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Engineering, Technology & Applied Science Research Vol. 13, No. 1, 2023, 9913-9918 9913 
 

www.etasr.com El-Ashmawy: An Efficient Methodology for Detecting the Vertical Movement of Structures  

 

An Efficient Methodology for Detecting the 
Vertical Movement of Structures  

 

Khalid L. A. El-Ashmawy 

Department of Civil Engineering, College of Engineering and Islamic Architecture  
Umm Al-Qura University, Makkah, Saudi Arabia 
klashmawy@uqu.edu.sa 
(corresponding author)  
 

Received: 2 November 2022 | Revised: 16 November 2022 | Accepted: 21 November 2022 

 

ABSTRACT 

Details regarding the public safety of engineering structures can be gleaned from measurements and 
monitoring. The development of a methodology for monitoring and analyzing structures' vertical 
displacement is explained in this paper. The developed methodology aims to add a new dimension to 
geometric leveling, and leveling routing, by applying a least squares solution for level network adjustment 
and performing statistical analysis to assess the change in vertical displacement. To monitor and analyze 
the vertical deformation of a building in Cairo, Egypt, the proposed methodology was utilized. Twenty 
monitoring points, five auxiliary points, and three local reference stations were utilized. All the 
measurements were taken with a geodetic invar staff and an automatic level with an attachment of a 
parallel plate micrometer. The observations were made for an interval of 81 months. The least squares 
adjustment technique was applied to obtain the adjusted levels and observations and to generate the 
required statistical data. The results of the subsequent epochs were compared to the results of the first 
epoch to determine the vertical movement of the monitoring points for each epoch. In addition, the 
significance of the present displacement was ascertained by comparing the values of vertical displacement 
to the determined 95% corresponding confidence intervals. The findings demonstrated that the building 
remained stable throughout the monitoring period. The case study demonstrates how effectively geometric 
leveling with least square adjustment can be used to monitor the vertical displacement of structures. 

Keywords-stability and safety of engineering structures; geometric leveling; vertical displacement 
monitoring; least squares adjustment; accuracy analysis 

I. INTRODUCTION  

The aim of measuring a structure's movement is to decide 
whether the structure is safe and stable. Deformation can be 
subjected to more analysis to determine whether it is caused by 
seasonal factors, daily variations, or other factors and then 
utilize the data to estimate how the structure will move in the 
future [1-5]. This movement must be identified for the purposes 
of safety studies and the prevention of future disasters. 
Deformation monitoring has the advantages of improving the 
design process of structures for use in the future and increasing 
safety by lowering the possibility of structural damage [6]. It is 
a crucial risk management tool. Presently, there are many 
techniques for deformation monitoring. Modern techniques 
often use geometric leveling and total stations for three-
dimensional (3D) control [7]. The above-mentioned techniques 
can be used in conjunction with a Terrestrial Laser Scanner 
(TLS) system [8-12] or Portable Digital Photogrammetric 
Stations (DPSs) [13-15]. In particular, TLS has evolved into a 
crucial tool for working with historical structures, supplying a 
point cloud that quickly generates a three-dimension model of a 
monument [8]. However, the majority of surveyors do not have 
access to the specialized equipment required by these remote 

sensing technologies. It is costly to purchase or rent this 
equipment, and it could cost even more to train or hire 
employees who can manage and model point cloud data [9, 
10]. A TLS system's data acquisition capacity also makes 
model creation challenging [10, 11]. 

Numerous software systems can help with this, but they 
consume time and computing resources and require an 
additional instrument that must be purchased or hired. As a 
result, these methods are severely constrained and can only be 
used for architectural heritage inspection [12, 16], where 
resources and budgets are significantly available. In addition, 
these methods have other issues, including the accuracy of the 
measurements they produce [17] despite the cost and 
complexity issues. Potential dimensional errors in the model 
can be caused by issues with close-range imaging [18], as well 
as variations in temperature and humidity [19], the reflectivity 
of various materials and colors, and the effects of incidence 
angle [20].  

Comparing to direct measurements, significant errors in 
measuring vertical deformations can happen based on the 
above-mentioned conditions, sometimes exceeding one 
centimeter in magnitude [21, 22]. This emphasizes the 



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www.etasr.com El-Ashmawy: An Efficient Methodology for Detecting the Vertical Movement of Structures  

 

significance of evaluation techniques that allow calibrating 
laser scanners, particularly as high-precision surveys 
development in architectural heritage sites. Typical tests like 
deformation monitoring should be checked using direct 
measurement methods [12]. 

To overcome some of the issues listed above, this paper 
aims to:  

 develop a cost-effective methodology based on a 
mathematical model for determining the accurate levels 
from measurements at individual monitoring points,  

 adjust redundant measurements and get their precision 
using the least squares solution,  

 develop software based on the derived mathematical model 
and the least squares solution for determining the adjusted 
levels and required statistical data of deformation points, 
and  

 use the developed methodology for detecting the vertical 
displacement of a building as a case study at a particular 
time interval. 

II. THE PROPOSED METHODOLOGY 

A. Development of the Mathematical Model 

Leveling is the method of measuring vertical distances, 
either directly or indirectly, to determine elevations. There are 
two approaches: geometric and trigonometric leveling [23]. 
Geometric leveling is more accurate, the required surveying 
instruments are more cost-effective, and the work in the field 
and office is easier. In geometric leveling, the difference in 
levels between two points can be obtained by taking the 
readings of the staffs, or rulers, placed on the points. A leveling 
instrument is used to measure the readings. The elevations of 
all points can be determined by knowing at least one point's 
elevation and the level differences between points. To apply the 
method of least squares in leveling adjustments, an observation 
equation is first written for any elevation difference [23]. 
Figure 1 illustrates the geometrical relationship for the 
elevation difference observed between two stations, A and B. 
The equation is written as: 

hAB hAB B Av h h        (1) 

which can be rewritten as: 

hAB B A hABv h h         (2) 

The observation equation (2) gives the relation between the 
unknown elevations of any two stations, A and B, the 
differential levelling observation 

hAB
  and its residual. This 

equation is essential in applying least squares adjustments of 
level nets. Equation (2) is linear and can be written directly in 
the form [24]: 

.V B         (3) 

where Δ is the vector to the current values set for the unknowns 
(elevations of the deformation points) in the iterative solution, 
B is the matrix of the partial derivatives of (2) in relation to the 
unknowns, V is the vector of residuals, i.e. the correction vector 

to the observations (height difference), and ε is the vector of 
discrepancies. 

The solution of (3) using least squares method is [23,24]: 

Δ = Ν
-1

.C     (4) 

where: 

. .

. .

t

t

N B W B

C B W 

 


 
     (5) 

The variance of unit weight is obtained by: 

2ˆ . . / ( )tV W V N U       (6) 

where 2ˆ  is the variance of unit weight, N is the number of 
observations, W is the weight matrix observations, U is the 
number of unknowns and equals to the number of deformation 
points, and (N-U) present the degrees of freedom. 

 

 
Fig. 1.  Geometric depiction of the proposed model. 

B. Developing the Necessary Software 

The software for determining the adjusted level and desired 
statistical data for each deformation point in every loop is being 
developed as part of the current research. The least squares 
method, as explained above, is used to determine the output of 
the developed software, which makes use of the data in the 
form of level differences and distances between network points 
in addition to the known levels of the benchmark(s). The 
variance of unit weight, adjusted levels of stations and their 
standard deviations (optional), residuals of observations, 
corrected observations, and their cofactor matrix (optional), 
and statistical data for gross error detection (optional) are all 
included in the software's ASCII file output. The software 
provides flexibility in level network adjustment as follows: 

 Any number and distribution of network points is 
acceptable. 

 The editing of input data specifications has remained 
flexible for practical reasons. If the input formats are 
consistent, they can be accepted. 

 The point-numbering is another important practical feature. 
Point-numbering is not restricted in any way by the 
software. The point-numbering is easy and almost natural. 



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www.etasr.com El-Ashmawy: An Efficient Methodology for Detecting the Vertical Movement of Structures  

 

 Weighting observations is possible. From a theoretical 
standpoint, it is desirable to weight the observations 
because it greatly aids in the detection of gross errors. 

 Determination of the necessary initial levels for unknown 
points in order to initiate the iterative process.  

 An iterative least-squares solution that can show the results 
of each iteration or the final iteration. 

The software makes use of effective methods like Data 
Structuring [25, 26], Random File Access, and Dynamic 
Memory Allocations [27] for the purpose of automatically 
processing and representing the data and the results. The 
software was created with window-driven user interfaces in 
mind to make it easier to use [28]. 

C. Classification of Leveling Points 

Three categories of points are proposed in the leveling line: 
i) monitoring points, ii) reference or benchmark points, and iii) 
auxiliary points. The monitoring points are selected to be 
placed on the building's exterior walls and required interior 
walls. To ensure that each building's wall is stable, the 
monitoring points are strategically placed. In order to 
determine only relative displacements, the reference points can 
be situated in the controlled area and undergo displacement. 
Absolute displacements can be obtained if the reference points 
are attached to solid foundation or other stationary structures 
outside that area. Even though leveling lines only require one 
reference point, experience suggests placing at least 3 of them 
in order to recognize unstable reference points. In order to 
ensure that they are unaffected by the building's movements, 
the reference points need to be positioned at a safe distance 
from it. Auxiliary points are positioned, for example, to 
connect independent sections of a levelling line. 

D. Fixing the Points 

Regarding fixing the points, they are typically secured by 
utilizing drill and epoxy to seal concrete nails on a wall or 
floor. All monitoring points must be well connected to the 
structure, particularly the concrete columns otherwise the 
displacements might be more accurately described as 
displacements of the points rather than structural 
displacements. 

E.  Leveling Instruments 

It is necessary to use automatic levels, also known as 
optical levels, that have a built-in compensator that 
automatically makes the line of sight horizontal. Accuracy can 
be improved by mounting a parallel plate micrometer over the 
telescope objective [29]. The parallel plate micrometer permits 
estimated readings up to 0.01mm and direct readings up to 
0.1mm on a staff of 1cm least count. Digital levels may also be 
used. Digital levels are automatic levels that have a digital 
image processing system built in. These levels allow for 
electronic recording and automatic reading of coded bars staff. 
The speed of leveling and the elimination of the errors brought 
on by human reading and recording are the main benefits of 
digital levels [30]. 

F. Field Work 

It is necessary to know the reference station levels before 
monitoring points can be observed. Otherwise, precise leveling 
can be used to obtain the local levels of reference stations [29]. 
Loops are used for the leveling of the monitoring points. Each 
loop begins at a reference station and ends at either the same or 
another reference station. At various epochs of a predetermined 
time interval, the levels of the monitoring points are obtained. 
After the reference and monitoring, points have been selected 
and the leveling line route has been established, the necessary 
auxiliary points and an approximate location of the instrument 
in each leveling line must be marked in order to guarantee the 
precision required by having equal sections of leveling and by 
following almost the same route of line levelling. Starting and 
stopping leveling measurements at reference stations is the only 
way to control the quality of the measurements.  

The misclosure (Δ) is the difference between the 
determined level and the known level, and it is calculated by : 

Misclosure (Δ) =ReferenceLevelknown – Reference Levelcomputed   (7) 

Following the completion of the levelling work, the 
misclosure is computed. The fieldwork team is able to repeat 
the measurements at a lower cost and, most importantly, 
without altering the conditions of the structure by carrying out 
this data pre-processing in the field. The permissible 
misclosure can be calculated as [6]: 

Misclosure tolerance = 0.9 √n  (mm)  (8) 

where n is the number of set-ups. 

All measurements ought to be repeated when the 
misclosure is more than the tolerance value. In case of 
permissible misclosure, the points' adjusted levels can be 
determined applying the least squares technique as explained 
above. 

G. Vertical Displacement Determination 

The developed software is utilized for computing the 
adjusted levels of the monitoring points for each epoch. In 
order to compare the results of the subsequent epochs with 
those of the first epoch, the results of the first epoch are used as 
a reference. The vertical displacement of each monitoring point 
can be determined as follows: 

dZ = Zfirst epoch – Zcurrent epoch   (9) 

where dZ is the vertical displacement of the monitoring point 
and Z the adjusted level of the monitoring point.  

H. Displacement Analysis 

Comparing the level differences between the observations 
of the first epoch and the current epoch is the traditional 
method for determining the stability of reference and 
monitoring points, as shown in (9). In recent deformation 
modeling techniques, statistics are applied to each epoch of 
measurements to get the significance of point movements. 
Comparing the obtained displacements to their respective 95% 
confidence intervals is used to obtain the significance of point 
displacements [31]. In case the value of the vertical movement 
of a point K is classified as dZK and the maximum dimension of 



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www.etasr.com El-Ashmawy: An Efficient Methodology for Detecting the Vertical Movement of Structures  

 

the combined 95% confidence ellipse for point K is specified as 
EK, two cases will arise [32]: 

 In the first case if |dZK| < EK, then no movement has 
happened in point K and the observed difference is due to 
measurement errors.  

 If |dZK| > EK then point displacement has occurred. 

EK can be obtained as:  

1 2 2
1.96 ( ) ( )

i i
KE m m 

     (10) 

where 1( )im
  is the standard error in level of point K in the 

current epoch and ( )
i

m  is the standard error in level of point 

K in the previous epoch. 

III. CASE STUDY 

A building in Cairo, Egypt, was selected as a case study for 
monitoring the vertical displacement. The building is 110.0m 
long, 60.0m wide, and 20m high. There are various offices in 
this 3-story structure. 

A. Choosing Points 

The field has been identified in the initial step in order to 
carry out the vertical displacement monitoring of the studied 
building. As shown in Figure 2, 3 local reference stations and 5 
auxiliary points were chosen. In order to ensure that the local 
reference stations were unaffected by the building's 
displacements, these points were fixed around it at a secure 
distance. 

 

 
Fig. 2.  Location of the case study points. 

Twenty monitoring points were fixed on the first floor of 
the case study building as part of the vertical movement 
monitoring project to determine the structure's stability. Figure 
2 depicts the positions of those monitoring points on the 
internal and external walls. The staff could easily hold on to the 
monitoring points on the building walls during levelling and 
observation because they were about 0.3m above the ground. 
Special nails were driven into the marked monitoring points to 
make them permanent. 

B. Measurements 

Measurements were acquired with a Leica NA2 automatic 
level, a GPLE3 geodetic invar staff with 1cm graduations, and 
an attachment for a Leica (10mm) GPM3 parallel plate 
micrometer. Before the monitoring points can be observed, it is 
necessary to know the levels of the reference stations B1, B2, 
and B3 as explained above. The level of point B1 is assumed to 
be 15.0m. The levels of points B2 and B3 were obtained by 
looping a level net from B1 to 5 auxiliary points, B2 and B3, 
and then closing back on B1. After determining the reference 
station levels, loops utilizing precise leveling were utilized to 
get the levels of monitoring points at 8 distinct 1-month 
interval epochs. Observations were made in the early morning. 
Each leveling line's misclosure did not exceed 0.4mm across all 
8 observation epochs, which is an acceptable tolerance for the 
purposes of this work. The relatively flat topography of the 
study area, the experience of the observer, and the instruments 
used all contributed to the leveling's high accuracy. 

C. Data Processing and Results 

The developed software was used to process the data from 
the level networks. The necessary data and measurements such 
as the levels of the reference stations and their standard 
deviations, height differences, and distances between stations, 
were inserted into the software by editing the data file. The 
final results, for each epoch, were obtained from the adjustment 
of the level network. As previously mentioned, the variance of 
the unit weight, the adjusted levels of the monitoring points and 
their standard deviations, the residuals of the observations, and 
the corrected observations with their cofactor matrix comprised 
the received results. The high precision of the adjusted 
observations can be seen by the fact that the first to eighth 
leveling epochs had maximum variances of unit weight of 
1.02m

2
 and standard errors of 1.01mm. The high accuracy of 

the adjusted levels is demonstrated by the fact that their 
maximum standard error was 1.06mm across all epochs. All 8 
epochs' computed standardized residuals for observations or 
levels were less than their rejection constants of the respective 
standardized residual which indicates that none of the 
observations were rejected due to gross errors or outliers. 

The adjusted values of levels of monitoring points for each 
observation epoch and the differences in levels between the 
first and the subsequent epochs were respectively computed 
with (9) and are tabulated in Table I. Equation (10) was used to 
calculate the 95% confidence level differences between the first 
and respective confidence intervals of the subsequent epochs. 
The vertical displacement values of monitoring points and the 
confidence intervals that correspond to them at a 95% level of 
confidence are shown in Table II. 

At a 95% confidence level, the magnitudes of the vertical 
movement of the monitoring points at each epoch were 
obtained and compared to their identical confidence intervals to 
decide whether the obtained displacements were actual 
(significant) displacements of the structure or caused by 
measurement errors. According to Tables I and II, all the 
evaluated movement values were less than their related 
confidence intervals, indicating that there was no vertical 
movement of the building within the monitoring period. 



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TABLE I.  THE ADJUSTED LEVELS AND VERTICAL DISPLACEMENT OF THE MONITORING POINTS 

Point 
Epoch (1) Epoch (2) Epoch (3) Epoch (4) Epoch (5) Epoch (6) Epoch (7) Epoch (8) 

Level 
m 

dZ 
mm 

Level 
m 

dZ 
mm 

Level 
m 

dZ 
mm 

Level 
m 

dZ 
mm 

Level 
m 

dZ 
mm 

Level 
m 

dZ 
mm 

Level 
m 

dZ 
mm 

Level 
m 

dZ 
mm 

P1 15.3092 0 15.3093 -0.10 15.3095 -0.30 15.3094 -0.20 15.3093 -0.10 15.3097 -0.50 15.3097 -0.50 15.3095 -0.30 
P2 15.4085 0 15.4086 -0.10 15.4082 0.30 15.4082 0.30 15.4086 -0.10 15.4083 0.20 15.4084 0.10 15.4086 -0.10 
P3 15.3120 0 15.3116 0.40 15.3113 0.70 15.3114 0.60 15.3114 0.60 15.3112 0.80 15.3113 0.70 15.3114 0.60 
P4 15.2960 0 15.2956 0.40 15.2957 0.30 15.2953 0.70 15.2954 0.60 15.2956 0.40 15.2954 0.60 15.2955 0.50 
P5 15.8168 0 15.8166 0.20 15.8163 0.50 15.8162 0.60 15.8165 0.30 15.8163 0.50 15.8166 0.20 15.8167 0.10 
P6 15.8097 0 15.8093 0.40 15.8092 0.50 15.8095 0.20 15.8096 0.10 15.8095 0.20 15.8098 -0.10 15.8096 0.10 
P7 15.0963 0 15.0966 -0.30 15.0966 -0.30 15.0965 -0.20 15.0962 0.10 15.0963 0.00 15.0966 -0.30 15.0965 -0.20 
P8 15.1254 0 15.1255 -0.10 15.1256 -0.20 15.1252 0.20 15.1254 0.00 15.1251 0.30 15.1253 0.10 15.1256 -0.20 
P9 15.8458 0 15.8453 0.50 15.8451 0.70 15.8455 0.30 15.8457 0.10 15.8450 0.80 15.8455 0.30 15.8458 0.00 

P10 15.6507 0 15.6507 0.00 15.6501 0.60 15.6505 0.20 15.6503 0.40 15.6500 0.70 15.6505 0.20 15.6502 0.50 
P11 14.2996 0 14.2998 -0.20 14.2997 -0.10 14.2992 0.40 14.2995 0.10 14.2990 0.60 14.2993 0.30 14.2996 0.00 
P12 14.2160 0 14.2154 0.60 14.2158 0.20 14.2157 0.30 14.2155 0.50 14.2158 0.20 14.2154 0.60 14.2158 0.20 
P13 15.5106 0 15.5108 -0.20 15.5105 0.10 15.5107 -0.10 15.5103 0.30 15.5101 0.50 15.5105 0.10 15.51 0.60 
P14 15.6034 0 15.6034 0.00 15.6032 0.20 15.6031 0.30 15.6036 -0.20 15.6033 0.10 15.6037 -0.30 15.6035 -0.10 
P15 15.8085 0 15.8083 0.20 15.8087 -0.20 15.8086 -0.10 15.8083 0.20 15.8083 0.20 15.8085 0.00 15.8086 -0.10 
P16 15.6054 0 15.6057 -0.30 15.6055 -0.10 15.6053 0.10 15.6051 0.30 15.6052 0.20 15.6055 -0.10 15.6056 -0.20 
P17 15.4709 0 15.4705 0.40 15.4708 0.10 15.4703 0.60 15.4701 0.80 15.4703 0.60 15.4704 0.50 15.4705 0.40 
P18 15.6615 0 15.6615 0.00 15.6616 -0.10 15.6613 0.20 15.6614 0.10 15.6612 0.30 15.6611 0.40 15.6612 0.30 
P19 15.7997 0 15.7990 0.70 15.7992 0.50 15.7991 0.60 15.7995 0.20 15.7997 0.00 15.7990 0.70 15.7992 0.50 
P20 15.6783 0 15.6782 0.10 15.6787 -0.40 15.6787 -0.40 15.6784 -0.10 15.6783 0.00 15.6781 0.20 15.6783 0.00 

TABLE II.  DETECTING THE VERTICAL DISPLACEMENT OF THE MONITORING POINTS 

Point 
Epoch (2) Epoch (3) Epoch (4) Epoch (5) Epoch (6) Epoch (7) Epoch (8) 

Point 
displacement 

|dZ| 
mm 

E 

mm 
|dZ| 
mm 

E 

mm 
|dZ| 
mm 

E 

mm 
|dZ| 
mm 

E 

mm 
|dZ| 
mm 

E 

mm 
|dZ| 
mm 

E 

mm 
|dZ| 
mm 

E 

mm 
P1 0.10 1.67 0.30 1.97 0.20 2.01 0.10 2.41 0.50 1.39 0.50 1.89 0.30 1.81 None 
P2 0.10 1.97 0.30 2.27 0.30 1.91 0.10 1.91 0.20 2.09 0.10 1.79 0.10 1.41 None 
P3 0.40 2.07 0.70 2.17 0.60 1.81 0.60 2.31 0.80 1.99 0.70 1.79 0.60 1.51 None 
P4 0.40 1.77 0.30 1.97 0.70 2.31 0.60 2.21 0.40 1.59 0.60 2.09 0.50 1.51 None 
P5 0.20 1.37 0.50 2.17 0.60 2.01 0.30 2.01 0.50 1.99 0.20 1.59 0.10 1.51 None 
P6 0.40 1.17 0.50 1.97 0.20 1.61 0.10 2.21 0.20 1.89 0.10 1.59 0.10 1.81 None 
P7 0.30 1.57 0.30 1.87 0.20 2.01 0.10 2.61 0.00 1.69 0.30 1.59 0.20 1.71 None 
P8 0.10 2.17 0.20 1.77 0.20 2.31 0.00 2.11 0.30 2.09 0.10 1.69 0.20 1.31 None 
P9 0.50 1.97 0.70 2.07 0.30 1.51 0.10 2.11 0.80 2.49 0.30 2.09 0.00 1.31 None 
P10 0.00 1.77 0.60 2.47 0.20 1.51 0.40 2.51 0.70 2.09 0.20 2.19 0.50 1.91 None 
P11 0.20 2.07 0.10 1.97 0.40 2.41 0.10 2.01 0.60 2.29 0.30 1.59 0.00 1.31 None 
P12 0.60 1.67 0.20 1.47 0.30 2.01 0.50 2.51 0.20 1.49 0.60 2.29 0.20 1.81 None 
P13 0.20 1.97 0.10 2.17 0.10 1.71 0.30 2.71 0.50 1.99 0.10 1.49 0.60 2.11 None 
P14 0.00 2.17 0.20 2.07 0.30 2.01 0.20 1.81 0.10 2.09 0.30 1.49 0.10 1.81 None 
P15 0.20 1.67 0.20 1.47 0.10 2.01 0.20 2.61 0.20 1.79 0.00 1.69 0.10 1.51 None 
P16 0.30 1.77 0.10 2.07 0.10 2.11 0.30 2.51 0.20 1.69 0.10 1.59 0.20 1.51 None 
P17 0.40 1.87 0.10 1.57 0.60 2.41 0.80 2.51 0.60 1.59 0.50 2.29 0.40 2.11 None 
P18 0.00 1.87 0.10 1.77 0.20 2.21 0.10 2.21 0.30 1.99 0.40 1.99 0.30 1.51 None 
P19 0.70 1.67 0.50 1.67 0.60 2.01 0.20 1.91 0.00 1.59 0.70 2.59 0.50 1.41 None 
P20 0.10 1.57 0.40 1.37 0.40 1.91 0.10 2.61 0.00 1.89 0.20 2.09 0.00 1.41 None 

 

IV. SUMMARY, CONCLUSIONS, AND 
RECOMMENDATIONS  

The aim of measuring a structure's movement is to decide 
whether there is actually a movement and whether the structure 
is safe and stable. Deformation monitoring has the advantages 
of improving the design process of structures for use in the 
future and increasing safety by lowering the possibility of 
structural damage. It is a crucial risk management tool. 

This paper explains the development of a methodology for 
monitoring and analyzing structures' vertical displacement. The 
developed methodology aims to add a new dimension to the 
well-known ones for geometric leveling and leveling routing. 
The proposed methodology is accurate and effective in 

determining the vertical displacement of structures. The case 
study demonstrates that geometric leveling is always effective 
for determining the vertical displacement of structures. For 
vertical displacement monitoring with a precision of less than 
0.4mm, this approach is suggested. Geometric leveling is an 
accurate, precise, and cost-effective method of vertical 
displacement monitoring but it is not considered to be cutting-
edge. Geometric leveling is recommended to be used 
extensively to monitor structures' deformation for the above-
mentioned reasons. 

The proposed method is subjected to limitations in its 
application areas. The proposed method can only be utilized to 
monitor displacements in the vertical plane, it cannot be 



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utilized to monitor displacements in the horizontal plane. The 
developed software and methodology are very adaptable, 
affordable, and of great interest to students and researchers. 
They provide a helpful tool for engineering firms to monitor 
the safety of structures. It is strongly recommended that 
engineering structures, especially high-rise buildings, should be 
monitored at a regular basis to check their stability and thereby 
increasing their safety. 

REFERENCES 

[1] H. O. Aghedo, Deformation Monitoring of Ikpoba River Bridge in Benin 
City, Edo State, Using GPS. Unpublished MSc Thesis of the Department 
of Surveying and Geoinformatics, Nnamdi Azikiwe University, Awka, 
2016. 

[2] M. Javanpour and P. Zarfam, "Application of Incremental Dynamic 
Analysis (IDA) Method for Studying the Dynamic Behavior of 
Structures During Earthquakes," Engineering, Technology & Applied 
Science Research, vol. 7, no. 1, pp. 1338–1344, Feb. 2017, 
https://doi.org/10.48084/etasr.902. 

[3] C. Zhang, Y. Gao, and E. Duan, "The Influence of Environment on the 
Settlement of Historic Buildings in China," KSCE Journal of Civil 
Engineering, vol. 25, no. 6, pp. 1951–1963, Jun. 2021, https://doi.org/ 
10.1007/s12205-021-0690-9. 

[4] M. Mackiewicz, J. R. Krentowski, P. Knyziak, and M. Wardach, 
"Consequences of excessive deformation of structural elements in 
precast buildings," Engineering Failure Analysis, vol. 137, Jul. 2022, 
Art. no. 106261, https://doi.org/10.1016/j.engfailanal.2022.106261. 

[5] J. Gao, L. Liu, Y. Zhang, and X. Xie, "Deformation mechanism and soil 
evolution analysis based on different types geogrid reinforced 
foundation," Construction and Building Materials, vol. 331, May 2022, 
Art. no. 127322, https://doi.org/10.1016/j.conbuildmat.2022.127322. 

[6] A. Ebeling, "Ground-Based Deformation Monitoring," Ph.D. 
dissertation, University of Calgary, Calgary, Canada, 2014, 
https://doi.org/10.11575/PRISM/26325. 

[7] K. Zschiesche, "Image Assisted Total Stations for Structural Health 
Monitoring—A Review," Geomatics, vol. 2, no. 1, pp. 1–16, Mar. 2022, 
https://doi.org/10.3390/geomatics2010001. 

[8] M. El-Tokhey, A. K. Abdel-Gawad, Y. Mogahed, and A. M. El-
Maghraby, "Accuracy assessment of laser scanner in measuring and 
monitoring deformations of structures," vol. 26, no. 2, pp. 144–151, Jan. 
2013, https://doi.org/10.5829/idosi.wasj.2013.26.02.13461. 

[9] S. Kalenjuk, W. Lienhart, and M. J. Rebhan, "Processing of mobile laser 
scanning data for large-scale deformation monitoring of anchored 
retaining structures along highways," Computer-Aided Civil and 
Infrastructure Engineering, vol. 36, no. 6, pp. 678–694, 2021, 
https://doi.org/10.1111/mice.12656. 

[10] E. Kaartinen, K. Dunphy, and A. Sadhu, "LiDAR-Based Structural 
Health Monitoring: Applications in Civil Infrastructure Systems," 
Sensors, vol. 22, no. 12, Jan. 2022, Art. no. 4610, https://doi.org/ 
10.3390/s22124610. 

[11] C. Cosarca, A. Jocea, and A. Savu, "Analysis of error sources in 
Terrestrial Laser Scanning. RevCAD," Journal of Geodesy and 
Cadastre, vol. 9, pp. 115–125, 2009. 

[12] L. Fregonese, G. Barbieri, L. Biolzi, M. Bocciarelli, A. Frigeri, and L. 
Taffurelli, "Surveying and Monitoring for Vulnerability Assessment of 
an Ancient Building," Sensors, vol. 13, no. 8, pp. 9747–9773, Aug. 
2013, https://doi.org/10.3390/s130809747. 

[13] X. Yu, Y. Ge, T. Zhao, G. Zhang, Y. Liu, and C. Yu, "The Dynamic 
Displacement Monitoring Method Using Unmanned Aerial Vehicles 
Based on Digital Close-Range Photogrammetry," Mathematical 
Problems in Engineering, vol. 2022, Sep. 2022, Art. no. e1949213, 
https://doi.org/10.1155/2022/1949213. 

[14] J. Hu, E. Liu, and J. Yu, "Application of Structural Deformation 
Monitoring Based on Close-Range Photogrammetry Technology," 
Advances in Civil Engineering, vol. 2021, Feb. 2021, Art. no. e6621440, 
https://doi.org/10.1155/2021/6621440. 

[15] M. E. Tjahjadi, L. A. Parsamardhani, and K. T. Suhari, "Bridge 
Structural Deformation Monitoring Using Digital Camera," IOP 
Conference Series: Earth and Environmental Science, vol. 1051, no. 1, 
Apr. 2022, Art. no. 012009, https://doi.org/10.1088/1755-1315/1051/ 
1/012009. 

[16] J. A. Clarke and D. F. Laefer, "Systematic Approach for Large-Scale, 
Rapid, Dilapidation Surveys of Historic Masonry Buildings," 
International Journal of Architectural Heritage, vol. 8, no. 2, pp. 290–
310, Mar. 2014, https://doi.org/10.1080/15583058.2012.692849. 

[17] R. M. Alkan and G. Karsidag, "Analysis of the Accuracy of Terrestrial 
Laser Scanning Measurements," in FIG Working Week, Rome, Italy, 
Aug. 2012. 

[18] A. Ekinci, T. Muturi, and P. M. V. Ferreira, "Aerial Close-Range 
Photogrammetry to Quantify Deformations of the Pile Retaining Walls," 
Journal of the Indian Society of Remote Sensing, vol. 49, no. 5, pp. 
1051–1066, May 2021, https://doi.org/10.1007/s12524-020-01275-5. 

[19] G. Durán-Dominguez, A. Felicisimo, and M.-E. Polo, "3D study of 
cultural heritage for conservation. Reliability of the portable 3D laser 
scanners," presented at the International Congress on Science and 
Technology for the Conservation of Cultural Heritage, Seville, Spain, 
Jun. 2014. 

[20] A. Berényi, T. Lovas, and A. Barsi, "Terrestrial laser scanning in 
engineering survey: Analysis and application examples," presented at the 
ASPRS 2010 Annual Conference, San Diego, CA, USA, Jan. 2010. 

[21] A. Dumalski, "Evaluation of Possible Application of Terrestrial Laser 
Scanner - ScanStation in Vertical Displacement Measurements," 
Technical Sciences / University of Warmia and Mazury in Olsztyn, vol. 
14, no. 1, pp. 33–43, 2011. 

[22] M. K. Villareal and A. F. Tongco, "Remote Sensing Techniques for 
Classification and Mapping of Sugarcane Growth," Engineering, 
Technology & Applied Science Research, vol. 10, no. 4, pp. 6041–6046, 
Aug. 2020, https://doi.org/10.48084/etasr.3694. 

[23] C. D. Ghilani, Adjustment Computations: Spatial Data Analysis, 6th 
Edition | Wiley, 6th ed. Hoboken, NJ, USA: Wiley and Sons, 2017. 

[24] E. M. Mikhail, Observations and Least Squares. 1982. 

[25] D. S. Malik, C++ Programming: Program Design Including Data 
Structures, 8th ed. Australia: Cengage Learning, 2017. 

[26] B. Nethravathi, G. Amitha, A. Saruka, T. P. Bharath, and S. Suyagya, 
"Structuring Natural Language to Query Language: A Review," 
Engineering, Technology & Applied Science Research, vol. 10, no. 6, 
pp. 6521–6525, Dec. 2020, https://doi.org/10.48084/etasr.3873. 

[27] H. Schildt, Turbo C/C++: The Complete Reference, 2nd ed. Berkeley, 
CA, USA: McGraw-Hill Osborne Media, 1992. 

[28] B. Perkins, J. V. Hammer, and J. D. Reid, Beginning C# 7 Programming 
with Visual Studio 2017, 1st ed. Indianapolis, IN, USA: Wrox, 2018. 

[29] K. L. A. El-Ashmawy, "Accuracy, time cost and terrain independence 
comparisons of levelling techniques," Geodesy and Cartography, vol. 
40, no. 3, pp. 133–141, Jul. 2014, https://doi.org/10.3846/20296991. 
2014.962727. 

[30] V. Golubev, "Surveying," in Springer Handbook of Geographic 
Information, W. Kresse and D. Danko, Eds. Springer International 
Publishing, 2022, pp. 281–296, https://doi.org/10.1007/978-3-030-
53125-6_11. 

[31] B. Bird, "Analysis of Survey Point Displacements Using Total Station 
Measurements," British Columbia Institute of Technology, Technical 
Report, Apr. 2009. 

[32] E. S. Okiemute, M. N. Ono, and O. O. Fatai, "Monitoring and Analysis 
of Vertical Deformation of Palm House Benin City Using Digital 
Level," International Journal of Advances in Scientific Research and 
Engineering, vol. 9, no. 4, pp. 6–16, Sep. 2022, https://doi.org/ 
10.31695/IJASRE.2018.32860.