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Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7922-7926 7922 
 

www.etasr.com Bakria et al.: Chaos Control and Stabilization of a PID Controlled Buck Converter Using the … 

 

Chaos Control and Stabilization of a PID Controlled 

Buck Converter Using the Spotted Hyena Optimizer 
 

Derradji Bakria 

LAADI Laboratory 
Department of Sciences and Technology 
Ziane Achour University of Djelfa 

Djelfa, Algeria 
bakriaderradji@gmail.com 

Messaouda Azzouzi 

Department of Sciences and Technology 
Ziane Achour University of Djelfa 

Djelfa, Algeria 

Dr.Azzouzi@yahoo.fr 
 

Djamal Gozim 

Department of Sciences and Technology 
Ziane Achour University of Djelfa 

Djelfa, Algeria 

gozimansour@gmail.com
 

 

Abstract-The voltage controlled buck converter by constant-

frequency pulse-width modulation in continuous conduction 

mode gives rise to a variety of nonlinear behaviors depending on 

the circuit parameters values, which complicate their analysis 

and control. In this paper, a description of the DC/DC buck 
converter and an overview of some of its chaotic dynamics is 

presented. A solution based on the optimized PID controller is 

suggested to eliminate the observed nonlinear phenomena and to 

enhance the dynamics of the converter. The parameters of the 

controller are optimized with the Spotted Hyena Optimizer 

(SHO) which uses the sum of the error between the reference 

voltage and the output voltage as well as the error between the 

values of the inductor current in every switch opening instant to 

determine the fitness of each solution. The simulations results in 
MATLAB proved the efficiency of the proposed solution. 

Keywords-buck converter; nonlinear behavior; optimized PID 

controller; spotted hyena optimizer 

I. INTRODUCTION  

DC-DC switched mode power converters have been widely 
used in many industrial and domestic applications such as 
hybrid cars, photovoltaic solar energy applications, cell phones 
chargers, etc. due to their high efficiency compared to the 
conventional linear regulators. To achieve the desired 
performance, the DC-DC converters can be either current 
controlled or voltage controlled. Controllers based on linear 
theory can be used due to their easy and low implementation 
cost and the good performance around the operating point [1, 
2]. However, they do not take into consideration the nonlinear 
phenomena that can occur in the converter in high frequencies 
or when one of the parameters of the converter changes [3-6]. 
Recent research has proposed numerous solutions to address 
the above-mentioned problems. For instance, in [7], boost 
converter discrete-time models were used as an example to 
present an analytical solution that allows the prediction of 

nonlinear phenomena in digital current mode controlled power 
converters. Meanwhile, in [8] the authors proposed a new 
method for the design of a stable and robust feedback control 
using the bifurcation analysis of the bilinear averaged model of 
boost converter and constrained stabilization principles. 
Another approach for designing a controller that guarantees the 
system's global stability was introduced in [9]. The approach is 
based on the principles of the contraction theory of switched 
systems. Nonetheless, the aforementioned works are based on 
analytical solutions and are a bit complex, and hard to 
implement in real plants. Fuzzy logic-based controllers have 
been used to control chaos in many studies [10-18]. However, 
the use of fuzzy logic complicates the control system and 
requires considerable computation time and a large memory 
space, while the use of the controllers based on metaheuristic 
algorithms ensure, at least, the same performance as the fuzzy 
controllers with less complexity and implementation cost [19-
21]. Nonetheless, most of previous works that use this type of 
controller are using the Integral Absolute Error (IAE) as an 
adaptation coefficient which is insufficient to estimate the 
fitness of each solution during the search.  

Nonlinear phenomena elimination in power converters is 
still an open research subject, although good results have been 
achieved in the literature. In this paper, we propose a method of 
shifting the nonlinear phenomena and expand the stability 
range of the converters without the need of complicated 
analysis methods or additional circuits. Using the powerful 
tools of MATLAB and the state-space model of the buck 
converter as an example, we designed a PID regulator that 
guarantees both global stability of the system and parameter 
disturbance rejection (load, input voltage, reference voltage). 
This design is based on the Spotted Hyena Optimizer (SHO) to 
determine the optimum gains of the controller using 
appropriate adaptation coefficients.  

Corresponding author: Derradji Bakria 



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II. SYSTEM DESCRIPTION 

A. Buck Converter 

A buck converter is a Switch Mode Power Supply (SMPS) 
that converts a DC voltage into a lower DC voltage through the 
commutation between different configurations [22, 23]. Buck 
converters are generally controlled via voltage mode control. In 
this control mode, the error (ℇ(t)) between the output voltage 
(�����) and the reference voltage (���	) is used to obtain the 
control signal (
���� ). The latter is compared with the 
sawtooth signal to generate the PWM signal needed to derive 
the switch. The proposed study circuit is illustrated in Figure 1. 

 

 
Fig. 1.  Voltage controlled buck converter. 

The state of the system is expressed by the vector  � 
 ���,����with: 
X�� 
 ��X� ���    (1) 

where the state matrices �� and �� for each configuration are: 

�� 
��
�� 

!"#$%"&%' ()(()*(+,
�

-"
��"%")�"

.�"%")�
-�

.�"%")�/
00
1
,�� 
 2

34
�06    (2) 

�7 
��
�� 

!"8%"&%' ()(()*(+,
�

-"
��"%")�"

.�"%")�
-�

.�"%")�/
00
1
,�7 
 900:    (3) 

�; 
 2
0 0
0 -�.�"%")�6 ,�; 
 9

0
0:    (4) 

Equation (5) represents the solution of (1):  

X���� 
 <=>�?-?@��X���A����-���� ��-���    (5) 
The behavior of the system is described in each 

configuration using (5) where the final state of the system in 
the current configuration is considered as the initial state X���A� 
for the next one. 

B. Spotted Hyena Optimizer 

SHO imitates the natural hunting behavior of the spotted 
hyenas to find the optimum solution for an optimization 
problem [24, 25]. A pack of spotted hyenas follow an 

organized group hunting technique that can be divided into 
three main behaviors: 

1) Searching and Encircling Prey 

When the hunt begins, the pack of the spotted hyenas has 
no information about the position of the prey, therefore the 
current fittest search agent will decide the possible location of 
the prey in the search space. Then, the rest of the pack will 
surround this position.  

2) Hunting 

The group hunting behavior of the spotted hyenas is based 
on a cluster of trusted friends that guide the members of the 
pack during the hunt. 

3)  Attacking 

All search agents will be forced to move towards the 
position of the prey. 

More details on the mathematical model of the SHO 
algorithm can be found in [24, 25]. 

C. SHO Application 

In this study, the SHO algorithm was applied to determine 
the optimal parameters of a PID controller that would improve 
the dynamics of the converter. It is based on the minimization 
of the steady state error between the reference and the 
measured voltage, and the error between the successive values 
of the inductor current (measured in each switch opening 
instant) which are the peaks of the inductor current. Equation 
(6) represents the proposed objective function. 

B��� 
 C�B� � C7B7    (6) 
B� 
 D∑ �F>-G�H

I>
J     (7) 

B7 
 K |M���|?N?@ O�    (8) 
where B� is the standard deviation of inductor current values 
measured in each switch opening instant, and B7 represents the 
Integral Absolute Error (IAE). 

 

 
Fig. 2.  Closed loop system with SHO. 

Figure 2 presents the control block diagram of the system, 

where PQ , P�  and PR  are respectively the proportional, the 
integral, and the derivative gains obtained by the SHO. 

III. RESULTS AND DISCUSSION 

The mathematical model of the proposed circuit presented 
in Figure 1 was simulated in MATLAB using (2)-(5). The 
converter and controller parameters are presented in Table I. 



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TABLE I.  PARAMETERS OF THE PROPOSED CIRCUIT 

Converter 

�S 24 Ω 
B 2500 TU 

VWX 
 VY 0.0177 � Z 0.02 T 
V� 2 Ω 
 47 [B 
V. 0.2 Ω V 22 Ω 

Optimizer 

C� 100 C7 1 
Iterations 100 

Search agents 20 

Controller 

PQ 8 
P� 800 PR 0.0001 
 

A. Original Behavior 

In this study, the input voltage was chosen for study and 
observation while the other parameters had fixed values. As 
shown in Figure 3, the converter dynamics clearly changed 
from Period 1, to Period 2, to Period 4, and then to chaotic 
dynamic behavior.  

 

 
(a) 

(b) (c) 

(d) (e) 

Fig. 3.  (a) Bifurcation diagram varying �S. (b) Phase plan diagram ��  �� 
and the inductor current ����� of Period 1 when �S 
 24� . (c) Phase plan 
diagram ��  �� and the inductor current ����� of Period 2 when �S 
 30�. (d) 
Phase plan diagram ��  �� and the inductor current ����� of Period 4 when �S 
 34�. (e) Phase plan diagram ��  �� and the inductor current ����� of 
chaos when �S 
 40�. 

The input voltage �S was set to start from 20V, and then it 
increased gradually to 80V. The converter exhibits the stable 

Period 1 behavior when �S _ 26� followed by the unstable 
period 2 behavior when 26 a �S _ 33.25�.�fterwards, the 
converter exhibits the unstable Period 4 when 33.25 a �S _34.75� . Finally, the converter shows irregular behavior 
(chaos) when �S e 34.75�. Figures 3(b), 3(c), 3(d) and 3(e) 
show the phase plan diagram ��  �� and the inductor current ����� of the aforementioned behaviors respectively. 
B. Optimized Behavior 

As shown in the convergence curve in Figure 4, the SHO 
algorithm finds the optimal gains of the controller after a few 
iterations. Figure 5 is the voltage wave diagram obtained before 
and after the optimized PID controller was implemented, where 
the latter begins after 0.06s. It is clear from the wave form of 
the output voltage and the phase plan diagram ��  �� that the 
converter returns to the stable Period 1 behavior at 0.067s. 

 

 
Fig. 4.  Convergence curve. 

 

Fig. 5.  V� after applying the optimized parameters. 
The bifurcation diagram in Figure 6 proves that the 

optimized controller is able to extend the stability range of the 
converter up to 80V of �S. For more efficiency evaluation, the 
robustness of the control to the sudden changes in the 
parameters of the converter has been tested. The response of 
the output voltage �� to a sudden change in the input voltage, 
the reference voltage and load are presented in Figure 7. 



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Fig. 6.  Bifurcation diagram varying �S using the optimized PID. 

(a) 

 

(b) 

 

(c) 

 

Fig. 7.  System response to changes in: (a) Input voltage, (b) reference 

voltage, (c) load. 

In the first 40ms, the system is subject to the parameters 
given in Table I, as shown in Figure 7(a). Steady state is 

reached in 6ms with no overshoot. At t=40ms, the input voltage 
is increased to 30V, as it is remarked, and the controller was 
able to stabilize the system. At the same instant as before, we 
repeated the same scenario by inducing a sudden change in the 
reference voltage. At t=40ms, the reference voltage changed to 
5V, and the controller adapts with the change and stabilizes the 
system to the new operating point. The results are shown in 
Figure 7(b). The same scenario is repeated again to test the 
response of the system to the change in load. At t=40ms we 
changed the load to 35Ω. From Figure 7(c), it can be seen that 
the system remains stable and tracks the reference voltage. 

IV. CONCLUSION 

In this paper, PI D controller gain tuning for a voltage 
controlled DC-DC buck converter is formulated as an 
optimization problem. This optimization is aimed to produce 
gains for the controller that would guarantee a robust closed 
loop. In addition, the objective function used to evaluate the 
fitness of the gains during the optimization is based on the sum 
of the error between the reference voltage and the output 
voltage as well as the error between the values of the inductor 
current in every switch opining instant. The SHO was used to 
solve this problem. 

To evaluate the efficiency of the designed controller to shift 
nonlinear phenomena, the bifurcation diagram obtained using 
the optimized controller is compared to that presented in the 
literature. We also tested the capability of the controller to 
reject the disturbance in the parameters of the converter (load, 
input voltage, and reference voltage). The obtained results 
prove the efficiency of the proposed solution to shift the 
nonlinear phenomena and to expand the range of the desired 
period 1 behavior. In addition to its high efficiency, this 
solution offers a simple control circuit and low implementation 
cost without the need of additional circuits. 

REFERENCES 

[1] A. G. Perry, G. Feng, Y.-F. Liu, and P. C. Sen, "A Design Method for 

PI-like Fuzzy Logic Controllers for DC–DC Converter," IEEE 
Transactions on Industrial Electronics, vol. 54, no. 5, pp. 2688–2696, 

Oct. 2007, https://doi.org/10.1109/TIE.2007.899858. 

[2] M. Saoudi, A. El-Sayed, and H. Metwally, "Design and implementation 

of closed-loop control system for buck converter using different 
techniques," IEEE Aerospace and Electronic Systems Magazine, vol. 32, 

no. 3, pp. 30–39, Mar. 2017, https://doi.org/10.1109/MAES.2017. 
150261. 

[3] M. M. Al-Hindawi, A. Abusorrah, Y. Al-Turki, D. Giaouris, K. Mandal, 

and S. Banerjee, "Nonlinear Dynamics and Bifurcation Analysis of a 
Boost Converter for Battery Charging in Photovoltaic Applications," 

International Journal of Bifurcation and Chaos, vol. 24, no. 11, Nov. 
2014, Art. no. 1450142, https://doi.org/10.1142/S0218127414501429. 

[4] A. Ghosh and S. Banerjee, "Study of complex dynamics of DC-DC buck 

converter," International Journal of Power Electronics, vol. 8, no. 4, pp. 
323–348, Jan. 2017, https://doi.org/10.1504/IJPELEC.2017.085200. 

[5] S. Banerjee, A. Ghosh, and S. Padmanaban, "Modeling and analysis of 

complex dynamics for dSPACE controlled closed-loop DC-DC boost 
converter," International Transactions on Electrical Energy Systems, 

vol. 29, no. 4, 2019, Art. no. e2813, https://doi.org/10.1002/etep.2813. 

[6] S. Demirbas, H. Fidanboy, and E. Kurt, "Exploration of the Chaotic 
Behaviour in a Buck–Boost Converter Depending on the Converter and 

Load Elements," Journal of Electronic Materials, vol. 8, no. 45, pp. 
3889–3899, 2016, https://doi.org/10.1007/s11664-016-4450-4. 



Engineering, Technology & Applied Science Research Vol. 11, No. 6, 2021, 7922-7926 7926 
 

www.etasr.com Bakria et al.: Chaos Control and Stabilization of a PID Controlled Buck Converter Using the … 

 

[7] A. K. Singha, S. Kapat, S. Banerjee, and J. Pal, "Nonlinear Analysis of 
Discretization Effects in a Digital Current Mode Controlled Boost 

Converter," IEEE Journal on Emerging and Selected Topics in Circuits 
and Systems, vol. 5, no. 3, pp. 336–344, Sep. 2015, https://doi.org/ 

10.1109/JETCAS.2015.2462151. 

[8] C. Yfoulis, D. Giaouris, F. Stergiopoulos, C. Ziogou, S. Voutetakis, and 
S. Papadopoulou, "Robust constrained stabilization of boost DC–DC 

converters through bifurcation analysis," Control Engineering Practice, 
vol. 35, pp. 67–82, Feb. 2015, https://doi.org/10.1016/j.conengprac. 

2014.11.004. 

[9] D. Angulo-Garcia, F. Angulo, G. Osorio, and G. Olivar, "Control of a 
DC-DC Buck Converter through Contraction Techniques," Energies, 

vol. 11, no. 11, Nov. 2018, Art. no. 3086, https://doi.org/10.3390/ 
en11113086. 

[10] K. Guesmi, N. Essounbouli, A. Hamzaoui, J. Zaytoon, and N. 
Manamanni, "Shifting nonlinear phenomena in a DC–DC converter 

using a fuzzy logic controller," Mathematics and Computers in 
Simulation, vol. 76, no. 5, pp. 398–409, Jan. 2008, https://doi.org/ 

10.1016/j.matcom.2007.04.008. 

[11] K. Guesmi, N. Essounbouli, and A. Hamzaoui, "Systematic design 
approach of fuzzy PID stabilizer for DC–DC converters," Energy 

Conversion and Management, vol. 49, no. 10, pp. 2880–2889, Oct. 
2008, https://doi.org/10.1016/j.enconman.2008.03.012. 

[12] K. Mehran, D. Giaouris, and B. Zahawi, "Stability Analysis and Control 

of Nonlinear Phenomena in Boost Converters Using Model-Based 
Takagi–Sugeno Fuzzy Approach," IEEE Transactions on Circuits and 

Systems I: Regular Papers, vol. 57, no. 1, pp. 200–212, Jan. 2010, 
https://doi.org/10.1109/TCSI.2009.2019389. 

[13] W. Hu, B. Zhang, and R. Yang, "Bifurcation Mechanism and 

Stabilization of V2C Controlled Buck Converter," IEEE Access, vol. 7, 
pp. 77174–77182, 2019, https://doi.org/10.1109/ACCESS.2019. 

2918297. 

[14] G. Djamal, G. Kamel, and M. Djiali, "On the elimination of nonlinear 
phenomena in DC/DC converters using type-2 fuzzy logic controller," 

Diagnostyka, vol. 19, no. 3, pp. 73–80, Sep. 2018, https://doi.org/ 
10.29354/diag/93139. 

[15] M. Ayati, A. Bakhtiyari, and A. Gohari, "Chaos control in buck 

converter using fuzzy delayed-feedback controller," in 4th International 
Conference on Control, Instrumentation, and Automation, Qazvin, Iran, 

Jan. 2016, pp. 362–365, https://doi.org/10.1109/ICCIAutom.2016. 
7483189. 

[16] Y. Yuan, C. Chang, Z. Zhou, X. Huang, and Y. Xu, "Design of a single-
input fuzzy PID controller based on genetic optimization scheme for 

DC-DC buck converter," in International Symposium on Next-
Generation Electronics, Taipei, Taiwan, May 2015, pp. 1–4, 

https://doi.org/10.1109/ISNE.2015.7131965. 

[17] Z. B. Duranay, H. Guldemir, and S. Tuncer, "Fuzzy Sliding Mode 
Control of DC-DC Boost Converter," Engineering, Technology & 

Applied Science Research, vol. 8, no. 3, pp. 3054–3059, Jun. 2018, 
https://doi.org/10.48084/etasr.2116. 

[18] K. Behih, K. Benmahammed, Z. Bouchama, and M. N. Harmas, "Real-

Time Investigation of an Adaptive Fuzzy Synergetic Controller for a 
DC-DC Buck Converter," Engineering, Technology & Applied Science 

Research, vol. 9, no. 6, pp. 4984–4989, Dec. 2019, 
https://doi.org/10.48084/etasr.3172. 

[19] H. Abderrezek, A. Ameur, and M. N. Harmas, "Robust DC/DC 

converter controllers using PSO," Electrotehnica, Electronica, 
Automatica, vol. 65, no. 1, pp. 31–37, Jan. 2017. 

[20] C.-B. Fu, A.-H. Tian, K.-N. Yu, Y.-H. Lin, and H.-T. Yau, "Analyses 

and Control of Chaotic Behavior in DC-DC Converters," Mathematical 
Problems in Engineering, vol. 2018, Nov. 2018, Art. no. e7439137, 

https://doi.org/10.1155/2018/7439137. 

[21] H. Abdelgawad and V. Sood, "Boost Converter Controller Design Based 
On Particle Swarm Optimization," International Journal on Power 

Engineering and Energy, vol. 7, no. 2, pp. 647–659, 2016. 

[22] R. W. Erickson and D. Maksimovic, Fundamentals of Power 

Electronics. Netherlands, Amsterdam: Kluwer Academic Publishers, 
2001. 

[23] K. Jayaswal and D. K. Palwalia, "Performance Analysis of Non-Isolated 
DC-DC Buck Converter Using Resonant Approach," Engineering, 

Technology & Applied Science Research, vol. 8, no. 5, pp. 3350–3354, 
Oct. 2018, https://doi.org/10.48084/etasr.2242. 

[24] G. Dhiman and V. Kumar, "Spotted hyena optimizer: A novel bio-

inspired based metaheuristic technique for engineering applications," 
Advances in Engineering Software, vol. 114, pp. 48–70, Dec. 2017, 

https://doi.org/10.1016/j.advengsoft.2017.05.014. 

[25] G. Dhiman and A. Kaur, "Spotted Hyena Optimizer for Solving 
Engineering Design Problems," in International Conference on Machine 

Learning and Data Science, Noida, India, Dec. 2017, pp. 114–119, 
https://doi.org/10.1109/MLDS.2017.5.