Mutual Coupling Between Coax-fed Rectangular Microstrip Antennas Embedded in Layered Uniaxial Anisotropic Dielectrics Benjamin D. Braaten* Dimitrios E.

Slides:

Advertisements

Similar presentations

Prof. David R. Jackson ECE Dept. Spring 2014 Notes 41 ECE

Advertisements

Design of a Low-Noise 24 GHz Receiver Using MMICs Eric Tollefson, Rose-Hulman Institute of Technology Advisor: Dr. L. Wilson Pearson.

Notes 12 ECE Microwave Engineering Fall Surface Waves Prof. David R. Jackson Dept. of ECE Fall 2011.

EKT 441 MICROWAVE Communications

A Metamaterial-Based Series Connected Rectangular Patch Antenna Array for UHF RFID Readers Benjamin D. Braaten Sayan Roy* Sanjay Nariyal Masud A. Aziz.

KNOWLEDGE SHARING TALK ON STUDY OF MICROSTRIP ANTENNA.

Mohammad Hossein Nemati, Ibrahim Tekin ** Electronics Engineering, Sabancı University, Istanbul, Turkey 1 A 77GHz on-chip Microstrip.

Modeling Multiple Printed Antennas Embedded in Stratified Uniaxial Anisotropic Dielectrics Ph.D. Candidate: Benjamin D. Braaten Electrical and Computer.

Microstrip Reflectarrays Myths and Realities JINA Conference David M

Microwave Engineering Instructor: Athar Hanif

Nasimuddin1 and Karu Esselle2

National Institute of Science & Technology Technical Seminar Presentation-2004 Presented By: Danish Kumar Hotta [EC ] Compact Microstrip Antenna.

THIS PRESENTATION CONSISTS OF 1.Introduction 2.Purpose of DRA 3.Structure of DRA 4.Excitation methods 5.Radiation patterns 6.Factors effecting the Resonant.

A Conformal CPW Folded Slot Antenna Array Printed on a Kapton Substrate Masud A. Aziz Sayan Roy* Layne A. Berge Irfanullah Sanjay Nariyal Benjamin D. Braaten.

A NEW PRINTED QUASI-LANDSTORFER ANTENNA

A Parametric Study on the Platform Tolerance of RFID Antennas and their Performance Enhancement with Artificial Magnetic Conductors A. S. Hoenshel and.

Analytic Expressions for Small Loop Antennas-With Application to EMC and RFID Systems Benjamin D. Braaten Electrical and Computer Engineering North Dakota.

Microwave Engineering, 3rd Edition by David M. Pozar Copyright © 2004 John Wiley & Sons Figure 9-1 (p. 443) Spin magnetic dipole moment and angular momentum.

Faisal Abedin Advisor: Dr. Mohammod Ali

A Multilayered Broadband Reflect-Array Manuel Romero.

Properties of Multiple Microstrip Antennas in Several Layers of Anisotropic Material A Dissertation Proposal By Benjamin Braaten February 19, 2008.

SDARS Receiver Front-End (Design Review)

UNDER THE GUIDANCE OF MR. A.K. DUA (KIET,GHAZIABAD) Design And Simulation Of Rectangular Patch Antenna Presented By:- Aali garg Aurv Sharma Jagveer Singh.

Benjamin D. Braaten* Masud A. Aziz Mark J. Schroeder Hongxiang Li

A Reduced Frequency Printed Quasi-Yagi Antenna Symmetrically Loaded with Meander Open Complementary Split Ring Resonator (MOCSRR) Elements Joshua Anderson.

High-Frequency RFID Tags: An Analytical and Numerical Approach for Determining the Induced Currents and Scattered Fields Benjamin D. Braaten Electrical.

1 Platform-Tolerant RFID Tag Antenna Y. C. Or (1), K. W. Leung * (1), R. Mittra (2), and K.V.S. Rao (3) (1). Wireless Communications Research Centre and.

Microwave Engineering, 3rd Edition by David M. Pozar

1 Antenna Performance in High-Voltage Corona Marcin M. Morys Dr. Gregory D. Durgin School of Electrical and Computer Engineering Georgia Institute of Technology.

Microwave Engineering, 3rd Edition by David M. Pozar Copyright © 2004 John Wiley & Sons Figure 3.1 (p. 92) (a) General two-conductor transmission line.

Introduction to Horn Antennas

Analysis of Thin Wire Antennas Author: Rahul Gladwin. Advisor: Prof. J. Jin Department of Electrical and Computer Engineering, UIUC.

How to achieve a homogeneous sensitivity in THz detector arrays

An Overview of the Theory and Applications of Metasurfaces: The Two-Dimensional Equivalents of Metamaterials IEEE Antennas and Propagation Magazine,

Half-Power Beamwidth of a Self-Adapting Conformal 1 x 4 Microstrip Array Benjamin D. Braaten* Masud A. Aziz Sayan Roy Sanjay Nariyal ECE Department North.

Design and Miniaturization of an RFID Tag Using a Simple Rectangular Patch Antenna for Metallic Object Identification Mun Leng Ng Auto-ID Adelaide.

Antennas & Propagation

Near Field Antenna Measurements for Cellular Phone Certification Ahlia M. Tillman, John Rzasa, Bandar Hakim, Quirino Balzano, and Christopher C. Davis.

Pattern Diversity Compact Patch Antenna M. S. Ruiz Palacios, M. J. Martínez Silva Universidad de Guadalajara, Jalisco, México Abstract— Diversity is a.

The Fundamental Physics of Directive Beaming at Microwave and Optical Frequencies in Terms of Leaky Waves Saman Kabiri, Master’s Student Dept. of Electrical.

A New Equivalent Circuit Extraction Method For Quasi-static Regions Benjamin D. Braaten Dr. Robert M. Nelson Yuxin Feng North Dakota State University.

Understanding the Electromagnetic Characteristics of Real Metamaterials via Rigorous Field Simulation Raj Mittra Electromagnetic Communication Laboratory.

A Printed Rampart-Line Antenna with a Dielectric Superstrate for UHF RFID Applications Benjamin D. Braaten Gregory J. Owen Dustin Vaselaar Robert M. Nelson.

On The Effect of Mutual Coupling on LF and UHF Tags Implemented in Dual Frequency RFID Applications Gregory J. Owen Benjamin D. Braaten* Robert M. Nelson.

1 The University of Mississippi Department of Electrical Engineering Center of Applied Electromagnetic Systems Research (CAESR) Atef Z. Elsherbeni

1 Practical considerations on train antenna design CSEM.

Introduction to Antennas & Propagation Introduction to Antennas & Propagation -1- Antennas & Propagation Wu Qun.

Mutual Coupling Between Broadside Printed Dipoles Embedded in Stratified Anisotropic Dielectrics Benjamin D. Braaten* Robert M. Nelson David A. Rogers.

Microwave Engineering, 3rd Edition by David M. Pozar Copyright © 2004 John Wiley & Sons Figure 6.1 (p. 267) A series RLC resonator and its response. (a)

Current Distribution of a Printed Dipole with Arbitrary Length Embedded in Layered Uniaxial Anisotropic Dielectrics Benjamin D. Braaten* North Dakota State.

Hanyang University 1/17 Antennas & RF Devices Lab. MODERN ANTENNA HANDBOOK by CONSTANTINE A.BALANIS ch. 4.4 – Jeong Gu Ho.

Study & Design of Micro-strip Patch Antenna

Microstrip Patch Antennas With Enhanced Gain by Partial Substrate Removal Adviser: Hung-Chi Yang Speaker: Yu-Ming Chen IEEE TRANSACTIONS ON ANTENNAS AND.

Design of a Low Return Loss Planar Inverted F Antenna (PIFA) for 4G & WLAN Applications Loaded with Metamaterial Lens Authors: Maninder Singh Varun Marwaha.

Microwave Engineering

Spring 2015 Notes 25 ECE 6345 Prof. David R. Jackson ECE Dept. 1.

Spring 2015 Notes 32 ECE 6345 Prof. David R. Jackson ECE Dept. 1.

3D printed Luneburg lens antenna for millimeter wave system Min Liang and Hao Xin Electrical and Computer Engineering Department, University of Arizona,

The Symposium Held by Nawroz University College of Engineering

ECE 6341 Spring 2016 Prof. David R. Jackson ECE Dept. Notes 41.

Antenna Design for Zigbee System

Jessore University of Science and Technology,

Frequency Reconfigurable Microstrip Patch Antenna

Antenna Design using SMTL for WiMAX/WLAN

Wireless Communications Chapter 4

A Compact Patch Antenna for Ultrawideband Application

Advisor: Dr. Yu-Jen Chi Presenting author: Yu-Ting Kao

ECE 6345 Spring 2015 Prof. David R. Jackson ECE Dept. Notes 27.

1st Week Seminar Sunryul Kim Antennas & RF Devices Lab.

Presentation transcript:

Mutual Coupling Between Coax-fed Rectangular Microstrip Antennas Embedded in Layered Uniaxial Anisotropic Dielectrics Benjamin D. Braaten* Dimitrios E. Anagnostou Keith W. Whites North Dakota State University, Department of Electrical and Computer Engineering, Fargo, North Dakota. 2. South Dakota School of Mines and Technology, Department of Electrical and Computer Engineering, Rapid City, South Dakota.

Topics  Problem Definition  Interests and Background  Mutual Coupling Results  Single anisotropic substrate  Single anisotropic superstrate  Separated by an anisotropic layer  Discussion/Conclusion North Dakota State University

Problem Definition Consider: North Dakota State University Optical axis is in the y- direction.

Interests and Background North Dakota State University The previous problem is of interest in many fields.  Microstrip antenna arrays [1].  Frequency Selective Structures (FSS) [2].  Radio Frequency Identification (RFID) [3].  IC based antennas.  “Engineered Materials” [4]. [1] David M. Pozar and Daniel H. Schaubert, “Microstrip Antennas: The analysis and Design of Microstrip Antennas and Arrays”, IEEE Press, Piscataway, NJ, [2] A.L.P.S. Campos an A.G. d'Assuncao, “Scattering parameters of a frequency selective surface between anisotropic dielectric layers for incident co-polarized plane waves,” IEEE Antennas and Propagation Society International Symposium, 2001, Vol. 4, July 8-13, 2001, p [3] K. Finkenzeller, RFID Handbook:Fundamentals and Applications in Contactless Smart Cards and Identification, John Wiley and Sons, West Sussex, England, [4] E. A. Navarro, A. Luximon, I. J. Craddock, D. L. Paul and M. Dean, “Multilayer and conformal antennas using synthetic dielectric substrates,” IEEE Antennas and Propagation, Vol. 51, No. 4, pp , 2003.

Microstrip Patch Results North Dakota State University Consider: L = 6.55 cm, W = cm, d 1 = d 2 = 1.58 cm f = 1.41 GHz.

Microstrip Patch Results North Dakota State University x d = 16.8 mm z d = mm f = 1.41 GHz Permittivity = 4.25 (chosen by isolating the patch)

Microstrip Patch Results North Dakota State University A single grounded anisotropicsubstrate (d 1 = 1.58 mm and d 2 = 0 mm.): (Pozar) David M. Pozar and Daniel H. Schaubert, “Microstrip Antennas: The analysis and Design of Microstrip Antennas and Arrays”, IEEE Press, Piscataway, NJ, 1995.

Microstrip Patch Results North Dakota State University A single grounded anisotropicsubstrate (d 1 = 1.58 mm and d 2 = 0 mm.):

Microstrip Patch Results North Dakota State University A single anisotropiccover (d 1 = 1.58 mm d 2 = 1.58 mm d 2 = 1.58 mm permittivity = 4.25):

Microstrip Patch Results North Dakota State University A single anisotropiccover (d 1 = 1.58 mm d 2 = 1.58 mm d 2 = 1.58 mm permittivity = 4.25):

Microstrip Patch Results North Dakota State University Separated by a single anisotropic layer (d 1 = 1.58 mm d 2 = 1.58 mm d 2 = 1.58 mm permittivity = 4.25):

Microstrip Patch Results North Dakota State University Separated by a single anisotropic layer (d 1 = 1.58 mm d 2 = 1.58 mm d 2 = 1.58 mm permittivity = 4.25):

Conclusion North Dakota State University  The coupling between two rectangular microstrip patch antennas in layered anisotropic dielectrics was investigated.  Initially, the E- and H-plane coupling between two microstrip antennas on a single anisotropic substrate was investigated.  It is shown that the permittivity in the y-direction (direction of the optical axis) has the largest impact on the mutual coupling in BOTH the E- and H-planes.  An increase in the permittivity of the substrate in the direction of the optical axis reduces the traditionally stronger E-plane coupling while increasing the traditionally weaker H-plane coupling.

Conclusion North Dakota State University  Next, the E- and H-plane coupling between two microstrip antennas with a single anisotropic superstrate was investigated.  It is shown that the mutual coupling is slightly reduced in both the E- and H-planes by an increase in permittivity in both directions of the superstrate (i.e., in the direction of the optical axis and in the direction orthogonal to the optical axis).  Finally, the two microstrip antennas were separated by a single anisotropic superstrate and the coupling was investigated.  It is shown that both components of the permittivity affect the mutual coupling in both the E- and H-planes.

Questions Thank you for listening! North Dakota State University