Download - Site Surveying Leveling
SCHOOL OF ARCHITECTURE, BUILDING AND
DESIGN
BACHELOR OF QUANTITY SURVEYING (HONOURS)
SITE SURVEYING [QSB 60103]
FIELD WORK 1 REPORT
LEVELLING
DARREN TAN QUAN WEN 0322662
YEAP PHAY SHIAN 0322243
LEE XIN YING 0322432
MICHELLE TUNG MAN KAYE 0324175
LOH MUN TONG 0323680
LECTURER: MR. CHAI VOON CHIET
SUBMISSION DATE: 8th DECEMBER 2016
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TABLE OF CONTENT
NO. TOPIC PAGE
1. INTRODUCTION TO LEVELLING
1.1 Definition of Levelling
1.2 Uses of Levelling
1.3 Definition of terms used in Levelling
1.4 Methods of Levelling
2 - 9
2. OBJECTIVES 10
3. APPARATUS USED 11 - 13
4. LEVELLING FIELDWORK 14
5. FIELD DATA 15 - 16
6. ADJUSTED FIELD DATA 17 - 18
7 TWO PEG TEST 19
8. DISCUSSION 20
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INTRODUCTION TO LEVELLING
1.1 DEFINITION OF LEVELLING
Levelling is the process of finding the relative height of different points on, above, or below the
surface.
It is the measurement of geodetic height using an optical levelling instrument and a level staff or
rod having a numbered scale.
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1.2 USES OF LEVELLING
Levelling acts as a referencing point to find out and make sure the vertical stability of the points
with respect to reference point or known as the benchmarks in its immediate vicinity.
It can be the connection to GPS reference points by connecting the points to reference stations
in global coordinate system via GPS to find out its regional stability and to separate sea level
rise from vertical crustal motion.
The point of mean sea level is connected to the national levelling network to define vertical
datum for national surveying and mapping, the connection to the network will allow all points to
be connected to each other and provides information on spatial variations in mean sea level.
Levelling can be used to design highways, railroads, canals, sewers, water supply systems, to
lay out construction projects according to planned elevations, to calculate volume of earthworks
and other materials and to investigate drainage characteristics of an area.
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1.3 DEFINITION OF TERMS USED IN LEVELLING
Level surface: A surface in which any point is perpendicular to the direction of the force
towards the pull of gravity. It can also refer to any surface which is parallel to the mean
spheroidal surface of the earth.
Level line: A line lying on a level surface in which normal to the plumb line at all points.
Level datum: An arbitrary level surface which refer to elevations. There are two types of datum,
the ordnance datum and an assumed datum.
● Ordnance datum (O.D.): Heights that are shown on Ordnance Survey (O.S.) referring
to the maps. Datum line is the mean sea level (MSL).
● Assumed datum: Established by giving a benchmark an assumed value to which all
heights and levels in the local area will be reduced.
Horizontal plane: A plane point that is tangent to the level surface at that particular point in
which perpendicular to the plumb line through that point.
Horizontal line: A straight line that is tangent to a point at a level line in which perpendicular to
the plumb line.
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Vertical plane: A plane containing a vertical line.
Vertical line: Commonly defined by a plumb line. It is a line normal to a point at the level line.
Elevation: Vertical distance above or below an arbitrarily assumed level surface or datum of a
point on or near the surface of the earth.
Mean sea level (MSL): The average height of the sea for all stages of the tides. It is derived by
averaging the hourly tide heights over a long period of 19 years at any particular place.
Bench mark (BM): A definite and permanent accessible point of known height above a datum
to which the height of other points can be referred.
Temporary benchmark (T.B.M.): A bench-mark set up by the surveyor himself for his own use
for a particular task.
Reduced level: Height or depth of any point above or below any datum. It is denoted as R.L.
Line of collimation: Intersection line 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: Vertical distance of collimation with respect to datum.
Back-sight (B.S.): First staff reading taken after the set-up of instrument. It is a staff reading
taken at a known elevation.
Foresight (F.S.): Last staff reading taken denoting the shifting of the instrument.
Intermediate sight (I.S.): Staff reading taken on a point in which elevation is to be determined.
It is the staff reading between back-sight and foresight.
Change point (C.P.): An arbitrary point which enables the levelling to continue from a new
instrument position. It is also denoted as turning point (T.P.).
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1.4 METHODS OF LEVELLING
Height of Collimation Method
This method consists of discovering the elevation of the plane of collimation (H.I.) for every set
up of the instrument and to obtain the reduced level of point to with reference to the respective
plane of collimation.
It is generally used in profile levelling and in setting out levels for constructional work.
Rules of booking
a. The survey starts from a known level which is the Ordnance Bench Mark (OBM) or a
Temporary Bench Mark (TBM). This is to obtain the first reading from the instrument
position which is the back sight.
b. The height of collimation is the addition of the back sight and reduced level, entered on
the same line.
c. An intermediate sight will occur between the back sight and foresight.
d. Foresight is the last reading from an instrument position.
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e. In order to get the next reduced level, the foresight or intermediate sight is subtracted
from the height of collimation, entered on the same line as the foresight or intermediate
sight.
f. When the instrument is moved to a new position, the height of collimation change.
g. A new height of collimation is given entered on the same line for every back sight.
h. All readings referring to the same point on the ground are entered on the same line.
In brief,
Heights of collimation (H. of C.) = Reduced Level (R.L.) + Back-sight (B.S.)
Reduced Level (R.L.) = Heights of collimation (H. of C.) - Foresight (F.S.)
Reduced Level (R.L.) = Heights of collimation (H. of C.) - Intermediate sight (I.S.)
Calculation checks,
Simple Check
Σ F.S. - Σ B.S. = First R.L. - Last R.L.
Full check
Σ I.S. + Σ F.S. + Σ (R.L. except the first) = Σ (each H. of C. x number of applications)
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Rise and Fall Method
This method consists in finding the difference of level between consecutive points by comparing
each point after the first with that immediately preceding it. The reduced level (R.L.) is found by
adding rise of subtracting fall to or from the preceding reduced level itself (R.L.).
It is commonly used for differential levelling.
Rules of booking
a. The first and last reduced level is on an Ordnance Bench Mark (OBM) or a Temporary
Bench Mark (TBM)
b. There is a rise when the first staff reading is larger than the second staff reading in any
consecutive pair of staff readings.
c. There is a fall when the first staff reading is less than the second staff reading in any
consecutive pair of staff readings.
d. In order to obtain the new reduced level, add the rise and subtract the fall from the
preceding reduced level entering on the same line as the rise or fall.
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In brief,
Fall (F) = Foresight (F.S.) – Back-sight (B.S.)
Fall (F) = Intermediate sight (I.S.) – Back-sight (B.S.)
Rise (R) = Back-sight (B.S.) - Foresight (F.S.)
Reduced Level (R.L.) = Precede Reduced Level + Rise (R)
Reduced Level (R.L.) = Precede Reduced Level - Fall (F)
Calculation checks,
Σ B.S. - Σ F.S. = Σ R - Σ F = Last R.L. - First R.L.
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OBJECTIVES
To give meaning as a basis for the proper knowledge of levelling.
To understand the ways of using levelling.
To determine the elevations of given points with respect to an assumed reference line
called datum.
To establish point at required elevation respect to datum
To measure the difference in height (ΔH) between two points, A and B, where
vertical rods are set up at each of these two points and a level between them.
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APPARATUS USED
Auto Level
An auto level, also known as a dumpy level or builder’s auto level is a professional levelling tool
used by contractors, builders, land surveying professionals, or the engineer who demands
accurate levelling every time. It is an optical measuring device used to establish a horizontal
plane. Auto level sets up fast, it is easy to use, and save time and money on every jobs.
The auto level has a compensator mechanism that uses a combination of fixed prisms or
mirrors and a moving prism suspended on a pendulum to give a horizontal reference. When
correctly set up the compensator will ensure that the ray of light through the centre of the
reticule is exactly horizontal.
Plumb bob
A plumb bob or a plummet is a weight with a pointed tip on the bottom that is suspended from a
string and used as a vertical reference line. This instrument used in surveying to sight a point on
the ground that is not readily visible. They are used to set the instrument exactly over a fixed
datum marker, prior to taking fresh readings.
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Tripod
To set up the tripod so that it is secure, the head is approximately level and the instrument
telescope will be at the eye level.
Each leg of a tripod is adjustable for length. The legs are locked by a lever clamp (left) or screw
(right). Once the legs have been set to the correct length it is important that the locking lever or
screw is tight.
Tripod Head has a polished level surface for the instrument to stand on. The tripod screw is
captive and mounted on a movable bracket to allow the instrument to be centred over a station
if necessary.
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Levelling Staff
The levelling staff is simply a large ruler, available in lengths of 3, 4, or 5 metres and usually
made of aluminium with telescopic sections. The levelling staff is sectional so that can be
adjusted in length to allow for easy storage and transport. The sections have locking buttons to
ensure accurate length is maintained.
The “E” pattern is designed to make it easy to read a small section of the scale when see
through a telescope.
Staff bubble
The staff bubble is an attachment for the levelling staff. It has to ensure that the bubble is in the
centre of the black circle which makes sure that the levelling staff is vertical and not tilted.
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LEVELLING FIELDWORK
Location: Taylor’s University Lakeside campus staff car park
Source: https://times.taylors.edu.my/pluginfile.php/2423365/mod_resource/content/1/Field-Work%20Assignment1.pdf
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FIELD DATA
Height of Collimation Method
BS IS FS HEIGHT OF COLLIMATION
REDUCED LEVEL
1.338 101.338 100.000
1.367 3.668 99.037 97.670
1.310 97.727
1.259 1.352 98.944 97.685
1.516 1.381 99.079 97.563
1.320 1.305 99.094 97.774
1.258 1.258 99.094 97.836
1.240 1.482 98.852 97.612
1.244 1.128 98.968 97.724
3.572 1.252 101.288 97.716
1.289 99.999
1.280 100.008
14.114 14.106 100.008
14.106 100.000
0.008 0.008
Acceptance Mis-closure: 12+/- √k
k = Number of set ups
12+/-√9 = +/- 36mm
Therefore, the levelling is acceptable
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Rise and Fall Method
BS IS FS RISE FALL REDUCED LEVEL
1.338 100.000
1.367 3.668 2.330 97.670
1.310 0.057 97.727
1.259 1.352 0.042 97.685
1.516 1.381 0.122 97.563
1.320 1.305 0.211 97.774
1.258 1.258 0.062 97.836
1.240 1.482 0.224 97.612
1.244 1.128 0.112 97.724
3.572 1.252 0.008 97.716
1.289 2.283 99.999
1.280 0.009 100.008
14.114 14.106 2.734 2.726 100.008
14.106 2.726 100.000
0.008 0.008 0.008
Acceptance Mis-closure: 12+/- √k
k = Number of set ups
12+/-√9 = +/- 36mm
Therefore, the levelling is acceptable
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ADJUSTED FIELD DATA
BS IS FS HEIGHT OF COLLIMATION
REDUCED LEVEL
ADJUSTMENT FINAL REDUCED
LEVEL
1.338 101.338 100.000 100.000
1.367 3.668 99.037 97.670 -0.0009 97.669
1.310 97.727 -0.0018 97.668
1.259 1.352 98.944 97.685 -0.0018 97.683
1.516 1.381 99.079 97.563 -0.0027 97.560
1.320 1.305 99.094 97.774 -0.0036 97.770
1.258 1.258 99.094 97.836 -0.0045 97.832
1.240 1.482 98.852 97.612 -0.0054 97.607
1.244 1.128 98.968 97.724 -0.0063 97.718
3.572 1.252 101.288 97.716 -0.0072 97.709
1.289 99.999 -0.0080 99.991
1.280 100.008 -0.0080 100.000
14.114 14.106 100.008
14.106 100.000
0.008 0.008
Height of Collimation Method
Arith. checked
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Rise and Fall Method
BS IS FS RISE FALL REDUCED LEVEL
ADJUSTMENT FINAL REDUCED LEVEL
1.338 100.000 100.000
1.367 3.668 2.330 97.670 -0.0009 97.669
1.310 0.057 97.727 -0.0018 97.668
1.259 1.352 0.042 97.685 -0.0018 97.683
1.516 1.381 0.122 97.563 -0.0027 97.560
1.320 1.305 0.211 97.774 -0.0036 97.770
1.258 1.258 0.062 97.836 -0.0045 97.832
1.240 1.482 0.224 97.612 -0.0054 97.607
1.244 1.128 0.112 97.724 -0.0063 97.718
3.572 1.252 0.008 97.716 -0.0072 97.709
1.289 2.283 99.999 -0.0080 99.991
1.280 0.009 100.008 -0.0080 100.000
14.114 14.106 2.734 2.726 100.008
14.106 2.726 100.000
0.008 0.008 0.008 Arith. checked
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TWO PEG TEST
Solution:
Instrument midway between point A and B:
RLA1 = 1.256
RLB1 = 1.258
True difference in level BA - 1.258 – 1.256 = 0.002m
From 1m away from A point:
RLA2 = 1.261
RLB2 = 1.261
Apparent difference in level BA - 1.261 – 1.261 = 0m
Since the apparent difference is less than the true difference in level, the line of
collimation is depressed by
0.002m – 0m = 0.002m over 30m
Angle of depression = tan-1 (0.002/30)
= 00’00’14”
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DISCUSSION
In this fieldwork we were required to measure the reduced level of 10 locations around
the Staff Parking at Taylor’s University Lakeside Campus. We started out by assuming a R.L of
100.000m AOD at a lamp post labelled BM 101. Aside from this assumed R.L, we need to
calculate the R.L of the other 10 other locations that was given to us, so we need to take our
equipment around. Making sure to mark down each R.L.
One of the difficulties we faced was trying to make sure the bubble was place in the
middle perfectly. So there will not be any errors. As we were taking down the measurement, we
did not have many intermediate sights, only 2 and most of it is back-sight and foresight.
Once the readings were taken, we used one method to calculate the reduced level,
which is Collimation Method. We arrived at a mis-closure of 0.008m, which was in the
acceptable error range. We then distributed the error to arrive at our final reduced level
readings.
Overall, this is a very new experience for us handling surveying instruments. It really
helps us understand more about the condition as well as widen our horizon. This was a really
fun and interesting assignment.