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Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8652-8657 8652 
 

www.etasr.com Jaballah et al.: A Comparative Study on Hybrid Vibration Control of Base-isolated Buildings Equipped … 

 

A Comparative Study on Hybrid Vibration Control of 

Base-isolated Buildings Equipped with ATMD 
 

Mohamed Seghir Jaballah 

Laboratory of Development in Mechanics and Materials 
Civil Engineering Department 
University of Ziane Achour 

Djelfa, Algeria 
ms.jaballah@univ-djelfa.dz 

Salaheddine Harzallah 

Built Environmental Research Laboratory, Civil 
Engineering Faculty, Sciences and Technology Department 

University of Houari Boumediene 

Bab Ezzouar, Algeria 
sharzallah@usthb.dz 

Bachir Nail 

Mechanical Engineering, Materials, and Structures Laboratory 

Faculty of Science and Technology 
Tissemsilt University 

Tissemsilt, Algeria 

bachir.nail@cuniv-tissemsilt.dz  
 

Received: 28 March 2022 | Revised: 11 April 2022 | Accepted: 14 April 2022 

 

Abstract-The vibration control for building structures using 

hybrid control (base isolators BI and Active Tuned Mass 
Dampers-ATMDs) has attracted the attention of researchers. 

This paper establishes a hybrid vibration control system of 

structure and compares structural response and active tuned 

mass damper performance among the structure using two 

different control algorithms (PID and LQR). Through simulation 

research, from the comparative analysis of performance indexes 
of structural response and ATMD performance, it is concluded 

that the LQR controller outperforms the PID controller in 
reducing the structural responses. 

Keywords-PID control; LQR control; hybrid control; base 

isolation; ATMD 

I. INTRODUCTION  

One of the biggest challenges in structural engineering is 
the development of structural vibration control techniques [1]. 
With those techniques, structures can be better protected from 
the damaging effect of destructive environmental forces such as 
earthquakes, winds, and other external loads [2]. Structural 
control has been investigated and has shown great results in 
reducing the vibrations in different civil structures under the 
effect of dynamic loads [3, 4]. 

The structural vibration control system can be divided by its 
method, or the types of devices being used, into four general 
types: passive control, active control, semi-active control, and 
hybrid control. A passive system can reduce the vibration 
energy without the need for external power. It uses a passive 
mechanism to reduce the response of the structure. This type of 
control utilizes two methods: seismic base isolation and 
supplemental damping [5]. Passive control mechanisms include 
tuned mass (or liquid) damper (TMD/TLD), viscoelastic 

damper, base isolation systems, etc. [5-7]. Although the usage 
of a passive control system is very simple and affordable, it has 
significant disadvantages, such as being less adaptable to 
external environmental actions such as earthquakes and winds. 
The active structural control system uses actuators, sensors 
mounted at different locations on the structure to measure 
external excitations and the structural response, and a computer 
to calculate the appropriate force control. An external power 
source also is needed for actuators to apply forces to control or 
to modify the motion of the structure. Active control devices 
include Active Tendon Systems (ATS), Active Mass Dampers 
(AMD), active brace systems, etc. [8]. Hybrid structural control 
systems are excellent vibration control systems, because they 
combine the reliability of the passive system and the 
adaptability of the active system [9, 10]. To get the optimal 
control force, many methods and algorithms have been created. 
An analytical model for the entire system and a dynamic model 
of the system are needed, including all its objects such as the 
structure, sensor, actuators, and controller [11, 12]. 

In a building structure equipped with an ATMD, a motor 
based device called actuator applies a force known as control 
force. One or more actuators apply these forces to a structure 
according to the control law and use an external energy source 
for their operation. These forces can be used to add or dissipate 
energy from the structure to be controlled. To build such a 
system, there are two radically different approaches: The first is 
to identify the seismic excitation which creates the vibrations to 
cancel it out by superimposing an "inverse" excitation on it. 
This active control strategy is called feedforward. It is mainly 
developed in acoustics [13, 14], but it is also very useful for the 
control of vibration of structures. The second is to identify the 
structure's response rather than the excitement that makes it 

Corresponding author: Mohamed Seghir Jaballah 



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vibrate. It, therefore, requires the modeling of the structure to 
evaluate its dynamic behavior. The vibration control work that 
goes into this type of strategy is called feedback loop control. 
[15]. 

 

 
Fig. 1.  Structural vibration control. 

Base isolation systems are a well-known application of the 
passive control approach. These base isolators are placed 
between the foundations and the superstructure, these devices 
make it possible to decouple the movement from the ground to 
the superstructure, the aim of which is to reduce the forces 
transmitted from the ground. The isolators absorb the ground’s 
shaking energy and filter high-frequency accelerations so that 
the isolated superstructure moves essentially in a rigid mode 
undergoing low accelerations and almost no deformations [16]. 
For this reason, the base isolation system is an effective tool to 
ensure the seismic protection of rigid structures. To design the 
appropriate base isolator and to have its optimum performance 
many parameters should be considered, like the different 
characteristics of the soil and the location of the structure [17]. 
LRB (Laminated Rubber Bearings) base isolators are known as 
one of the most used systems in isolating structures. And 
therefore, this type was chosen in the current study. 

The main purpose of this work is to compare and evaluate 
two different types of control algorithms (PID and LQR), that 
control and drive the ATMD. The ATMD will be placed on the 
top floor because it has been proven that putting the it there is a 
very effective strategy to reduce the structural responses. Our 
structure will be equipped with base isolators in both cases and 
the performance of the two systems will be evaluated under the 
effect of three strong earthquakes (El Centro, Kobe, and 
Northbridge).  

II. PID AND LQR CONTROLLERS 

A Proportional Integral Derivative (PID) regulator is a 
control organ that allows carrying out the closed-loop 
regulation of an industrial process. The regulator compares a 
value measured on the process with a setpoint. The difference 
between these two values (the error signal) is then used to 
calculate a new input value of the process tending to reduce as 
much as possible the difference between the measurement and 
the setpoint (lowest possible error signal). 

"PID" represents the abbreviations of the three actions it 
uses to make its corrections: a Proportional action, an Integral 
action, and a Derivative action. Adjusting this type of 
controller is often a matter of experience. Its independence 

towards the model of the system is a guarantee of robustness 
when applied to known, linear, and little-variant systems[18]. 

���� �	��	���
	���	���
�
	�� ����     (1) 
where �� is the proportional gain, �� is the integral gain, and 
�� is the derivative gain. 

 

Prop or tional

In tegral

D erivative

Plantr(t) +
-

+
+

+

Output y (t)e(t)

feedback
 

Fig. 2.  The PID controller. 

Linear Quadratic Regulator (LQR) control belongs to the 
family of optimal control algorithms. In optimum control, a 
cost function representing a performance index is chosen and 
then reduced to provide the optimal input. In the quadratic 
optimum control problem, the cost function can be designed to 
be quadratically dependent on the control input and the output 
state or response [19]: 

� �	��	� �����
	��
��
�� ���
�    (2) 

where Q is the weighting matrix (output), and R is the control 
vector (input). The performance index J represents the balance 
between the structural response and the control energy, the 
purpose of which is to reduce the response of the structure. The 
performance index shown in (3) is chosen in such a way, as to 
minimize the structural response and control energy over the 
time interval from �0 to ��. When the elements of � are large, 
the response of the system will be minimized to a large control 
force. When the elements of R are large, the control force will 
be small, but the structural response cannot be reduced 
sufficiently [20, 21]. 

���� �������    (3) 
K (LQR gain vector) is given by: 

� � ������    (4) 
where P is the solution matrix of Ricaati’s equation. 

 

 
Fig. 3.  The LQR controller. 

 



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III. MATHEMATICAL FORMULATION 

The movement equation of structure is written as: 

 �!���
"�#���
����� � � �$! ���
%���    (5) 
where M is the mass matrix, C is the damping matrix, and K is 
the stiffness matrix [22]. 

In this study, each matrix can be represented as follows: 

 � 
&'(�)*	)�	)� 	…	),	)��     (6) 

" �

-
.
.
.
.
.
.
/0* 
0� �0��0� 0� 
0� �0�

�0� ⋱ ⋱
⋱ ⋱ ⋱

⋱ ⋱
0, 
0�2� �0�2�
�0�2� 0�2� 3

4
4
4
4
4
4
5

    (7) 

� �

-
.
.
.
.
.
.
/6* 
6� �6�6 6� 
6� �6�

�6� ⋱ ⋱
⋱ ⋱ ⋱

⋱ ⋱
6, 
6�2� �6�2�
�6�2� 6�2� 3

4
4
4
4
4
4
5

   (8) 

Displacement vector: 

7�8�
-
..
.
/
�*
��
⋮
�,
��2�3

44
4
5
, 

velocity vector: 

7�#8�
-
.
.
.
/ �*��#
⋮
�,#
��2�#

#

3
4
4
4
5
, 

acceleration vector: 

7�!8 �
-
.
.
.
/ �*!��!
⋮
�,!
��2�! 3

4
4
4
5
	. 

where �*	  and ��2�	are the base and active mass damper 
displacements, 7:8	 is the influence vector, in this study 
7:8� ;0,0,…,1,1?�, and 7
8 denotes the applied control forces 
location vector [23]. 

The state-space representation is used to represent the 
equation of motion for the building structure [24-26]. 

@x# � 	B�
��C � 	"�
D�    (9) 
where A is the system matrix, x the state vactor, B the input 
matrix u the input vector, C  the output matrix, y the output 
vector, and D  the feedthrough matrix. 

Equation (2) can be rewritten as [10]: 

@�#����!���E� F
;0? ;G?

�; ?��;�? �; ?��;"?H@
����
�#���E
   

F ;0?�; ?��7:8H7����8
@
;0?

�; ?��7
8ExI! ���    (10) 

IV. NUMERICAL SIMULATION 

In this study, the performance of a hybrid control system 
(base isolators + ATMD) is investigated. The active force is 
obtained by a PID and an LQR controller. A 5-story base-
isolated building is considered. The top floor displacement was 
used as feedback in both control systems (PID and LQR). The 
damping and stiffness of the ATMD are determined assuming a 
passive TMD device adjusted to the structure's first mode. The 
building structure parameters are shown in Table I. The 
proportional, integral and derivative values selected for the PID 
controller are: Kp = -20, Ki = -1, Kd =-300 and filter coefficient 
N=100. 

TABLE I.  BUILDING PARAMETERS 

Floor Mass (Kg) Stiffness (KN/m) Damping (KN.s/m) 

Base isolators 1.5 × 10
3
 2.16 × 10

2
 2.7 

1 1.5 × 10
3
 2.1 × 10

6
 34 

2 1.5 × 10
3
 2.1 × 10

6
 34 

3 1.5 × 10
3
 2.1 × 10

6
 34 

4 1.5 × 10
3
 2.1 × 10

6
 34 

5 1.5 × 10
3
 2.1 × 10

6
 34 

ATMD 900 7.85 0.689 
 

mn

mn-1

xn

xn-1

m1

x1

Actuator

mATM D

kATM D

cATM D

Ba se is olators

xatmd

Earthquake 
excitation

 
Fig. 4.  Base isolated building equipped with ATMD on the top floor. 



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The simulation was done in Matlab/Simulink. Three strong 
historically known earthquakes were used. El Centro (1940), 
Northridge (1994), and Kobe (1995) earthquakes. 

V. RESULTS AND DISCUSSION 

The response results of the isolated, uncontrolled structure 
were compared to the same structure equipped with an ATMD, 
using PID and LQR control algorithms. Figures 5-7 show the 
building’s top floor displacement comparison. 

 

 
Fig. 5.  Structural response under El Centro seismic excitation. 

 
Fig. 6.  Structural response under Kobe seismic excitation. 

 
Fig. 7.  Structural response under Northridge seismic excitation. 

(a) 

 

(b) 

 

(c) 

 

Fig. 8.  Maximum story drift for the structure under the different 

earthquake excitations: (a) El Centro, (b) Kobe, and (c) Northridge. 

Figure 5 shows the top floor displacement under El Centro 
earthquake excitation. It can be seen that the hybrid control 
system using the LQR controller reduces the peak displacement 
by almost 60% and the PID controller by 49% in comparison 
with the uncontrolled structure. Figure 6 shows the top floor 
displacement under Kobe earthquake excitation. From this 
Figure, it can be noted that the hybrid control system using the 
LQR controller outperforms the PID controller and reduces the 



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peak displacement by almost 57%. The top floor displacement 
under Northridge earthquake excitation is shown in Figure 7. 
Again, the hybrid control system using the LQR controller 
surpasses the PID controller and reduces the peak displacement 
by almost 62%. As these Figures show, using the LQR 
controller to control the displacement of the top floor of the 
structure always gives better results than when using a PID 
system. It can be seen that the hybrid system designed using an 
LQR controller is more efficient and effective than PID control 
in reducing the displacement of this building in the three cases. 

VI. CONCLUSION 

The objective of this study is to combine the application of 
base isolators and ATMDs to minimize the structural responses 
under the influence of seismic excitations using two different 
controllers, LQR and PID. According to the numerical studies 
for a 5-story building, and the obtained results, the following 
conclusions can be drawn: 

• The comparison between LQR and PID controllers 
indicates that the LQR controller is more effective in 
reducing the displacements and the vibration of the building 
and surpasses the PID controller by far. 

• In this study, the active control system proved to be far 
more efficient than the passive control systems in reducing 
the structural response. 

• More than 50% of the top floor displacement is reduced by 
using the hybrid control system. 

• Using a hybrid control system to control the vibration of a 
structure improves its performance in resisting strong 
earthquake excitations and makes the structure safer and 
more comfortable during earthquakes. 

For future research, we will work in combining LQR and 
PID controllers in order to get the advantages of each system. 

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