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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
SCHOOL OF ARCHITECTURE, BUILDING AND DESIGN
BACHELOR OF QUANTITY SURVEYING (HONOURS)
SITE SURVEYING (QSB60103)
Fieldwork one: Levelling
Group member:
Name Student ID
1. Wong Qin Kai 0320024
2. Lee Shze Hwa 0320053
3. Ng Huoy Miin 0319097
4. Hoi Wei Han 0323335
Lecturer: Mr. Chai Voon Chiet
Submission date: 12th July 2016
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
TABLE OF CONTENT
TITLE CONTENT PAGE NUMBER
1 Introduction to Leveling
1.1 Definition of Leveling
1.2 Definition of Terms Used in Leveling
1.3 Differential Leveling
1.4 Vertical Control Surveys
3-9
2 Outline of Apparatus
2.1 Automatic Level
2.2 Adjustable Leg-Tripod
2.3 Optical Plummet
2.4 Horizontal Bubble Level
2.5 Bar-Coded Level Rod
2.6 Plumb Bob
10-12
3 Objectives 13
4 Introduction to the site 13
5 Leveling Fieldwork
Field Data
5.1 Height of Collimation Method
14
6 Adjusted Data
6.1 Rise and Fall Method
15
7 Discussion 16
8 Conclusion 17
9 References 18
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
1.0 INTRODUCTION TO LEVELING
1.1 DEFINITION OF LEVELING.
Leveling
Leveling is defined as “an art of determining the relative height of different points on, above or
below the surface”.
Principle of Leveling
The principle of levelling is to obtain horizontal line of sight with respect to which vertical
distances of the points above or below this line of sight are found.
The objective of Leveling
The objective of levelling is to find the elevation of given point with respect to some assumed
reference line called datum and to establish point at required elevation respect to datum.
1.2 DEFINITION OF TERMS USED IN LEVELING
Level Surface
It is any surface parallel to the mean spheroidal surface of the earth. Since the earth is an oblate
spheroid, a level surface may be regarded as a curved surface, every point on which is
equidistant from the center of the earth.
Level line
It is a line lying in a level surface. It is therefore, normal to the plumb line at all points.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
Horizontal plane
A plane perpendicular to the local direction of gravity. In plane surveying, it is a plane
perpendicular to the local vertical line.
Horizontal Line
It is any line lying on the horizontal plane. It is usually a straight line tangential to the level line.
Vertical plane
It is a plane containing a vertical line.
Vertical line
It is a line normal to the level surface through that point e. g. a plumb line.
Vertical angle
Angle between two intersecting lines in a vertical plane, one of the two lines is commonly taken
as horizontal in surveying.
Datum
“It is an arbitrary level surface from which elevation of points may be referred”. In India mean
sea level is considered as datum of zero elevation it is situated at Karachi.
Mean Sea Level
It is the average height of sea for all stages of tides it is derived by averaging the hourly tide
height over a period of 19 years.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
Elevation or Reduced level
It is height or depth of any point above or below any datum. It is denoted as R.L.
Benchmark (B.M.)
It is a fixed reference point of known elevation with respect to datum.
Line of collimation
It is a line joining the intersection of cross hairs of diaphragm to the optical centre of object glass
and its continuation. It is also known as line of sight.
Height of instrument
It is the elevation of line of collimation with respect to datum.
Backsight (B.S.)
The first reading from a new instrument position.
Intermediate Sight (I.S.)
Readings between the backsight (B.S.) and foresight (F.S.)
Foresight (F.S.)
The last reading from an instrument position.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
Change Point (T.P)
It is a point on which both fore and back sight are taken.
There leveling has two type of layouts which are the rise and fall method and the height of
collimation method.
1.3 DIFFERENTIAL LEVELING
DEFINITION OF DIFFERENTIAL LEVELINGThe establishment of differences in elevation between two or more points with respect to a
datum. Normally surveyor will assign an elevation of 100.00 to the datum rather using the mean
sea level elevation.
THEORY
Add rod readings (BS) to benchmark or known turning point elevations to get the elevation of
the line of sight (HI). Subtract rod readings (FS) from the line of sight to establish elevations of
unknown points. Repeat over and over.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
SCHEMATIC
Elev + BS = HI
HI - FS = New Elevation
REDUCINGERRORS
Making certain the bubble is centered when you make a rod reading. Keeping the rod plumb
when the reading is taken. Establishing equal BS and FS reading distances. Equaling reading
distances will cancel out any error caused by the line of sight not being parallel with the axis of
the bubble tube on the Dumpy Level. Not as important with the self-leveling Automatic Levels.
Lastly, it will not always possible due to the terrain.
SUGGESTIONS FOR GOOD LEVELLING
Anchor tripod legs firmly. Checking of the bubble level before and after each reading. Taking as
little time as possible between BS and FS. Trying to keep the distance to the BS and the FS
equal. Providing the rod person with a level for the rod.
COMMONMISTAKES
Faulty reading of the rod. Not fully extending the rod for high readings. Touching the tripod
during reading. Confusion between recording BS and FS entries into the field book.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
CHECK
Page Checking. Method of checking arithmetic. The BS and FS columns are added up and their
difference should be equal to the difference between the beginning and ending elevations.
Closure Method of checking accuracy. The difference between the beginning and ending
elevations for a loop or the difference between the ending elevation and the known elevation of
the ending BM.
1.4 VERTICAL CONTROL SURVEYS
A vertical control survey determines elevation with respect to sea level. These surveys are also
used as a benchmark upon which other surveys are based and high degree of accuracy is
required. These surveys are useful for tidal boundary surveys, route surveys, construction
surveys and topographic surveys. In a vertical control system, at least two permanent
benchmarks should be used, but more may be required depending upon the needs and complexity
of the project. These projects are needed for the construction of water and sewer systems,
highways, bridges, drains, and other major town or city infrastructure. These surveys can be done
alone, but are often done in conjunction with a horizontal control survey.
1.4.1 HEIGHT OF COLLIMATION METHOD:
It consists of finding the elevation of the plane of collimation (H.I.) for every set up of the
instrument, and then obtaining the reduced level of point with reference to the respective plane of
collimation.
1. Elevation of plane of collimation for the first set of the level determined by adding back side
to R.L. of B.M.
2. The R.L. of intermediate point and first change point are then obtained by starching the staff
reading taken on respective point (IS & FS) from the elation of the plane collimation. (H.I.)
3. When the instrument is shifted to the second position a new plane collimation is set up. The
elevation of this plane is obtained by adding B.S. taken on the C.P. From the second position of
the level to the R.L. C.P. The R.L. of successive point and second C.P. are found by subtract
these staff reading from the elevation of second plane of collimation Arithmetical check.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
Sum of B.S. – sum of F.S. = last R.L. – First R.L.
This method is simple and easy.
Reduction of levels is easy.
Visualization is not necessary regarding the nature of the ground.
There is no check for intermediate sight readings.
This method is generally used where more number of readings can be taken with less
number of change points for constructional work and profile leveling.
1.4.2 RISE AND FALL METHOD:
It consists of determining the difference of elevation between consecutive points by comparing
each point after the first that immediately preceding it. The difference between their staff reading
indicates a rise fall according to the staff reading at the point. The R.L is then found adding the
rise to, or subtracting the fall from the reduced level of preceding point. The arithmetic check in
this method is as follows:
∑ BS - ∑ FS = ∑ Rise - ∑ Fall = Last RL - First RL
This method is complicated and is not easy to carry out. Reduction of levels takes more time.
Visualization is necessary regarding the nature of the ground. Complete check is there for all
readings. This method is preferable for check levelling where number of change points are more.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
2.0 OUTLINE OF APPARATUS
2.1 AUTOMATIC LEVEL
An Auto level is a Professional Leveling Tool used by Contractors, Builders, Land Surveying
Professionals, or the Engineer who demands accurate leveling every time. Auto level set up fast
and easy to use and save time and money on every job.
1. Gun sight
2. Circular level (pond bubble)
3. Levelling Screw
4. Base Plate
5. Objective Lens
6. Focusing Knob
7. Horizontal fine motion screw
8. Horizontal circle window
9. Horizontal circle setting ring
10. Reticle adjusting screw cover
11. Eyepiece
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
2.2 ADJUSTABLE-LEG TRIPOD
A tripod is a three-legged stand. Adjustable-leg tripods are the more common of the two in the
construction work especially outdoors because of generally uneven terrain. The adjustable-leg
tripod is easier to set up on uneven ground because each leg can be adjusted to exactly the height
needed to find level even on a very steep slope. The adjustable-leg tripod is also easy to transport
due to having retractable legs.
2.3 OPTICAL PLUMMET
In surveying, a device used in place of a plumb bob to center transits and theodolites over a
given point, preferred for its steadiness in strong winds.
2.4 HORIZONTAL BUBBLE LEVEL
Horizontal bubble is an instrument used to indicate the horizontal level. A slightly curved glass
tube which in incompletely filled with either spirit or alcohol.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
2.5 BAR-CODED LEVEL ROD
Bar-coded level rod can determine the relative height of the different points in the area under
survey.
2.6 PLUMB BOB
A plumb bob or a plummet is a weight usually with a pointed tip on the bottom, that is suspended
from a string and used as a vertical reference line.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
3.0 OBJECTIVES
1. To enhance students’ knowledge in leveling procedure.
2. To enable students to get hands-on experience in setting up and working with the auto-level.
3. To allow students to apply theories that had been taught in the classes in a hand-on situation such as making adjustments for each reduced levels of every single staff station in order to obtain the most accurate reduced levels.
4. To determine the error of misclosure in order to determine whether the levelling is acceptable.
4.0 INTRODUCTION TO THE SITE
We were asked to conduct a fieldwork by leveling around the staff parking of Taylor’s
University Lakeside Campus. The location of Benchmark (BM) was given with the reduce level
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
of 100.00 m at the lamp post labelled as BM 101. We were required to obtain the reduce level of
the 10 locations given as shown in the photo below.
Field Data (Height of collimation method)
Back-sight Intermediate sight
Foresight Height of collimation
Reduce level Remarks
1.250 101.250 100.000 BM1011.261 3.502 99.009 97.748 TP 1
1.175 97.834 TP 21.298 1.325 98.982 97.684 TP 31.385 1.320 99.047 97.662 TP 41.240 1.155 99.132 97.892 TP 51.245 1.285 99.092 97.847 TP 61.350 1.510 98.932 97.582 TP 71.245 1.150 99.027 97.782 TP 83.635 1.350 101.312 97.677 TP 91.320 1.300 101.332 100.012 TP 10
1.320 100.012 BM10115.229 15.217 100.012-15.217 -100.0000.012 0.012
Error of distribution
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Arithmetical check:
B.S. - F.S. = Last R.L. - First R.L.
= 15.229 - 15.217 = 100.012 - 100.000
= 0.012
BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
= (100.012-100.000) /10
= (0.012) /10
= 0.0012
Back-sight Intermediate sight
Foresight Height of collimation
Reduce level Adjustment Adjusted RL
Remarks
1.250 101.250 100.000 -0.000 100.000 BM1011.261 3.502 99.009 97.748 -0.0012 97.746 TP 1
1.175 97.834 -0.0012 97.832 TP 21.298 1.325 98.982 97.684 -0.0024 97.682 TP 31.385 1.320 99.047 97.662 -0.0036 97.658 TP 41.240 1.155 99.132 97.892 -0.0048 97.887 TP 51.245 1.285 99.092 97.847 -0.0060 97.841 TP 61.350 1.510 98.932 97.582 -0.0072 97.578 TP 71.245 1.150 99.027 97.782 -0.0084 97.774 TP 83.635 1.350 101.312 97.677 -0.0096 97.667 TP 91.320 1.300 101.332 100.012 -0.0108 100.001 TP 10
1.320 100.012 -0.012 100.000 BM10115.229 15.217 100.012-15.217 -100.0000.012 0.012
Field Data (Rise and fall method)
Back-sight Intermediate sight
Foresight Rise Fall Reduce level Remarks
1.250 100.000 BM1011.261 3.502 2.252 97.748 TP 1
1.175 0.086 97.834 TP 21.298 1.325 0.150 97.684 TP 31.385 1.320 0.022 97.662 TP 41.240 1.155 0.230 97.892 TP 51.245 1.285 0.045 97.847 TP 61.350 1.510 0.265 97.582 TP 71.245 1.150 0.200 97.782 TP 83.635 1.350 0.105 97.677 TP 91.320 1.300 2.335 100.012 TP 10
1.320 0.000 100.012 BM10115.229 15.217 2.851 2.839 100.012-15.217 -2.839 -100.0000.012 0.012 0.012
Error of distribution
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Arithmetical check:
B.S. - F.S. = Rise - Fall = Last R.L. - First R.L.
15.229 - 15.217 = 2.851 - 2.839 = 100.012 - 100.000
= 0.012
BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
= (100.012-100.000) /10
= (0.012) /10
= 0.0012
Back-sight Intermediate sight
Foresight Rise Fall Height of collimation
Reduce level
Adjustment Adjusted RL
Remarks
1.250 101.250 100.000 -0.000 100.000 BM1011.261 3.502 2.252 99.009 97.748 -0.0012 97.746 TP 1
1.175 0.086 97.834 -0.0012 97.832 TP 21.298 1.325 0.150 98.982 97.684 -0.0024 97.682 TP 31.385 1.320 0.022 99.047 97.662 -0.0036 97.658 TP 41.240 1.155 0.230 99.132 97.892 -0.0048 97.887 TP 51.245 1.285 0.045 99.092 97.847 -0.0060 97.841 TP 61.350 1.510 0.265 98.932 97.582 -0.0072 97.578 TP 71.245 1.150 0.200 99.027 97.782 -0.0084 97.774 TP 83.635 1.350 0.105 101.312 97.677 -0.0096 97.667 TP 91.320 1.300 2.335 101.332 100.012 -0.0108 100.001 TP 10
1.320 0.000 100.012 -0.012 100.000 BM10115.229 15.217 2.851 2.839 100.012-15.217 -2.839 -100.0000.012 0.012 0.012
7.0 DISCUSSION
In this leveling fieldwork, we were required to measure the reduced level of the 11 locations
given (including Benchmark) around the staff parking area at Taylor’s University Lakeside
Campus. Before start the fieldwork, we had learnt to set up the leveling instrument and the
precautions that we needed to be aware to reduce the error. Benchmark (BM) has been given
with 100.00 m Reduce level (RL) at a lamp post labelled BM 101. After setup the instrument and
placed bar-coded level rod, the levelling process began by observed and recorded the backsight
(BS) at BM 1 and foresight (FS) at point A. The height of the instrument will remain the same
for each observation made until the instrument is moved to a new location. Then, we shifted the
location of the auto level and obtained BS of point A, intermediate sight (IS) of point B and FS
of point C. Since we could not obtain the reading of bar-coded level rod at point D, we were
forced to shift the auto level. The process was repeated by shifting the auto level in order to
obtain the BS and FS. At last, we were required went back to BM 1 and obtained FS to the
calculate the error of misclosure.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
In order to check the accuracy of our leveling, we used the formula of ±12√(k) which k is the
total number of setup to obtain the maximum allowable error of closure. Unfortunately, our first
obtained leveling data was not acceptable and we were forced to redo the leveling. We had
decided to have more setup to reduce the error and end up we had total 10 set up. The error of
enclosure which is 0.012 m is less than the maximum allowable error of closure which is 0.038
m. Hence, our second leveling was acceptable.
We were decided to use both height of collimation method and rise and fall method to
calculate the RL of each point. Since the final RL is more than initial RL, the reduce level must
be adjusted by distribute the error against the number of setup. Therefore, the reduce level was
adjusted by subtracting to each set up. Lastly, we were required to arrange and convert the
leveling data and the adjusted the reduce level to computer in order to produce a fieldwork
report.
8.0 CONCLUSION
Throughout this fieldwork, we were appreciated to have this opportunity to learn the leveling
procedure and use the specialized site surveying apparatus. For example, automatic level,
adjustable-leg tripod, optical plummet, horizontal bubble level, bar-coded level rod and plump
bob. Besides, we learnt the way to calculate the reduced level by using height of collimation
method and rise and fall method whilst we also learnt to adjust the reduce level. Due to the first
leveling data was not acceptable, we had put more precaution on the leveling process to avoid
error such as ensure the instrument always in horizontal level by checking the bubble, double
check the reading that taken and ensure the plumb bob was perfectly centered over the peg.
It was a great experience for us to understand the scope of work of a site surveyor. A site
surveyor locates the buildings, roads and utilities for real estate develops and was responsible to
measure and mark their locations on the maps by using mathematics, specialized technology and
equipment.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
As a future Quantity Surveyor, it helps us to know more about the site by comprehend the site
surveying knowledge. Overall, we were enjoyed the fieldwork and special thanks to our lecturer,
Mr. Chai by teaching us how to conduct a leveling fieldwork.
9.0 REFERENCES
1.4.2 Rise and Fall Method
"How To Use Auto Levels". Newenglandlaser.com. N.p., 2016. Web. 4 July 2016. From
http://newenglandlaser.com/index.php?n=how_to_use_auto_levels
2.1 AUTOMATIC LEVEL
"Automatic Levels". EngineerSupply. N.p., 2016. Web. 4 July 2016.
From http://www.engineersupply.com/automatic-levels.aspx
2.2 ADJUSTABLE-LEG TRIPOD
"What Is A Tripod? How Do Tripods For Laser Levels Work? | How To Use Laser Level With
Tripod | Laser Levels | Johnson Level & Tool Mfg Company". Johnsonlevel.com. N.p., 2016.
Web. 4 July 2016.
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BQS MARCH INTAKE 2016 │FIELDWORK ONE │LEVELLING
From http://www.johnsonlevel.com/News/WhatisaTripodHowdoTripods
2.3 OPTICAL PLUMMET
"What Is Optical Plummet? Definition And Meaning". Dictionaryofconstruction.com. N.p.,
2016. Web. 4 July 2016.
From http://www.dictionaryofconstruction.com/definition/optical-plummet.html
8. CONCLUSION
"What Is A Land Surveyor; Find Out What Surveying Is All About And What It's Like To Be In
The Surveying Industry | A Life Without Limits". Alifewithoutlimits.com.au. N.p., 2016. Web. 4
July 2016.
From http://www.alifewithoutlimits.com.au/about-surveying/
"What Are The Duties Of A Land Surveyor?". Work.chron.com. N.p., 2016. Web. 4 July 2016.
From http://work.chron.com/duties-land-surveyor-12939.html
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