Designing of optimized microstrip fractal antenna using hybrid metaheuristic framework for IoT applications

doi:10.23919/JSEE.2024.000115

Abstract

Abstract:

Nowadays, wireless communication devices turn out to be transportable owing to the execution of the current technologies. The antenna is the most important component deployed for communication purposes. The antenna plays an imperative role in receiving and transmitting the signals for any sensor network. Among varied antennas, micro strip fractal antenna (MFA) significantly contributes to increasing antenna gain. This study employs a hybrid optimization method known as the elephant clan updated grey wolf algorithm to introduce an optimized MFA design. This method optimizes antenna characteristics, including directivity and gain. Here, the factors, including length, width, ground plane length, height, and feed offset-X and feed offset-Y, are taken into account to achieve the best performance of gain and directivity. Ultimately, the superiority of the suggested technique over state-of-the-art strategies is calculated for various metrics such as cost and gain. The adopted model converges to a minimal value of 0.2872. Further, the spider monkey optimization (SMO) model accomplishes the worst performance over all other existing models like elephant herding optimization (EHO), grey wolf optimization (GWO), lion algorithm (LA), support vector regressor (SVR), bacterial foraging–particle swarm optimization (BF-PSO) and shark smell optimization (SSO). Effective MFA design is obtained using the suggested strategy regarding various parameters.

Key words: micro strip fractal antenna (MFA) model, gain, directivity, support vector regressor (SVR) approach, elephant clan updated grey wolf algorithm (ECU-GWA)

Reddy S KARUNAKAR, Guttavelli ANITHA. Designing of optimized microstrip fractal antenna using hybrid metaheuristic framework for IoT applications[J]. Journal of Systems Engineering and Electronics, 2025, 36(3): 659-670.

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Reference	Adopted model	Feature	Challenge
[24]	SVR	Optimal impedance matching, high gain	Needs consideration on SBD features with varied geometries of antenna.
[25]	FEM model	High efficiency, greater antenna gain	Antenna matching was taken into account.
[26]	Cantor set technology	Return loss reduction, High antenna gain	Very complex.
[27]	MSSG	Return loss reduction, high gain	More attention must be paid to antenna system miniaturization.
[28]	PSO-ANN model	Size reduction ability, high design accuracy	Requires computation of different dimensions.
[29]	BF-PSO model	Low time utilization, high bandwidth	Need to focus on the cost function.
[30]	IWO	Less return loss, enhanced radiation efficiency	Resonant frequency variance is not attained well.
[31]	FEM model	Less array size, minimal return loss	Diverse switching techniques must be exploited for picking frequencies.
[32]	GA	Computational complexity reduction, high accuracy	The flexibility is not fixed at all.
[33]	SRPA	Performance efficiency enhancement, gain increased, size minimization	It is used only for short ranges.

Parameter	Value
Length/m	0.0081
Width/m	0.0055
Strip line width/m	0.0034
Feed offset	[−0.0240,−0.0020]
Num iterations	2
Height/m	0.0054
Ground plane length/m	0.0480
Ground plane width/m	0.0480
Feed location	[−0.0240,−0.0020,0.0054]
Fractal center offset	[0,0]
Substrate. length	0.0480
Substrate. width	0.0480
Substrate. shape	Box

Method		Frequency/MHz
Method		50	60	70	80
EHO	Simulated	1.7274	1.7268	1.7262	1.7255
EHO	Measured	1.7275	1.7270	1.7265	1.7258
GWO	Simulated	1.7274	1.7268	1.7261	1.7253
GWO	Measured	1.7273	1.7267	1.7260	1.7252
LA	Simulated	1.7274	1.7269	1.7262	1.7255
LA	Measured	1.7275	1.7270	1.7264	1.7256
SMO	Simulated	1.7274	1.7270	1.7264	1.7259
SMO	Measured	1.7276	1.7272	1.7266	1.7260
SSO	Simulated	1.7277	1.7272	1.7266	1.7259
SSO	Measured	1.7275	1.7270	1.7264	1.7257
SVR [24]	Simulated	1.7276	1.7271	1.7265	1.7259
SVR [24]	Measured	1.7275	1.7270	1.7264	1.7257
BF-PSO [29]	Simulated	1.7275	1.7270	1.7264	1.7257
BF-PSO [29]	Measured	1.7275	1.7270	1.7264	1.7258
ECU-GWA	Simulated	1.7379	1.7375	1.7371	1.7366
ECU-GWA	Measured	1.7376	1.7371	1.7366	1.7360

Technique	Return loss	Reflection coefficient/dB	VSWR
EHO	2.48e-06	−2.48e-06	7.01e+06
GWO	9.60e-07	−9.60e-07	1.81e+07
LA	3.28e-06	−3.28e-06	5.30e+06
SMO	2.59e-06	−2.59e-06	6.70e+06
SSA	5.69e-06	−5.69e-06	3.05e+06
SVR [24]	4.34e-07	−4.34e-07	4.01e+07
BF-PSO [29]	1.27e-06	−1.27e-06	1.37e+07
ECU-GWA	8.40e-06	−8.40e-06	1.24e+06

Constraints	EHO	GWO	LA	SMO	SSO	SVR [24]	BF-PSO [29]	ECU-GWA
Length	0.01169	0.01583	0.01716	0.00956	0.01409	0.01665	0.00885	0.0081
Width	0.01021	0.01926	0.01900	0.00577	0.01362	0.00621	0.01541	0.0054
Height	0.03482	0.01104	0.02376	0.04555	0.04951	0.00991	0.01757	0.0053
Strip line width	0.003374	0.001871	0.012358	0.002955	0.005851	0.004279	0.006373	0.00344