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An Efficient Design of Corrugated Horn Antenna

Ph.D. Synopsis

Submitted to

Gujarat Technological University

For The Degree

of

Doctor of Philosophy

In

Electronics & Communication Engineering

By

PRASHANT D. SACHANIYA

Enrolment No: 159997111010 (EC Engineering)

Supervisor

Dr. Jagdishkumar M. Rathod,

Professor,

Electronics Department,

B.V.M. Engineering College, Vallabh Vidhyanagar, Anand

DPC Members

Dr. Trushit Upadhyaya, Professor, CHARUSAT, Changa

Dr. Sarman K. Hadia, Associate Professor, GTU Graduate School of

Engineering & Technology, Ahmedabad

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TABLE OF CONTENTS

Sr. No. Contents Page

No.

1. Title of the thesis 1

2. Table of Contents 2

3. Abstract 3

4. Brief description on the state of the art of the research topic 4

5. Definition of the Problem 8

6. Objective and Scope of work 9

7. Original contribution by the thesis 9

8. Methodology of Research, Results / Comparisons 10

9. Achievements with respect to objectives 17

10. Testing of Axially Corrugated Gaussian Profiled Horn 18

11. Objective V/S Simulated V/S Fabricated design 19

12. Conclusion 19

13. Publications 21

14. References 21

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1. Abstract

In satellite communication technology, the great demands in future technology are wideband

antennas, which give high bandwidth, more directive gain, less cross-polarization, and good

beam symmetry. For this reason, the horn antenna is the better choice. A horn antenna is very

advantageous to achieve high gain and good radiation efficiency. Although horn antennas have

numerous disadvantages, many techniques have been investigated and suggested for horn

antennas to overcome these disadvantages. One approach is the different structure of the horn

antenna, and it is a corrugated horn antenna.

In this thesis, the main research work focused on the novel design of the corrugated horn

antenna, which will be optimizing the different antenna parameters. In the corrugated horn

antenna, numerous research was carried out to optimize one or two antenna parameters. The

available corrugated horn antenna works with only particular applications, and the same

antenna cannot work with different applications due to parametric limitations. The proposed

corrugated horn antenna uses the advantage of two different profiled corrugated horn antennas

in a single structure. The proposed corrugated horn antenna was designed with axial

corrugation profile and gaussian corrugation profile. The designed proposed corrugated horn

antenna name as "Axially Corrugated Gaussian Profiled Horn Antenna (ACGPHA)”. The

proposed corrugated horn antenna designed at 2.4 GHz and its wide bandwidth performance

over S-Band (2-4 GHz) applications. The designed axially corrugated gaussian profiled horn

antenna gives a better result of its all antenna parameters like gain, directive radiation pattern,

cross polarization, beam symmetry, wide bandwidth performance with size compactness. Due

to this reason, axially corrugated gaussian profiled horn antenna is defining as an efficient

design of corrugated horn antenna. The proposed axially corrugated gaussian profile horn

simulated at 2.48 GHz. The simulated result of gain is 14.27 dB, VSWR of 1.10, S11 of -26.17

dB, cross-polarization of -35.87 dB, beam symmetry of ±50 (100) degree and bandwidth of 66

% obtained. The measured result at 2.48 GHz of gain is 16.28 dBi, which is greater than the

simulated value due to the additional length of waveguide transition at the input side of the

corrugated horn. The measured value of S11 was -21.37 dB, and a cross-polarization of -30.34

dB is obtained. The measured result of the proposed corrugated horn is precisely matched with

the simulation design result. The invented design model of the proposed axially corrugated

horn antenna can work with all the design frequencies of the band by replacing the value of

lambda.

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2. Brief description on the state of the art of the research topic

In India, most satellite communication is carried out on the L and S-band due to its weather

conditions. For satellite communication, there is a high directive gain, and a wideband antenna

is required. The horn antenna gives better results in terms of gain and wide bandwidth

performance. Several types of horn antenna exist for efficient satellite communication. There

is one efficient structure of the horn antenna, and It is called Corrugated Horn Antenna; why it

is called "corrugated" because the inside wall is manufactured in a succession of "slots" and

"teeth" [1]. Corrugated horn antenna can propagate specific hybrid modes (Combination of TE

& TM mode) to produce radiation patterns with extremely good beam symmetry with low

cross-polarization levels, high beam efficiency with very low side lobes, and the potential for

wide-bandwidth performance [2-3]. Corrugated Horn Antenna is used as a direct feed antenna

for moderate gain applications and is used with a parabolic reflector antenna for achieving high

gain applications. Corrugated Horn is called as a gold antenna amongst all feed antenna [4].

Corrugated horn antennas are used in radar surveying, satellite communications, target

detection, radio astronomy, national security, microwave remote sensing, weather radar, and

the reflector antenna [4-6].

The Granet et al. presented the basic concept about corrugated horn antenna, design, parame-

ters, mode converter, and different types of corrugation profile [1]. Olver et al. described the

theory, design, performance and application of microwave feed horn for reflector antenna [2].

Clarricoats et al. reviewed the book on the corrugated horn for microwave antenna. In this book,

the theory, design, manufacture, horns of non-circular cross-section & historical background

are given [3]. Lamb et al. presented the design concept used in the development of the optical

layout of the receiver, properties of optical elements are reviewed & the suitability of various

types of the optical component was discussed [4]. Biao D. et al. presented the formula for de-

signing a corrugated horn antenna. The given formula is not only suitable for the corrugated

horn with single depth & dual depth corrugation but also suitable for the corrugation horns with

more depth corrugation, single V-shaped slots, dual V-shaped slots, single ring loaded slot, and

dual ring loaded slots [5]. T. L. Zhang et al. investigated a new design of corrugated horn an-

tenna & shaped reflector antennas. The invented design gives better results compared to con-

ventional reflectors and feed antennas [6]. A. F. Kay investigated the novel design of feed horn

antenna. It has low noise, broadband performance & high aperture efficiency [7]. A. J. Simons

et al. presented the novel design of high-performance feed for large paraboloidal reflector an-

tennas [8]. H. C. Minnett et al. investigated hybrid mode corrugated horn antenna using vertical

slots. It is capable of carrying two and three hybrid mode generation [9]. H. C. Minnett et al.

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presented the mathematical formula for propagation and radiation behaviour of corrugated

feeds. In this paper, a detailed analysis of corrugated horns was given [10].

C. G. Parini et al. investigated the cross-polar radiation pattern of corrugated waveguides the-

oretically and experimentally. Also, the theory of waveguide flange angle & higher-order mode

is given in this paper [11]. Hass Alexander et al. & Microwaves and Radar Institute is devel-

oping a steerable Cassegrain antenna and a frequency range between 8 GHz to 12.4 GHz. The

Return loss lies below -20 dB for the frequency sweep of 8 GHz to 12.4 GHz. The length of

the horn 52.5 cm, and the aperture radius 13.9 cm [12]. Wang et al. presented THz corrugated

horn antenna which was operating at 191 GHz and it has a gain of 9.8 dB, return loss of -31.2

dB, and VSWR is 1.04. The size of the silicon substrate designed antenna is 5000um x 5000um

x750um; the size of the rectangular waveguide size is 863.6um x 43l.8 um x 2500um, the width

of the horn aperture 4000 um. The corrugated groove's size loaded on the outer surface of the

antenna is 70um x 750um x 200um, and the periodic interval between the corrugated slots is

l20um [13]. Makwana Balvant et al. designed multimode corrugated feed for 7.25 GHz. The

higher-order modes TE21 and TM11 are generated in proper phase and magnitude in addition to

the dominant, TE11 mode, which is passed through the corrugated structure to generate HE11

and HE21 modes. The feed was then used as a source to illuminate the aperture of offset para-

bolic reflector antenna having an offset angle of 90 degree and minimal F/D of 0.4. The sec-

ondary patterns were simulated using the method of the physical optic. A significant reduction

in cross-polarization is obtained compared to the illumination of offset reflector by conven-

tional corrugated feed [14]. Johannes E. Mckay et al. presented higher-order modes HE11, HE12,

and HE13 generated corrugated horn antenna. Two different designs of corrugated horn are

presented for the gain of 20 dBi. The first was designed to improve sidelobe minimization with

a length of only 15.6λ long with -60 dB cross-polarization. The second was designed to opti-

mize the horn's size further, and it is 4.8λ long with a cross-polarization level of -35 dB. The

proposed design of the horn works at 94 GHz with a 20% bandwidth [15].

Hon Ching Moy-Li et al. presented the use of a 3-layer 5×5 Frequency Selective Surfaces (FSS)

to enhance the Gain of a horn antenna with radial corrugations. The directivity of 3.78 dB and

the length of the antenna is 1.32λ at 20.45GHz [16]. Gupta Jay Vishnu et al. presented the

development of the ANFIS based CAD model to design a compact axial corrugated horn

antenna. It was demonstrated that, once the ANFIS model is properly trained, the horn can be

easily designed with less processing time, minimum computational resources, and with high

accuracy. The antenna was designed at 15 GHz, and the check result between 12 to 18 GHz.

The proposed model were ao = 46.5 mm, Ltotal = 79.1 mm, N = 15, w = 1.97mm, t = 0.49 mm

[17]. Junbo Wang et al. presented the 94GHz compact tanh/linear profiled horn and it has

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achieved a 50dB level of side lobes and -64 dB level of cross-polarization, which is suitable

for the high-performance reflector applications systems [18]. Yang Wu et al. presented the two

different wideband corrugated horns for the square kilometer array, operating between 2.8 GHz

to 5.18 GHz. First, the wide flare horn was designed using available equations and methods,

but the results are not acceptable. The second design is compact, and it is well work with a

higher frequency. The newly designed corrugated horn has a return loss of 20 dB at 2.8 GHz.

The result shows that the aperture efficiency is above 86 % and achieved well over the whole

band [19]. Pengyu Zhang et al. investigated the modal matching method used for axially

dielectric rod loaded corrugated horn antenna. The rexolite loaded axially corrugated horn was

investigated for the frequency sweep between 17 GHz to 33 GHz. The improved result of gain,

return loss, and cross-polarization was obtained in this design [20].

Gonzalo et al. presented the gaussian profile corrugated horn. Higher conversion efficiency

was obtained in the throat region due to the geometrical Gaussian profile. The newly designed

Gaussian profile corrugated horn gives the better result of cross-polarization and beam sym-

metry. The proposed Gaussian profile corrugated horn is designed for HISPASAT 1C and HIS-

PASAT 1D satellite [21]. A. C. Ludwig presented the three different definitions of cross-po-

larization. The definition was discussed for several applications [22]. C. A. Balanis presented

the book on “antenna theory: analysis & design. In the chapter, a high gain antenna and the

theory of corrugated horn antenna are presented [23]. C. Granet presented the different types

of corrugation profiles with their design equations [24]. G. L. James presented TE11 to HE11

mode converter using a circular waveguide. The mode converter consists of only five slots and

achieves return loss better than 30 dB over the band 2.7 < Ka < 3.8 [25]. Mun Seok Choe et al.

investigated mode transition behaviour from half to quarter wavelength in F-band (90-140

GHz) TE11 to HE11 converter of varying corrugation depths [26]. Salimi et al. presented a com-

pact circular corrugated horn antenna with low sidelobe level generation. In this design Gauss-

ian profile of corrugation is used. This paper achieved a -50 dB cross-polarization level [27].

Mac A. et al. presented the design of a corrugated conical horn antenna. The wideband & nar-

rowband horns are considered. The result comparison of the wideband and narrowband horn

was presented [28]. Wang et al. designed a tanh profiled corrugated horn antenna. The invented

design obtained -40 dB side lobe level & -58 dB cross-polarization level at 322 GHz [29].Zhao

et al. presented the miniaturization design of corrugated horn for Ka-band. It has vertical &

horizontal corrugation slots. Due to this method the size of the horn antenna was reduced [30].

Abbas Azimi et al. presented the new compact design of a wide bandwidth corrugated horn

antenna. The antenna was designed over 8 to 18 GHz. The VSWR of the said antenna was less

than 1.85 over the entire bandwidth. The antenna gain increased from 12.5 dB to 16 dB [31].

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Soares et al. were designed a corrugated horn for the CosmoGal satellite. The mission will

collect the radiation of the cosmic microwave background by a radiometer in three different

radio astronomy frequency bands (10.6-10.7 GHz, 15.35-15.4 GHz, and 23.6 GHz-24 GHz).

The directivity of 23 dBi, sidelobe level below -35 dB & cross-polarization below -45 dB was

obtained [32]. McElhinney et al. were constructed a quasi-optical corrugated horn antenna. The

horns convert a cylindrical TE11 mode into free space TEM00 mode over the frequency band of

84 to 104 GHz. The design gets a reflection of -35 dB & Gaussian coupling efficiency of 97.8%

[33]. Teniente et al. presented a combined structure of horizontal and vertical corrugation slot-

ted corrugated horn antenna. The designed antenna gives wider bandwidth performance [34].

Yang C. et al. presented a tri-pin, tri-mode corrugated horn antenna. The designed antenna

improves the cross-polarization of 30.5 dB to 48.2 dB [35]. Zeng L. et al. were invented wide-

band profiled corrugated feed horns for multichroic application. This feed horn has a return

loss of -25 dB & cross-polarization of -30 dB. The performance is close to the ring-loaded

corrugated horn antenna. It is easy to fabricate at millimeter wavelengths [36]. Schwerthoeffer

et al. presented the relationship between Gaussian beam and reflector antennas. Also, the con-

ical corrugated horn antenna works between 26.5 to 40 GHz [37]. Addamo G. et al. presented

a reduced-order method based on the Krylov subspace concept and singular value decomposi-

tion for the analysis of conical corrugated horn antenna. The designed wideband corrugated

horn antenna works on Ka-band [38]. Tao Hong et al. present a large aperture conical corru-

gated horn with a sine profile. It is the compact version of a corrugated horn antenna. The

designed antenna has a VSWR of less than 1.15 in working band (32, 35 & 38 GHz) [39]. B.

M. Thomas et al. investigated the procedure for the design of wideband corrugated conical

horn. In this design ring loaded slot mode converter is used. The horn flare angle of 30° was

selected for optimum configuration. It has been shown that a return loss is better than 30 dB

and cross-polar level -30 dB was achieved for a bandwidth ratio of 2.1:1 [40].

G. G. Gentili et al. have analyzed dual profile corrugated circular waveguide horn. In this paper,

the phase center of the horn can be successfully controlled by varying the exponential profile

length and its variations with frequency are considerably smaller than that of linear profile

horns [41]. Gupta Jay Vishnu et al. presented the proposed U-band hybrid corrugated horn

antenna & it achieved similar performance to that of the conventional corrugated horn antenna.

The paper also includes the sensitivity analysis & issue that conventional corrugated horns

facing while fabrication [42]. Mohammad Hossein Roshan Zamir et al. investigated a new de-

sign of TE11 to HE11 mode converter for corrugated horn antenna. The mode converter with

novel slots provides low reflection compared to all mode converters. In this design bandwidth

ratio of 2:1 with return loss better than 25 dB is possible [43]. Giuseooe Addamo et al. presented

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the design of a compact dual-band circular corrugated horn for satellite application in the Ku/K

band. The designed horn antenna works in the transmission mode on [10.7, 12.75] & [17.7,

21.2] GHz & in the receiver band [13.0, 14.5] GHz [44]. Jia-chi Samuel chieh et al. were pre-

sented the development of a Ku band (10-16 GHz) corrugated conical horn antenna using 3-D

print technology or stereolithography. The antenna is printed using ABS, a thermoplastic, and

then coated with conductive paint. The designed antenna achieves a gain of 19.6 dBi at 16 GHz.

The VSWR remains 1 to 1.92 for 11 to 18 GHz [45]. Dhaval Pujara et al. presented the devel-

opment of an Adaptive Neuro-Fuzzy Interface System (ANFIS) based model for predicting the

performance of pyramidal and conical corrugated horn antenna. The advantage of the proposed

model takes less time & minimum computational resources compared to convention testing

software [46]. L. J. Foged et al. discuss the achievable performance & limitations of wideband

probes with multiple corrugated apertures. The design aperture covering up to 1:2 bandwidth

in the L to Ka-band range [47]. S. B. Sharma et al. presented the design & radiation character-

istics of a dual-mode corrugated matched feed horn. This type of feed improves the cross-po-

larization of an offset reflector antenna. In this design higher-order, HE21 mode is added with

HE11 mode to configure a dual-mode corrugated horn antenna [48].

3. Definition of the Problem

The main objectives of the research work are to optimize the different parameters of Corrugated

Horn Antenna so that the efficient design of corrugated horn antenna will work with all required

applications and the design model of Corrugated Horn Antenna can fit with all frequency band

of applications. The research title defined as:

“An Efficient Design of Corrugated Horn Antenna”

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4. Objective and Scope of work

The main objectives of the research work are to optimize the different parameters of the

Corrugated Horn Antenna, and these are defined in the below table:

4.1. Objectives of the Proposed Corrugated Horn Antenna

Sr. No. Antenna Parameters Objective Value of the Proposed Design

1. Gain Greater Than 10 dB

2. Frequency Band S Band (2-4 GHz)

3. VSWR 1

4. S11 Parameter Better than -20dB

5. Cross Polarization Better than -20dB

6. Beam Symmetry ±20 degree (40 degree)

7. Bandwidth Greater than 20%

8. Size Compact

9. Fabrication Difficulty Should be less

10. Cost Less to medium

11. Application Design model should work with All Frequency band

of Applications.

5. Original contribution by the thesis

In this thesis, five different types of corrugated horn antenna are designed and simulated using

ANSIS HFSS software. The details of each corrugated horn antennas are given below:

5.1. Linear Profiled Corrugated Horn Antenna

5.2. Axially Corrugated Horn Antenna

5.3 Compact Profiled Corrugated Horn Antenna

5.4 Gaussian Profiled Corrugated Horn Antenna

5.5 Axially Corrugated Gaussian Profiled Corrugated Horn Antenna (Dual Profiled Corrugated

Horn Antenna)

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6. Methodology of Research & Results Comparisons

6.1 Methodology of Research

Fig. 1 Flow of Research Methodology applied for designing a Corrugated Horn

6.2 Results & Design Comparison

The structure of Corrugated Horn antenna divides in mainly three parts:

1. Input wave guide

2. Mode converter

3. Corrugation profile.

The basic constructional view of corrugated horn Antenna shown in Fig.1

Fig. 2 Basic Structure of Corrugated Horn Antenna [1]

Selection of Frequency band, Cut-

off Frequency and Application

Selection of Shape of Horn

Antenna

Design of Mode Converter

(TE11 to HE11)

Design & Optimize the Linear

Profiled Corrugated Horn Antenna

Design & Optimize the Axial

Profiled Corrugated Horn Antenna

Design & Optimize the Compact

Profiled Corrugated Horn Antenna

Design & Optimize the Gaussian

Profiled Corrugated Horn Antenna

Proposed Axially Corrugated

Gaussian Profiled Horn Antenna

Optimize the different antenna

parameters of ACGPHA

Compare Proposed Antenna with

previous research paper/work

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6.2.1. Input Waveguide:

There are two methods available for the selection of waveguide:

Method 1: Input radius ai=3λ/2π

Method 2: EIA standard waveguide selection

6.2.2. Mode Converter:

In this design of Corrugated Horn Antenna, the circular waveguide select as an input

waveguide. The circular waveguide has TE11 as a dominant mode for wave propagation. The

corrugation profiled part has required propagating Hybrid mode (HE11) for wave propagation.

That is why the second part of the corrugated horn antenna is a Mode converter. Here in this

research work, the TE11 to HE11 mode converter is required to smooth transition between two

different modes.

There are three types of mode converter available for hybrid mode conversion:

1. Variable depth slot mode converter.

2. Variable pitch to width slot mode converter.

3. Ring loaded slot mode converter.

The variable depth slot mode converter is widely used and simple to construct TE11 to HE11

mode converter. Variable pitch to width mode converter does not satisfy the design criterion of

S-Band frequency. Ring loaded slot mode converter gives a little bit better result compare to

Variable depth slot mode converter, but it has a large design difficulty. The Variable depth slot

mode converter is used as a main TE11 to HE11 mode converter to design a proposed design of

corrugated horn antenna.

6.2.3. Corrugation Profile:

There is numerous research work already carried out for the different types of Corrugation

profiles. In this thesis, three corrugated profiles are used as a final optimized design of

corrugated horn antennas. These are linear profile, axial profile, and Gaussian profile

corrugation part.

There are five different proposed corrugated horn antennas designed and simulated to find out

the final, efficient design of corrugated horn antennas.

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6.2.3.1. Linear Profiled Corrugated Horn Antenna (LPCHA)

There is a simple profile corrugated horn antenna is Linear Profiled Corrugated Horn Antenna,

and it is widely used Corrugated Profiled in designing a Corrugated Horn antenna. The

proposed LPCH at design frequency 2.48 GHz is shown in Fig. 3. The S11 Parameter of LPCH

is shown in Fig.4. It is -24.1008 dB at 2.48 GHz and below -23 dB for the entire S-Band. The

Gain, Cross Polarization, and Beam Symmetry of Proposed LPCH are 20.6049 dBi, -30.952

dB, and ± 30 degrees (60 degrees) at 2.48 GHz shown in Fig.5. The 3D radiation pattern of

LPCH is shown in Fig. 5.

Fig. 3 Side, Top and 3D view of Proposed Linear Profiled Corrugated Horn Antenna

Fig. 4 S11 Parameter Proposed Linear Profiled Corrugated Horn Antenna

Fig. 5 Gain, Cross Pol. & 3D Radiation Pattern of Proposed Linear Profiled Corrugated Horn

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6.2.3.2. Axial Profiled Corrugated Horn Antenna (APCHA)

Axially corrugated horn antenna is the compact profiled of a corrugated horn antenna, and it is

provided gain up to 10 to 15 dBi. The main characteristics of axially corrugated horn antenna

are to provide size compactness with good radiation efficiency. The proposed axially profiled

corrugated horn antenna is in Fig. 6. The S11 Parameter of APCH is in Fig.7, and it is -19.6921

dB at 2.48 GHz and below -20 dB for the entire S-Band. The Gain, Cross Polarization, and

Beam Symmetry of Proposed LPCH are 15.1661 dB, -15.1661 dB, and ±10 degrees (20

degrees) at 2.48 GHz shown in Fig.8. The 3D radiation pattern of APCH is in Fig. 8.

Fig. 6 Side, Top and 3D view of Proposed Axial Profiled Corrugated Horn Antenna

Fig. 7 S11 Parameter of Proposed Axial Profiled Corrugated Horn Antenna

Fig. 8 Gain, Cross Pol. & 3D Radiation Pattern of Proposed Axial Profiled Corrugated Horn

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6.2.3.3 Compact Profiled Corrugated Horn Antenna (CPCHA)

The Compact Profiled Corrugated Horn has the advantage of size compactness with good beam

symmetry. The proposed Compact Profiled Corrugated Horn antenna is shown in Fig. 9. The

S11 Parameter of CPCH is shown in Fig. 10. It is -22.6486 dB at 2.48 GHz and below -10 dB

for the entire S-Band. The Gain, Cross Polarization, and Beam Symmetry of Proposed CPCH

are 16.2787 dB, -33.7292 dB, and ± 40 degrees (80 degrees) at 2.48 GHz shown in Fig. 11. The

3D radiation pattern of CPCH is shown in Fig. 11.

Fig. 9 Side, Top and 3D view of Proposed Compact Profiled Corrugated Horn Antenna

Fig. 10 S11 Parameter of Proposed Compact Profiled Corrugated Horn Antenna

Fig. 11 Gain, Cross Polarization & 3D Radiation Pattern of Proposed Compact Profiled

Corrugated Horn

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6.2.3.4 Gaussian Profiled Corrugated Horn Antenna (GPCHA)

Gaussian Profiled Corrugated Horn has provided a fair value of cross-polarization and good

beam symmetry. The proposed Gaussian Profiled Corrugated Horn antenna is shown in Fig.

12. The S11 Parameter of GPCH is shown in Fig.13. It is -30.2966 dB at 2.48 GHz and below -

25 dB for the entire S-Band. The Gain, Cross Polarization, and Beam Symmetry of Proposed

GPCH are 16.8229 dB, -29.8614 dB, and ± 40 degrees (80 degrees) at 2.48 GHz shown in

Fig.14. The 3D radiation pattern of GPCH is shown in Fig. 14.

Fig. 12 Side, Top and 3D view of Proposed Gaussian Profiled Corrugated Horn Antenna

Fig. 13 S11 Parameter of Proposed Gaussian Profiled Corrugated Horn Antenna

Fig. 14 Gain, Cross Pol. & 3D Radiation Patt. of Proposed Gaussian Profiled Corrugated Horn

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6.2.3.5 Axially Corrugated Gaussian Profiled Corrugated Horn Antenna (ACGPHA)

The Proposed Axially Corrugated Gaussian Profiled Horn antenna is a dual profiled corrugated

horn antenna. It is consists of an axially profile corrugated horn antenna, and Gaussian profiled

corrugated horn antenna. The Axially profiled corrugated horn antenna has an advantage of

size compactness and good radiation pattern. The Axially corrugated horn is described in

section 6.2.3.2. The Gaussian profiled corrugated antenna has a lower value of cross-

polarization and good beam symmetry, designed and simulated in section 6.2.3.4. The

advantage of both profiled used in a single structure is a proposed design of the efficient design

of corrugated horn antenna, i.e., Axially Corrugated Gaussian Profiled Horn Antenna.

The proposed Axially Corrugated Gaussian Profiled Horn Antenna is shown in Fig. 15. The

S11 Parameter of ACGPH is shown in Fig.16. It is -26.1751 dB at 2.48 GHz and below -20 dB

for the entire S-Band. The Gain, Cross Polarization, and Beam Symmetry of Proposed ACGPH

are 14.2743 dB, -35.8704 dB, and ± 50 degrees (100 degrees) at 2.48 GHz shown in Fig.17.

The 3D radiation pattern of ACGPH is shown in Fig. 17, and there is a lower value of side and

back-lobe.

Fig. 15 Side, Top and 3D view of Proposed Axially Corrugated Gaussian Profiled Corrugated

Horn

Fig. 16 S11 Parameter of Proposed Axially Corrugated Gaussian Profiled Corrugated Horn

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Fig. 17 Gain, Cross Polarization & 3D Radiation Pattern of Proposed Axially Corrugated

Gaussian Profiled Corrugated Horn

7. Achievements with respect to objectives

7.1 Comparison between Proposed Designs of Corrugated Horn Antennas

Antenna

Parameters

Linear

Profiled

Corrugated

Horn

(LPCH)

Axial

Profiled

Corrugated

Horn

(APCH)

Compact

Profiled

Corrugated

Horn

(CPCH)

Gaussian

Profiled

Corrugated

Horn

(GPCH)

Axially

Corrugated

Gaussian

Profiled

Horn

(ACGPH)

VSWR 1.1330 1.2312 1.1592 1.0630 1.1033

S11

Parameter -24.1008 dB -19.6921 dB -22.6486 dB -30.2966 dB -26.1751 dB

Gain 20.6049 dB

(20 dB)

15.1661 dB

(15 dB)

16.2787 dB

(16 dB)

16.8229 dB

(15 dB)

14.2743 dB

(15 dB)

Cross

Polarization -50.2376 dB - 15.5931 dB -33.7292 dB -29.8614 dB -35.8701 dB

Beam

Symmetry

±25 Degree

(50 Degree)

±10 Degree

(20 Degree)

±40 Degree

(80 Degree)

±35 Degree

(70 Degree)

±50 Degree

(100 Degree)

Length of an

Antenna 656.40 mm 152.37 mm 828.66 mm 425.00 mm 316.50 mm

No. of

Corrugation 30 10 12 25 15

Aperture

Radius 268.28 mm 210.16 mm 153.21 mm 206.68 mm 158.4 mm

Fabrication

Difficulties Difficult Easy Easy Medium Medium

Page 18 of 25

7.2 Design dimension of Proposed Efficient Design of Corrugated Horn Antenna: ACGPHA

Sr. No. Design Parameters Design Value

1. Input Circular Waveguide (ai) WG 451 (57.29mm)

2. Mode Converter (TE11 to HE11) Variable Depth Slot Mode Converter

3. Corrugation Profile Dual Profile (Axially + Gaussian)

4. No. of Slots (NSlots) (3+12) = 15 Slots

5. Profile Angle (θ) 45 Degree

6. Pitch to width ratio (δ) 0.72

7. Length (L) 316.5 mm

8. Aperture Radius (ao) 158.4 mm

9. Material Aluminum

8. Testing of Axially Corrugated Gaussian Profiled Horn Antenna

The proposed corrugated horn antenna was tested using Vector Network Analyser for

return loss measurement. The Anechoic Chamber is used to test the gain, radiation pattern,

and cross-polarization of the corrugated horn antenna. The value of return loss is measured

in Vector Network Analyser, and the photographs are shown in Fig. 18.

Fig. 18 Testing of Axially Corrugated Gaussian Profiled Horn Antenna using Vector Network

Analyser

The result of the gain, radiation pattern, and cross-polarization is obtained from the testing

proposed axially corrugated horn antenna in Anechoic Chamber. The photograph of testing

a corrugated horn antenna is shown in Fig. 19 and 20.

Page 19 of 25

Fig. 19 Standard Pyramidal horn as a

transmitter for testing of an antenna

Fig. 20 Axially Corrugated Gaussian Profile

Horn as a Receiver in the testing of an

antenna

9. Objective design V/S Simulated design V/S Fabricated design

Antenna

Parameters Objective Design Simulated Design Fabricated Design

Design Frequency 2.48 GHz 2.48 GHz 2.48 GHz

Frequency Band S-Band (2-4 GHz) S-Band (2-4 GHz) S-Band (2-4 GHz)

Gain > 10 dB 14.2743 dB (15 dB) 16.28 dB (15 dB)

VSWR 1 1.1033 (2.48 GHz) 1.1867 (2.48 GHz)

S11 Parameter > -20 dB -26.17 dB (2.48 GHz) -21.37 dB (2.48 GHz)

Cross Polarization > -20 dB -35.87 dB (2.48 GHz) -30.34 dB (2.48 GHz)

Length of Horn Compact 316.80 mm (≈2.6λ) 545 mm (≈4.4λ)

Aperture of Horn Compact 158.4 mm (≈1.3λ) 196.5 mm (≈1.6λ)

Bandwidth (%) 20 % 66.66% 60%

Fabrication

Difficulties Less to Medium

Medium

(p=15.1mm, w=10.9

mm, t=4.2 mm)

Medium

(p=15mm, w=11 mm,

t=4 mm)

Cost Less to Medium Approx. 1 Lac. INR 85,000/- INR

10. Conclusion

There are five designs of the proposed corrugated horn are presented in this research

work. The proposed design of corrugated horn was designed at 2.48 GHz and optimized

for the whole S-Band (2-4 GHz).

The first design, linear profiled corrugated horn was very simple to construct and the

most widely used corrugation profile. There was a number of optimization carried out

Page 20 of 25

for the excellent result of antenna parameters. The linear profiled corrugated horn had

an excellent result of S11, gain, directive radiation pattern, but that had only one main

disadvantage of larger length (≈6λ). So alternate profile was used for the size compact-

ness.

There was a two different design of proposed corrugated horn antenna designed and

simulated for the size compactness. There was an axial profile corrugated horn and

compact profile corrugated horn antenna.

The axial profiled corrugated horn was small in dimensions, but it had a limited gain,

cross-polarization, and beam symmetry. The compact profiled corrugated horn had a

fair value of S11, gain, directive radiation pattern but it had a compromised value of

cross-polarization and beam symmetry. In both compact profiles, there was an issue

with cross-polarization and beam symmetry.

To improve the value of cross-polarization and beam symmetry, the Gaussian profile

horn was designed and it had given the good value of gain, directive radiation pattern,

cross-polarization, and beam symmetry but it had only one disadvantage of larger

length.

The next task was to implement an axial profile and gaussian profile in a corrugation

horn antenna. The axial profile corrugated horn has an advantage of size compactness

while the gaussian profile has an advantage of high gain, good value of cross-polariza-

tion, and beam symmetry. The combined structure of corrugated horn was invented to

optimize all the objectives parameters of an efficient design of corrugated horn antenna.

The proposed axially corrugated gaussian profile corrugated horn is the combination of

two profiles and this design gets optimum results in terms of all mentioned antenna

parameters. At the design frequency (2.48 GHz), the simulated result of gain was 14.27

dB, VSWR of 1.10, S11 of -26.17 dB, cross-polarization of -35.87 dB, beam symmetry

of ±50 (100) degree and bandwidth of 66 % obtained. The measured result at 2.4 GHz

had a gain of 16.28 dB, which was greater than the simulated value due to the additional

length of waveguide transition at the input side of the corrugated horn. The measured

value of S11 was -21.37 dB, and a cross-polarization of -30.34 dB was obtained. The

proposed corrugated horn also works with the entire S-band. The result of simulated

and measured was almost the same so that it can be defined as an efficient design of

corrugated horn antenna.

The simulated design of the proposed axially corrugated gaussian profile horn has a

length of 2.6λ long and the aperture radius of 1.3λ long while the fabricated design has

Page 21 of 25

a length of 4.4λ and aperture radius of 1.6λ. So proposed corrugated horn is compact

compared to the available corrugated horn antenna.

The invented design model of the proposed axially corrugated gaussian profiled horn

antenna can work with all the band frequency by replacing the value of λ.

11. Publications

Paper Published

[1] Prashant D. Sachaniya, Honey Dhandhukia, Jagdish M. Rathod. "Review and Analyze Low

Cross Polarized Feed for Offset Parabolic Reflector Antenna for S-Band Application.” Journal

of Communication Engineering & Systems. 2018; 8(3): 30–36p. [ISSN: 2249-8613 (Online),

ISSN: 2321-5151 (Print)] - (UGC Approved)

[2] Sachaniya Prashant, Siddharth Shah, and Jagdish Rathod. "Hybrid Feed Horn for S-band

Application." 2019 IEEE Indian Conference on Antennas and Propagation (InCAP). IEEE,

2019. [DOI: 10.1109/InCAP47789.2019.9134503] - (Scopus Indexed)

[3] Prashant D. Sachaniya, Jagdishkumar M. Rathod, "Miniaturization of asymmetrical

gaussian profiled corrugated horn." IOP Conference Series: Materials Science and

Engineering. Vol. 1070. No. 1. IOP Publishing, 2021.[DOI:10.1088/1757-

899X/1070/1/012078 - (Scopus Indexed)

Book Chapter

[1] Prashant D. Sachaniya, Jagdishkumar M. Rathod. "Design and Fabrication of Axially

Corrugated Gaussian Profiled Horn Antenna" Smart Antenna: Latest Trends in design and

Application. Springer Book-S219 (Under Publiction Process)

Patent

[1] Prashant Dilipbhai Sachaniya, Jagdishkumar M. Rathod. "Novel Design of Corrugated

Horn Antenna for Satellite Applications" Indian Patent, Application No: 202121004770,

Application date: 03 February 2021. (Published in Journal & Under Review Process)

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