24,000", 24,000', etc.).
Examples
1. If 1 centimetre on a map represents 10 metres on the ground, what will
be the RF?
2. The scale of a plan is 1:4. If a square on the plan measures 3 by 3 units
what is the corresponding ground area?
3. An area was measured on a plan by, 250 mm x 175 mm. Calculate the
ground area in metres if the scale is (a) 1:2000 (b) 1: 500

1.13 Study and Review Questions

1. Explain surveying and state three surveying activities
2. Name the four main ways upon which surveying can be classified?
Under each of the classifications state and explain two sub-
classifications
3. State the object as well as the two main purpose of surveying?
4. Give three importance of surveying
5. State and explain three of the principles of surveying
6. What is reconnaissance in surveying
7. What the three main sources of errors in surveying? Explain each of
them
8. Errors in surveying can be classified into three classes, name and
explain each of these classes
9. Name the kinds of measurements in surveying
10. What is a plan scale? Name the three different kinds of scale in
surveying
11. If 1 centimetre on a map represents 10 metres on the ground, what will
be the RF?

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CHAPTER 2

2 MEASUREMENT OF HORIZONTAL DISTANCES

2.1 Introduction

One of the most important operations in surveying is measurement of
horizontal distance between two points. Distance measurement is generally
regarded as the most fundamental of all surveying observations. In plane
surveying, the distance between two points means the horizontal distance. If
the points are at different elevations, the distance is the horizontal length
between vertical lines at the points.

2.2 Methods of Measuring Horizontal Distances

Depending on the accuracy desired and time available for measurement, there
are many methods of measuring horizontal distances. In surveying, linear
measurements have been obtained by many different methods. These include
(1) pacing, (2) odometer readings, (3) optical rangefinders, (4) tacheometry
(stadia), (5) subtense bars, (6) chaining and taping, (7) electronic distance
measurement (EDM), (8) satellite systems, and others. Of these, surveyors
most commonly use taping, EDM and satellite systems today.

2.3 Ranging

The process of marking a number of intermediate point a survey line joining
two stations in the field so that the line between them may be measured
correctly, is called ranging. When the line is short or its end station is clearly
visible, the chain may be laid in true alignment. If the line is long or its end
station is not visible due to undulating ground, it is required to mark a
number of points with ranging rod such as a, b, c, d, etc. along chain lines
prior to chaining the distance between A and B as shown in Figure 2.1.

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d
c B
b
a

A

Figure 2.1 Ranging a Line

Ranging may be done either by eye estimation or by using line ranger or
theodolite. Theodolites are generally used in important works only. Ranging
may be classified as

1. Direct ranging
2. Indirect ranging

2.3.1 Direct Ranging

When intermediate ranging rods are fixed along the chain line, by direct
observations from either end station, the process is known as ―Direct ranging‖

2.3.2 Indirect Ranging

When end stations are not intervisible and the intermediate ranging rods are
placed in line by interpolation or by reciprocal ranging or by running an
auxiliary line (or random line) the process is known as indirect ranging.
Indirect ranging is resorted to the following situations.

1. When the end stations of a line are not distinctly visible due to a large
distance
2. When the end station of a line are not visible due to raised ground.

2.4 Distance Measurements by Chaining

2.4.1 Introduction to Chaining

Chain surveying is one of the methods of land surveying. It is the system of
surveying in which sides of various triangles are measured directly in the field
and no angular measurements are taken. Almost all surveying is based on the
triangle, and to reproduce a given triangle three things must be known: either
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(a) the lengths of the three side, or (b) two sides and an angle, or (c) one side
and two angles. Chain survey is based on the first of these three.

2.4.2 Principle of Chain Surveying

The principle of chain surveying is to divide the area into a number of triangles
of suitable sides. As a triangle is the only simple plane geometrical figure
which can be plotted with lengths of its sides alone, a network of triangles is
preferred to in chain surveys.

2.4.3 Suitability and Unsuitability of Chain Surveying

Chain surveying is most suitable in the following cases

1. When the ground is fairly level and open with simple details
2. When large scale plans are required such as those for a factory size.
3. When the area is comparatively small in extent

Chain surveying is unsuitable in the following cases

1. It is unsuitable for large areas
2. It is unsuitable for areas crowded with many details
3. It is unsuitable for wooded areas
4. It is unsuitable for undulating areas.

2.4.4 Shape, Size and Arrangement of Triangles

In chain surveying all the three sides of a triangle are liable to error. Hence, all
the side of the triangle should preferably be equal having each angle nearly
60˚. An equilateral triangle is also more accurately plottable than an obtuse
angled triangle. Hence, to ensure minimum destruction due to errors in
measurement and plotting, the best shaped triangle is an equilateral triangle.
Due to the configuration of the ground, it is not always possible to have
equilateral triangles. An attempt should therefore be made to have triangles
which are very nearly equilateral. Such triangles are known as well
conditioned or well shaped triangles. A well-conditioned triangle should not
contain any angle smaller than 30˚ and greater than 120˚. Figure 2.2 shows
the different types of shape and size of triangles in chain surveying.

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Z Z

Z 75 15
60
145
Y
60 60 Y X 30 20
X 75
Y X
An Ideal Triangle Well-Conditioned Triangle Ill-Conditioned Triangle

Figure 2.2 Types of Triangle in Chain Surveying
The triangle having angle smaller than 30˚ or greater than 120 ˚, are known as
ill-conditioned triangles. Ill conditioned triangles should always be avoided. In
case, ill-conditioned triangles are unavoidable, greater care must be taken in
their chaining and plotting. The size of a triangle depends upon the nature of
the detail and the terrain. If the terrain is open with lesser details, large
triangles may be adopted. On the other hand, if the terrain is crowded with
details, small sized triangles may be suitable.

2.4.5 Terminologies in Chain Surveying

The following are the some basic terminologies in chain surveying.

1. Main survey station – The point where two sides of a main triangle meet
is called, main survey station. Main survey station is a point of
importance at the beginning and at the end of a chain line. The chain
lines joining the main survey stations are known as main survey lines.
2. The station /subsidiary survey station – The station which are selected
on the main survey lines for running auxiliary lines are called
subsidiary stations. The chain lines joining the subsidiary survey
stations are known as auxiliary, subsidiary or more commonly as tie
lines. These are provided to locate the interior details which are far
away from the main lines.
3. Base line – The longest of the main survey lines is called a base line.
Various survey stations are plotted with reference to the base line
4. Check lines – The lines which are run in the field to check the accuracy
of the field work are called check lines. If the measured length of a
check line agrees with the length scaled off the plan, the survey is
accurate. Figure 2.3 illustrates these terminologies

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Base Line: AC
A Main Survey Lines: AB, BC, CD and AD
Main stations: A, B, C and D
Subsidiary Stations: E and F
Subsidiary or Tie Lines: BE and FD
Check Lines: HG and MN

D
M
E N

F
Road

H

G

B

C

Figure 2.3 Layout of a Chain Surveying

2.4.6 Field Work in Chain Surveying

The field work of chain surveying is carried out in the following steps

Reconnaissance

It is always useful and often absolutely necessary for the surveyor to make a
preliminary inspection of the area before commencing his actual detail survey
for the purpose of fixing the survey stations and forming a general plan for the
network of the chain lines. On arriving at the field, the surveyor first of all
walks around and thoroughly examines the ground, with the view to
determining how best he may arrange the work. The positions of the stations
can be selected and marked, the poles being used to test intervisibility. During
recce, the surveyor should prepare a sketch showing the arrangement of lines
and the numbering or lettering of the stations.

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Selection of Station

In examining the ground for a good arrangement of survey lines, the surveyor
should endeavour to meet the following requirements.

 Survey lines should be as few as practicable and such as to form a
geometrically sound framework.
 Triangle should be well conditioned and angles less than 30 ˚ should be
avoided if possible.
 There should be an adequate numbers of check line and if these can be
used to pick up some details, so much the better.
 Offsets should be kept short especially those to important features.
 Lines should lie over the more level ground

Stations Marking

Stations should be marked so that they can be found again at any time during
the survey. In soft ground wooden pegs about 0.3 m by 30 mm square may be
driven in flush and made conspicuous by dabs of paint or chalk. For marking
a permanent station, a stone of any standard shape may be embedded in the
ground and fixed with cement mortar. A brief description of each survey
station is given and reference sketches are drawn in the field book.

Running the Survey Line

On completion of preliminary work, survey lines are run as detailed below:
1. Ranging is done between the end stations of the base line.
2. A chain/tape is stretched in true alignment keeping one end of the chain
at the stating station
3. An arrow is fixed at the other end of the chain while it is kept lying on
the ground.
4. The surveyor walks along the chain line and takes offsets to adjacent
detail points on the right and left sides of the chain lines.
5. Chainages and offsets are recorded in the field book
6. Process of chaining and offsetting, is repeated until the end of the base
line is reached
7. Other lines are similar completed

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Note keeping
The book in which chainages, offset measurements and sketches of detail
points are recorded, is generally called a field book. At the beginning of a chain
line, the following information is recorded in the field book:
1. The name or number of the chain line
2. The name or number of the survey station
3. The symbol denoting the station mark
4. The direction of the survey lines starting from or ending at the station.
5. The initial chainage which is generally zero is enclosed in the symbol.
The complete record of the chain survey should include the following:
a. A general plan of lines
b. The details of lines
c. The date of survey
d. Names of surveyor and assistant

Plotting the Survey

After the field work, the data that was obtained is then plotted to produce a
map or plan of the survey.

2.4.7 Obstacles in Chain Survey

Various types of obstacles generally met during chaining may be overcome by
any one of the following methods. Obstacles to chaining may be classified as
under:
1. Obstacles which obstruct ranging but not chaining
2. Obstacles which obstruct chaining but not ranging
3. Obstacles which obstruct both ranging and chaining.

2.4.8 Errors in Chain Surveying

All measurements made with tapes and chains are subject to some form of
error, no matter how carefully any line is measured. The error may be due to
surveyor‘s carelessness or inexperience; it may be due to prevailing climatic
conditions, or it may be inherent in the instrument being used. Errors can be
divided into several classes which are:

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Gross Errors
These are mistakes arising from inexperience, carelessness or fatigue in the
observer. Examples are, miscounting of chain lengths, displacement of arrows
from their true position and faulty booking of field information (3.02 m instead
of 13.02 m). These can only be eliminated by proper and careful methods of
observing booking.

Systematic/Cumulative/Constant errors

These are errors whose magnitude and algebraic sign can be determined. They
always recur in the same instrument or operation. They include misalignment
of the tape, error due to sag of the chain in stepping operations, the chain not
being true to length and the chain not being pulled straight.

Accidental/Human errors

These are caused by variations in the eye sight of persons using the
instrument and sudden changes of temperature or wind and atmospheric
disturbances. They are usually small and not cumulative.

2.5 Distance Measurement by Taping

2.5.1 Introduction to Taping

Observation of horizontal distances by taping consists of applying the known
length of a graduated tape directly to a line a number of times. Two types of
problems arise: (1) observing an unknown distance between fixed points, such
as between two stakes in the ground and (2) laying out a known or required
distance with only the starting mark in place. Tapping can be applied on both
level and sloping grounds.

2.5.2 Taping on Level Ground
Taping on levelled ground can be performed in six steps: (1) lining in, (2)
applying tension, (3) plumbing, (4) marking tape lengths, (5) reading the tape,
and (6) recording the distance.

2.5.3 Horizontal Measurement on Sloping Ground

In taping on uneven or sloping ground, it is standard practice to hold the tape
horizontally and use a plumb bob at one or perhaps both ends. On steeper

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slopes, where a long length cannot be held horizontally without plumbing from
above shoulder level, shorter distances are measured and accumulated to total
a full tape length. This procedure, called breaking tape, is illustrated in Figure
2.4.

Figure 2.4 Procedure for Breaking Tape

2.5.4 Slope Measurement

In measuring the distance between two points on a steep slope, rather than
break tape every few meters, it may be desirable to tape along the slope and
compute the horizontal component. This requires measurement also of either
the altitude angle α or the difference in elevation d (see Figure 2.5).

Figure 2.5 Slope Measurement

In Figure 2.8, if altitude angle is determined, the horizontal distance between
points A and B can be computed from the relation:

H  Lcos eqn. 2.1
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Where H is the horizontal distance between points, L the slope length
separating them, and α is the altitude angle from horizontal, usually obtained
with an Abney hand level and clinometer. If the difference in elevation d
between the ends of the tape is measured, which is done by levelling, the
horizontal distance can be computed using the following expression derived
from the Pythagorean Theorem:

H  L2  d 2 eqn. 2.2

2.5.5 Sources of Error in Taping

There are three fundamental sources of error in taping namely

1. Instrumental errors: A tape may differ in actual length from its nominal
graduated length because of a defect in manufacture or repair, or as a
result of kinks.
2. Natural errors: The horizontal distance between end graduations of a
tape varies because of the effects of temperature, wind, and weight of the
tape itself.
3. Personal errors: Tape-persons setting pins, reading the tape, or
manipulating the equipment.

2.6 Electronic Distance Measurement (EDM)

2.6.1 Introduction to EDM

A major advance in surveying instrumentation occurred with the development
of electronic distance measuring (EDM) instruments. These devices measure
lengths by indirectly determining the number of full and partial waves of
transmitted electromagnetic energy required in traveling between the two ends
of a line. In practice, the energy is transmitted from one end of the line to the
other and returned to the starting point; thus, it travels the double path
distance. Multiplying the total number of cycles by its wavelength and dividing
by 2, yields the unknown distance.

2.6.2 Principles of EDM

In Section 2.6.1, it was stated that distances are observed electronically by
determining the number of full and partial waves of transmitted

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electromagnetic energy that are required in traveling the distance between the
two ends of a line. In other words, this process involves determining the
number of wavelengths in an unknown distance. Then, knowing the precise
length of the wave, the distance can be determined. This is similar to relating
an unknown distance to the calibrated length of a steel tape.

The procedure of measuring a distance electronically is depicted in Figure 2.6,
where an EDM device has been centred over station A by means of a plumb
bob or optical plumbing device.

Figure 2.6 Generalised EDM Procedure

The instrument transmits a carrier signal of electromagnetic energy to station
B. A reference frequency of a precisely regulated wavelength has been
superimposed or modulated onto the carrier. A reflector at B returns the signal
to the receiver, so its travel path is double the slope distance AB. In the figure,
the modulated electromagnetic energy is represented by a series of sine waves,
each having wavelength λ. The unit at A determines the number of
wavelengths in the double path, multiplied by the wavelength in feet or meters,
and divided by 2 to obtain distance AB.

2.7 Study and Review Questions

1. Explain five methods the are used for linear measurement

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2. What is ranging in surveying? Name the two types of ranging
3. What is chain surveying
4. What is the principle of chain surveying
5. Under what conditions can chain surveying be said to be suitable
6. Name three situations the makes chain surveying unsuitable
7. What is a well-conditioned and an ill-conditioned triangle
8. What should be the size, shape and arrangement of triangles during
chain surveying
9. Explain the following terms as they are applied in chain surveying
a. Main surveying line
b. Baseline
c. Check lines
d. Subsidiary survey station
10. Explain how chain surveying is carried out in the field
11. What are the main obstacles that may be encountered in chain
surveying
12. Explain how you would overcome obstacle the obstruct chaining but not
ranging
13. Compute the horizontal distance of a line with a slope distance of 500 m
and an altitude angle of 70˚
14. Name the sources of errors in taping
15. Explain the principle of EDM

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CHAPTER 3

3 ANGULAR MEASUREMENT AND DIRECTION

3.1 Introduction

Determining the locations of points and orientations of lines frequently
depends on the observation of angles and directions. In surveying, directions
are given by azimuths and bearings. Angles measured in surveying are
classified as either horizontal or vertical, depending on the plane in which
they are observed. Horizontal angles are the basic observations needed for
determining bearings and azimuth. Vertical angles are used in trigonometric
levelling, stadia and for reducing slope distances to horizontal.

Three basic requirements determine an angle. As shown in Figure 3.1, they are
(1) reference or starting line, (2) direction of turning, and (3) angular distance
(value of the angle).

Figure 3.1 Basic Requirement in Determining an Angle

3.2 Units of Angular Measurement

A purely arbitrary unit defines the value of an angle. The sexagesimal system
which is used in many countries is based on degrees, minutes, and seconds,
with the last unit further divided decimally. In other countries (mainly Europe),
the grad or gon is commonly used. Radians may be more suitable in computer
computation.

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3.3 Kinds of Horizontal Angles

The kinds of horizontal angles most commonly observed in surveying are (1)
interior angles (angles to the left and right), (2) exterior angles (angles to the
left and right), and (3) deflection angles. Since they differ considerably, the
kind used must be clearly indicated in field notes. Interior angles, shown in
Figure 3.2, are observed on the inside of a closed polygon. Normally the angle
at each apex within the polygon is measured. A check can be made on their
values because the sum of all interior angles in any polygon must equal (n-
2)180˚ where n is the number of angles.

Exterior angles, located outside a closed polygon, are complements of interior
angles. The advantage to be gained by observing them is their use as another
check, since the sum of the interior and exterior angles at any station must
total 360˚. The sum of the exterior angles for a closed polygon traverse must
equal (n+2)180˚.

a. Angles to the right b. Angles to the left

Figure 3.2 Closed Loop (Polygon) Traverse

Deflection angles (see Figure 3.3) are observed from an extension of the back
line to the forward station. They are used principally on the long linear
alignments of route surveys.

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As illustrated in the figure, deflection
angles may be observed to the right
(clockwise) or to the left (anticlockwise)
depending on the direction of the route.
Clockwise angles are considered plus and
anticlockwise ones minus, as shown in the
figure. Deflection angles are always smaller
than 180˚ and appending an R or L to the
numerical value identifies the direction of
turning.

Figure 3.3 Deflection Angle

3.4 Direction of a Line

The direction of a line is defined by the horizontal angle between the line and
an arbitrarily chosen reference line called a meridian. Different meridians are
used for specifying directions including (a) geodetic (also often called true), (b)
astronomic, (c) magnetic, (d) grid, and (e) assumed.

3.5 Azimuth

Azimuths are horizontal angles observed clockwise from any reference
meridian. In plane surveying, azimuths are generally observed from north, but
astronomers and the military have used south as the reference direction.
Examples of azimuths observed from north are shown in Figure 3.4.

Figure 3.4 Example of Azimuth
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As illustrated, they can range from 0° to 360° in value. Hence, the azimuth of
OA is 70°, of OB is 145°, of OC is 235°, and of OD is 330°.

A line‘s forward direction can be given by its forward azimuth and its reverse
direction by its back azimuth. In plane surveying, forward azimuths are
converted to back azimuths, and vice versa, by adding or subtracting 180°. For
example, if the azimuth of OA is 70°, the azimuth of AO is 70°+180° = 250°.

3.6 Bearing

Bearings are another system for designating directions of lines. The bearing of
a line is defined as the acute horizontal angle between a reference meridian
and the line. The angle is observed from either the north or south toward the
east or west, to give a reading smaller than 90°. The letter N or S preceding the
angle, and E or W following it shows the proper quadrant. Thus, a properly
expressed bearing includes quadrant letters and an angular value. An example
is N80°E. Figure 3.5 shows the bearing of different lines.

Figure 3.5 Bearing of Lines

In the figure above, all bearings in quadrant NOE are measured clockwise from
the meridian. Thus the bearing of line OA is N70°E. All bearings in quadrant
SOE are anticlockwise from the meridian, so OB is S35°E.

3.7 Comparison of Bearing and Azimuth

Since bearings and azimuths are encountered in so many surveying
operations, the comparative summary of their properties given in Table 3.1

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should be helpful. Bearings are readily computed from azimuths by noting the
quadrant in which the azimuth falls, then converting as shown in the table.

Table 3.1 Comparison of Bearing and Azimuth

3.8 The Compass and the Earth Magnetic Field

3.8 Introduction

The branch of surveying in which directions of survey lines are determined by
a compass and their lengths by chaining or taping directly on the surface of
the earth is called compass surveying. Method of chain surveying is preferred
to if the area to be surveyed is small in extent and higher accuracy is aimed at.
On the other hand, if the area is comparatively large, with undulations,

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compass surveying is adopted. Before recommending the compass survey for
any area, it must be ascertained that area is not magnetically disturbed.

3.8.2 Surveying Compass

Figure 3.6 shows the surveyor’s compass and the prismatic compass. The
instrument consists of a metal baseplate (A) with two sight vanes (B) at the
ends. The compass box (C) and two small level vials (D) are mounted on the
baseplate, the level vials being perpendicular to each other. When the compass
was set up and the bubbles in the vials centred, the compass box was
horizontal and ready for use.

b. Surveyor Compass
a. Surveyor Compass

d. Prismatic Compass
c. Compass Box

Figure 3.6 Types of Surveying Compasses

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3.8.3 Magnetic Declination

Magnetic declination is the horizontal angle observed from the geodetic
meridian to the magnetic meridian. An east declination exists if the magnetic
meridian is east of geodetic north; a west declination occurs if it is west of
geodetic north. East declinations are considered positive and west declinations
negative. The relationship between geodetic north, magnetic north, and
magnetic declination is given by the expression

geodetic azimuth = magnetic azimuth + magnetic declination eqn. 3.1

Since the magnetic pole positions are constantly changing, magnetic
declinations at all locations also undergo continual changes. One way of
determining the magnetic declination at a point is to interpolate it from an
isogonic chart. An isogonic chart shows magnetic declinations in a certain
region for a specific epoch of time. Lines on such maps connecting points that
have the same declination are called isogonic lines.

Examples

Assume the magnetic bearing of a property line was recorded as S43˚30'E in
1862. At that time the magnetic declination at the survey location was 3˚15'W.
What geodetic bearing is needed for a subdivision property plan?

3.8.4 Local Attraction

This is a local anomaly caused from such things as power lines, railroad
tracks, metallic belt buckles, and so on that affect the direction a compass
needle points at any location. As an example, when set up beside a streetcar
with overhead power lines, the compass needle would swing toward the car as
it approached, then follow it until it is out of effective range Local attraction is
present if the forward and back bearings of a line differ by more than the
normal observation errors. Consider the following compass bearings read on a
series of lines as shown in Table 3.4.

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Table 3.2 Compass Bearing of a Series Lines

Line Bearing
AB N24˚15'W
BC N76˚40'W
CD N60˚00'E
DE N88˚35'E
BA S24˚10'E
CB S76˚40'E
DC S61˚15'W
ED S87˚25'W

Forward-bearing AB and back-bearing BA agree reasonably well, indicating
that little or no local attraction exists at A or B. The same is true for point C.
However, the bearings at D differ from corresponding bearings taken at C and
E by roughly to the west of north. Local attraction therefore exists at point D
and deflects the compass needle by approximately to the west of north. It is
evident that to detect local attraction, successive stations on a compass
traverse have to be occupied and forward and back bearings read.

3.9 The Theodolite

3.9.1 Introduction

The theodolite is a very useful instrument for engineers. It is used primarily for
measuring horizontal and vertical angles. However, the instrument can be
used for other purposes like (i) Prolonging a line, (ii) Measuring distances
indirectly and (iii) Levelling. Theodolites these days are all transit theodolites.
Here the line of sight can be rotated in a vertical plane through 180˚ about its
horizontal axis. This is known as transitting and hence the name "transit".

There are basically two types of theodolite, the optical mechanical type and the
electronic digital type, both of which may be capable of reading directly to 1',
20", 1" or 0.1" of arc, depending upon the precision of the instrument. Figure
3.9 shows the main part of a theodolite

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Figure 3.7 Main Parts of a Theodolite

The telescope is of measuring type, has an object glass, a diaphragm and an
eyepiece and is internal focussing. When elevated or depressed, it rotates
about its transverse horizontal axis (trunnion axis) which is placed at right
angles to the line of collimation and the vertical circle which is connected to
the telescope rotates with it.

The vertical circle is rigidly connected to the transverse axis of the telescope
and moves as the telescope is raised or depressed. The vertical circle is
graduated in degrees with graduations.

3.9.2 Basic Definitions

Line of collimation: It is an imaginary line joining the intersection of the cross
hairs with the optical centre of the objective.

Face left condition: If the vertical circle is on the left side of the observer it is
known as face left condition. Since normally the vertical circle is on the left
side it is also known as normal condition.

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Face right condition: If the vertical circle is on the right side of the observer,
the theodolite is in the face right condition. The telescope is then in the
inverted form and hence the condition is known reverse condition.

Changing face: It is the operation of changing face left to face right and vice
versa.

Double sighting or double centring: It is the operation of measuring an angle
twice, once with telescope in the normal condition and another in the reverse
condition.

Plunging the telescope: This is also known as transitting or reversing. It is the
process of rotating the telescope through 180˚ in the vertical plane. By this
process the direction of objective and eyepiece ends are reversed.

Swinging the telescope: It is the process of turning the telescope clockwise or
anticlockwise about its vertical axis. Clockwise rotation is called swing right
and anticlockwise rotation is called swing left.

3.9.3 Instrumental Errors

In order to achieve reliable measurement of the horizontal and vertical angles,
one must use an instrument that has been properly adjusted and adopt the
correct field procedure.

In a properly adjusted instrument, the following geometrical relationships
should be maintained

1. The plane of the horizontal circle should be normal to the vertical axis of
rotation.
2. The plane of the vertical circle should be normal to the horizontal transit
axis.
3. The vertical axis of rotation should pass through the point from which
the graduations of the horizontal circle radiate.
4. The transit axis of rotation should pass through the point from which
the graduations of the vertical circle radiate.
5. The principal tangent to the plate bubble should be normal to the main
axis of rotation.

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6. The line