BANDWIDTH AND GAIN ENHANCEMENT OF A SLOTTED BOWTIE ANTENNA USING PARTIAL SUBSTRATE REMOVAL

Similar documents
CPW- fed Hexagonal Shaped Slot Antenna for UWB Applications

DUAL-BAND LOW PROFILE DIRECTIONAL ANTENNA WITH HIGH IMPEDANCE SURFACE REFLECTOR

DESIGN OF A NOVEL MICROSTRIP-FED DUAL-BAND SLOT ANTENNA FOR WLAN APPLICATIONS

Slot Antennas For Dual And Wideband Operation In Wireless Communication Systems

TRIPLE-BAND OMNI-DIRECTIONAL ANTENNA FOR WLAN APPLICATION

New Design of CPW-Fed Rectangular Slot Antenna for Ultra Wideband Applications

RECTANGULAR SLOT ANTENNA WITH PATCH STUB FOR ULTRA WIDEBAND APPLICATIONS AND PHASED ARRAY SYSTEMS

A MICROSTRIP ANTENNA FOR WIRELESS APPLICATION

SIZE REDUCTION AND BANDWIDTH ENHANCEMENT OF A UWB HYBRID DIELECTRIC RESONATOR AN- TENNA FOR SHORT-RANGE WIRELESS COMMUNICA- TIONS

International Journal of Modern Trends in Engineering and Research e-issn No.: , Date: 2-4 July, 2015

Investigation on Octagonal Microstrip Antenna for RADAR & Space-Craft applications

L-BAND COPLANAR SLOT LOOP ANTENNA FOR INET APPLICATIONS

Rectangular Patch Antenna to Operate in Flame Retardant 4 Using Coaxial Feeding Technique

Dual-band bow-tie antenna with parasitic elements for WLAN applications

Design and Simulation of Inverted T-Shaped Antenna for X- band Applications

Wideband Bow-Tie Slot Antennas with Tapered Tuning Stubs

DUAL BAND MONOPOLE ANTENNA FOR WLAN/WIMAX APPLICATIONS

Design and Development of a 2 1 Array of Slotted Microstrip Line Fed Shorted Patch Antenna for DCS Mobile Communication System

A Low-Cost Microstrip Antenna for 3G/WLAN/WiMAX and UWB Applications

Design of Star-Shaped Microstrip Patch Antenna for Ultra Wideband (UWB) Applications

CHAPTER 4 DESIGN OF BROADBAND MICROSTRIP ANTENNA USING PARASITIC STRIPS WITH BAND-NOTCH CHARACTERISTIC

H And U-Slotted Rectangular Microstrip Patch Antenna

CIRCULARLY POLARIZED SLOTTED APERTURE ANTENNA WITH COPLANAR WAVEGUIDE FED FOR BROADBAND APPLICATIONS

Comparison of Return Loss for the Microstrip U-Slot Antennas for Frequency Band 5-6 Ghz

ISSN: [Sherke* et al., 5(12): December, 2016] Impact Factor: 4.116

L-slotted Microstrip Patch Antenna for WiMAX and WLAN Applications

Design of a Dual Band Rectangular Microstrip Antenna

Design and Implementation of Pentagon Patch Antennas with slit for Multiband Wireless Applications

Small-Size Monopole Antenna with Dual Band-Stop Function for Ultra-Wideband Wireless Communications

High gain W-shaped microstrip patch antenna

Microstrip Patch Antenna Design for WiMAX

Planar Inverted L (PIL) Patch Antenna for Mobile Communication

Miniaturization of Microstrip Patch Antenna for Mobile Application

COMPARISON OF FEEDING TECHNIQUES FOR THE DESIGN OF MICROSTRIP RECTANGULAR PATCH ANTENNA FOR X-BAND APPLICATIONS

Effect of Height on Edge Tapered Rectangular Patch Antenna using Parasitic Stubs and Slots

AN APPROACH TO DESIGN AND OPTIMIZATION OF WLAN PATCH ANTENNAS FOR WI-FI APPLICATIONS

DESIGN AND SIMULATION OF TRI-BAND RECTANGULAR PATCH ANTENNA USING HFSS

BROADBAND SERIES-FED DIPOLE PAIR ANTENNA WITH PARASITIC STRIP PAIR DIRECTOR

QUAD-BAND MICROSTRIP ANTENNA FOR MOBILE HANDSETS

A Broadband Omnidirectional Antenna Array for Base Station

Effects of Two Dimensional Electromagnetic Bandgap (EBG) Structures on the Performance of Microstrip Patch Antenna Arrays

Bandwidth Enhancement in Microstrip Rectangular Patch Antenna using Defected Ground plane

Design of a Compact and Low-Cost Fractal-Based UWB PCB Antenna

DUAL-WIDEBAND SQUARE SLOT ANTENNA WITH A U-SHAPED PRINTED TUNING STUB FOR PERSONAL WIRELESS COMMUNICATION SYSTEMS

Design of Rectangular-Cut Circular Disc UWB Antenna with Band-Notched Characteristics

RECTANGULAR SLOT ANTENNA WITH PATCH STUB FOR ULTRA WIDEBAND APPLICATIONS AND PHASED ARRAY SYSTEMS

Parametric Analysis of Planar Circular Monopole Antenna for UWB Communication Systems

Single-Feed Triangular Slotted Microstrip Bowtie Antenna for Quad-bands Applications

DESIGN AND ANALYSIS OF MICROSTRIP FED SLOT ANTENNA FOR SMALL SATELLITE APPLICATIONS

Wideband Unidirectional Bowtie Antenna with Pattern Improvement

Design of Frequency and Polarization Tunable Microstrip Antenna

Design of Log Periodic Dipole Array Antenna Using Two Sides with Comparision of Two Dielectric Material Result

Design & Analysis Of An Inverted-T Shaped Antenna With DGS For Wireless Communication

Microstrip Patch Antenna Using Suspended Techniques

COMPACT CPW-FED SLOT ANTENNA USING STEPPED IMPEDANCE SLOT RESONATORS HARMONIC SUPPRESSION

Design and Analysis of Dual Band Star Shape Slotted Patch Antenna

Microstrip Patch Antenna with Fractal Defected Ground Structure for Emergency Management

Designing of Rectangular Microstrip Patch Antenna for C-Band Application

A Compact Triple Band Antenna for Bluetooth, WLAN and WiMAX Applications

COMPACT FRACTAL MONOPOLE ANTENNA WITH DEFECTED GROUND STRUCTURE FOR WIDE BAND APPLICATIONS

Mutual Coupling Reduction of Micro strip antenna array by using the Electromagnetic Band Gap structures

A CPW-fed triangular monopole antenna with staircase ground for UWB applications

Design of a Wideband CPW Fed Monopole Antenna with Fractal Elements for Wireless Applications

A Pair Dipole Antenna with Double Tapered Microstrip Balun for Wireless Communications

DESIGN OF A MODIFIED W-SHAPED PATCH ANTENNA ON AL 2 O 3 CERAMIC MATERIAL SUBSTRATE FOR KU-BAND

DESIGN AND SIMULATION OF WIDE BAND L-SHAPED ANTENNA

COMPACT WIDE-SLOT TRI-BAND ANTENNA FOR WLAN/WIMAX APPLICATIONS

5. CONCLUSION AND FUTURE WORK

DUAL WIDEBAND SPLIT-RING MONOPOLE ANTENNA DESIGN FOR WIRELESS APPLICATIONS

A NOVEL NOTCHED ULTRA WIDEBAND PATCH ANTENNA FOR MOBILE MICROCELLULAR NETWORK

Wide band Slotted Microstrip Antenna for Wireless communications

Compact Triple-Band Monopole Antenna with Inverted-L Slots and SRR for WLAN/WiMAX Applications

Gain Enhancement of Pyramidal Horn Antenna using EBG Technique

A COMPACT CPW-FED UWB SLOT ANTENNA WITH CROSS TUNING STUB

Design and Simulation Based Study of Microstrip E Shaped Patch Antenna Using Different Substrate Materials

Design of Narrow Slotted Rectangular Microstrip Antenna

Design of a Circularly Polarised Dual Band Notched Ultra Wideband Antenna with Fractal DGS for S-Band and C-Band Applications

Broadband Circular Polarized Antenna Loaded with AMC Structure

Irregular Pentagonal Patch Antenna For L Band Application

A COMPACT MULTIBAND MONOPOLE ANTENNA FOR WLAN/WIMAX APPLICATIONS

A Wideband Stacked Microstrip Patch Antenna for Telemetry Applications

Design of a Wideband Planar Microstrip-Fed Quasi-Yagi Antenna

NOVEL DESIGN BROADBAND CPW-FED MONOPOLE ANTENNA WITH TRAPEZIUM SHAPED-STUB FOR COMMUNICATION SYSTEM

Efficient Design of Sierpinski Fractal Antenna for High Frequency Applications

Design of Frequency Reconfigurable Antenna with Circular Patch

High Permittivity Design of Rectangular and Cylindrical Dielectric Resonator Antenna for C-Band Applications

A Millimeter Wave Center-SIW-Fed Antenna For 60 GHz Wireless Communication

R. Zhang, G. Fu, Z.-Y. Zhang, and Q.-X. Wang Key Laboratory of Antennas and Microwave Technology Xidian University, Xi an, Shaanxi , China

Study of the Effect of Substrate Materials on the Performance of UWB Antenna

Circular Patch Antenna with CPW fed and circular slots in ground plane.

CIRCULAR-SLOTTED CPW ANTENNA FOR WiMAX/C BAND APPLICATIONS

ENHANCEMENT OF PRINTED DIPOLE ANTENNAS CHARACTERISTICS USING SEMI-EBG GROUND PLANE

A Compact Dual Band Microstrip Antenna for GPS L1/GS Applications

Ultra-Wideband Patch Antenna for K-Band Applications

H. Sabri and Z. Atlasbaf Faculty of Engineering, Department of Electrical Engineering Tarbiat Modares University (TMU) Tehran, Iran

Triple Band X Shape Microstrip Patch Antenna for Ku/K Band Applications

DESIGN OF WIDEBAND TRIANGLE SLOT ANTENNAS WITH TUNING STUB

DESIGN OF MID-BAND FREQUENCY PATCH ANTENNA FOR 5G APPLICATIONS

A COMPACT SLOTTED MICROSTRIP PATCH ANTENNA FOR MULTIBAND APPLICATIONS

DRAFT. Design and Measurements of a Five Independent Band Patch Antenna for Different Wireless Applications

Transcription:

BANDWIDTH AND GAIN ENHANCEMENT OF A SLOTTED BOWTIE ANTENNA USING PARTIAL SUBSTRATE REMOVAL Mohammed K. Abu Foul 1, Mohamed Ouda 2 1: Master Student, Electrical Eng. Dept., IUG, Palestine, mabufoul@hotmail.com 2: Associate Professor, Electrical Eng. Dep., IUG, Palestine, mouda@iugaza.edu.ps ABSTRACT: This research proposes a new antenna design for gain and bandwidth enhancement of the slotted bowtie microstrip antenna using the principle of partial substrate removal. This new design is a lightweight and compact one that is suitable for broadband communications due to its high gain and wide bandwidth. The slotted bowtie shape achieves the required wide bandwidth without increasing the microstrip size. This antenna was designed to achieve a bandwidth of more than 5 GHz. Furthermore, the gain of the bowtie antenna was enhanced by more than 2 db due to the loss reduction in surface waves by using partial substrate removal. ANSOFT s High Frequency Structure Simulator (HFSS) which is based on finiteelement method (FEM) was used for the design and the simulation of the antenna. The standard antenna parameters such as gain, return loss, and radiation patterns were obtained and plotted. KEYWORDS: Bowtie antenna, Broadband, High gain, HFSS, loss reduction. I. INTRODUCTION Printed slot antennas offer an attractive solution to compact, conformal, and low-cost designs of many wireless application systems [1] due to small size, light weight, low cost, good performance, and low profile [2]. In order to use slot antennas in broadband communication systems, the antennas must have wide bandwidth with suitable gain. These requirements are achieved by using slotted bow-tie antenna [3]. A slotted bow-tie antenna is preferred because of its basic geometrical structure, broadband characteristics, and number of applications when compared to a linear wire and a printed dipole antenna. Furthermore, they allow a considerable size reduction in compare to patch antennas that leads to lower operating frequencies without increasing the overall patch area [4]. It is known that the gain of a single patch antenna is generally low [1]. There are three types of losses i.e. conductor loss, dielectric loss and surface wave loss that lower gain of a patch antenna. The conductor loss depends on the quality of the materials. The dielectric loss is dependent on the loss tangent of materials and the quality of the substrate, while the surface wave loss depends on the permittivity of materials and the substrate thickness. Although better quality selection of conductor and substrate can reduce the conductor and dielectric losses and improving the gain of the antenna, the gain of the patch antenna can be further enhanced by suppressing surface waves [5]. In this research, the effects of partial substrate removal on the performance of slotted bowtie microstrip antenna were investigated for antenna gain enhancements. The basic idea is 1

to improve the gain of a slotted bow-tie microstrip antenna by suppressing surface waves and reducing dielectric loss through partial substrate removal surrounding the antenna. This method is for ease of fabrication, which is considered a practical method to enhance gain and bandwidth of the antenna, and it s a method used when the electric permittivity ε r of the designed antenna is low. [5]. Bow-tie slot antenna geometry was studied and designed for wideband operation. The related simulation and analysis are performed using ANSOFT s High Frequency Structure Simulator (HFSS) which is based on finite-element method (FEM) which is considered the industry standard for antenna design and simulations. II. ANTENNA STRUCTURE AND DESIGN Several studies have demonstrated that the use of a partial substrate removal can enhance the gain of the antenna [5]. This method was applied and studied on the slotted bow-tie antenna. The bow-tie antenna designed is shown in Figure 1, where a substrate that has electric permittivity ε r = 2.2 and thickness H1=1.57mm was used. The antenna dimension as well as the feeding lines were designed and optimized to achieve input impedance matching to 50Ω. The antenna dimensions are given in Table 1. Figure 1: The antenna structure and design Table 1: The antenna parameters Parameter Value (mm) Parameter Value (mm) L1 8 W2 1.2 L2 2.25 W3 5 L3 1 W4 3 L4 19 H1 1.57 W1 22.9 H2 1.2 2

III. SIMULATION RESULTS The parameters of the antenna under study in this research are the substrate removal width W3, H1 which is the thickness of the substrate and the electric permittivity ε r of the substrate. Only one parameter is changed at a time during the analysis. The effect of the substrate removal, W3 equal 5mm, on the bandwidth, radiation pattern and gain of the slotted bow-tie microstrip antenna is shown in figures 2, 3 and 4. 0 comparison between with and without substrate removal -5-10 -15 S11 (db) -20-25 -30-35 -40 Without substrate removal With substrate removal -45 7 8 9 10 11 12 13 14 f (GHz) Figure 2: The return loss with and without substrate removal. Figure 3: Antenna radiation pattern with and without substrate removal. 3

Figure 4: Antenna gain with and without substrate removal at 10 GHz. It s clear that the gain was increased by more than 2dB which is considered as an excellent enhancement. Furthermore, the bandwidth with the presence of substrate removal was enhanced by 1.5 GHz. A better return loss can be obtained by optimizing the width of the substrate removal, W3. A reduction of the return loss that reflects a good impedance matching and low VSWR was obtain as shown in figure 5. 0 The effect of changing W3-5 -10-15 -20 S11 (db) -25-30 -35-40 W3=4mm -45 W3=5mm W3=6mm -50 7 8 9 10 11 12 13 14 f (GHz) Figure 5: Return loss for different values of W3. 4

Figures 6, 7 and 8 show the return loss, radiation pattern and the gain, respectively, with the substrate removal width W3=5mm for different values of substrate thickness H1. It s clear that there is a slight effect on the radiation pattern and gain and larger effect on the return loss due to shifted in the resonance frequency of the antenna. Figure 6: Return loss for different values of H1. Figure 7: Antenna radiation pattern for different values of H1. 5

Figure 8: Antenna gain for different values of H1 at 10 GHz. Figure 9 shows the return loss with W3 equals 5mm and H1 equals 1.57mm with relative permittivity ε r 2.1, 2.2 and 3.2. It can be seen clearly the effect of changing ε r on the resonance frequency of the antenna. 0 The effect of changing er -5-10 -15 S11 (db) -20-25 -30-35 er=2.1 er=2.2 er=3.2-40 7 8 9 10 11 12 13 14 f (GHz) Figure 9: Return loss for different values of ε r 6

IV. CONCLUSION The technique of using partial substrate removal and its effect on the gain and bandwidth was applied on a slotted bow-tie microstrip antenna. The antenna was designed and simulated using HFSS software. The results obtained showed that by suppressing surface waves and reducing dielectric loss, the gain of the designed antenna has been enhanced by more than 2 db with an increase of up to 1.5 GHz in the bandwidth. This new design is suitable for broadband communications applications. V. REFERENCIES [1] H. Boutayeb, and T. Denidni, Gain Enhancement of a Microstrip Patch Antenna Using a Cylindrical Electromagnetic Crystal Substrate, IEEE transactions on antennas and propagation, Vol. 55, NO. 11, November 2007 [2] A. Eldek, A. Elsherbeni, and Ch. Smith, Coplanar waveguide fed bow-tie slot antennas for wideband operations, Center of Applied Electromagnetic Systems Research, The University of Mississippi [3] M. Nagatoshi, H. Morishita, and Sh. Tanaka, A Study on an Improvement of Folded Bow-Tie Antenna by Adding Aditional Elements, IEEE international conference in Antennas and propagation (APSURSI), July 2011 [4] A. Durgun, C. Balanis, C. Birtcher, and D. Allee, Design, Simulation, Fabrication and Testing of Flexible Bow-Tie Antennas, IEEE transaction on antennas and propagation, Vol. 59, NO. 12, December 2011 [5] S. Yeap, and Z. Chen, Microstrip Patch Antennas With Enhanced Gain by Partial Substrate Removal, IEEE transaction on antennas and propagation, Vol. 58, NO. 9, September 2010 7

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback