Microstrip Antenna Design for Wireless Applications
- Length: 338 pages
- Edition: 1
- Language: English
- Publisher: CRC Press
- Publication Date: 2021-11-16
- ISBN-10: 0367554380
- ISBN-13: 9780367554385
- Sales Rank: #0 (See Top 100 Books)
The book focuses on recent advances in the field of Microstrip antenna design and its applications in various fields including Space communication, Mobile communication, wireless communication, medical implants, wearable applications etc. Scholars from Electronics/ Electrical/ Instrumentation Engineering, researchers and industrial person will benefit from this book. Students, researchers and industrial person expressed concerns about obtaining antenna measurements in various environments. The book shall provide the literature using which students and researchers would design antennas for above mentioned applications. Ultimately, it will enable users to take measurements in different environments. Young researchers pursuing their PG programs or Doctoral degree are also much interested to do their research in the micro-strip antennas, but there are very limited literatures available in recent applications. This book is intended to help such scholars in their studies and enhance the knowledge and skills in the latest happening in the Communication world like IoT, D2D, Satellite, wearable devices etc.
This book will addresses the complete functional framework workflow in printed antenna design system, such as the book:
- Explores basic and high level concepts, thus serving as a manual for those in the industry while also helping beginners to understand both basic and advanced aspects in planer antenna design issues.
- is based on the latest technologies, and covers the major challenges, issues, and advances in Micro-strip antenna design.
- provides latest techniques used for the design of antenna in terms of its structure, defected ground, MIMO and fractal design.
- explores data acquisition and case studies related to data-intensive technologies in antenna used in Internet of Things.
- provides the design of Micro-strip antenna in terms of latest applications and uses like uses in IoT and device to device communication.
Cover Half Title Title Page Dedication Table of Contents Preface Organization of the Book Part I: Overview and Introduction Part II: Performance Analysis of Microstrip Antennas Part III: Multiple-Input Multiple-Output (MIMO) Antenna Design and Its Applications Part IV: Fractal and Defected Ground Structure Microstrip Antennas Part V: Microstrip Antennas in Vehicular Communication Part VI: Importance and Use of Microstrip Antennas in IoT Part VII: Ultra-Wideband Antenna Design for Wearable Applications Part VIII: Microstrip Antenna Design for Miscellaneous Applications Editors Associate Editors Part I Overview and Introduction 1 Microstrip Patch Antenna Techniques for Wireless Applications 1.1 Introduction of Antennas 1.2 Rectangular Microstrip Patch Antennas 1.3 Fringing Effect in Microstrip Antennas 1.4 Microstrip Antenna Feeding Techniques 1.5 Comparison of Microstrip Antennas With Conventional Antennas 1.6 Advantages and Disadvantages of Microstrip Patch Antennas 1.7 Application of Microstrip Antennas 1.8 Conclusion References 2 A Review: Microstrip Patch Antennas for Ultra-Wideband 2.1 Introduction 2.2 Band-Notch Characteristics 2.3 10.6 GHz Bands 2.4 Under FCC Standard Band Greater Than 500 MHz 2.5 Conclusion References Part II Performance Analysis of Microstrip Antennas 3 Design and Performance Analysis of Microstrip Antennas Using Different Ground Plane Techniques for Wireless Applications 3.1 Introduction 3.2 Parameters of Microstrip Antennas 3.2.1 Gain 3.2.2 VSWR 3.2.3 Bandwidth 3.2.4 Return Loss 3.2.5 Shapes 3.3 Design Considerations 3.4 Fringing Effect 3.5 Principles 3.5.1 Properties 3.5.2 Feeding Methods 3.5.3 Contacting Type 3.5.4 Line Feed Microstrip 3.5.5 Probe Feed Microstrip 3.5.6 Non-Contacting Type 3.5.7 Proximity Coupled Feed 3.5.8 Aperture Coupled Feed 3.6 Performance Analysis 3.7 Simulation and Results 3.8 Applications of Microstrip Patch Antennas 3.9 Multiple-Input Multiple-Output 3.10 Fractal and Defected Ground Structure Microstrip Antennas 3.11 Microstrip Antennas for Vehicular Communication 3.12 Importance and Use of Microstrip Antennas in IoT Applications 3.13 Ultra-Wideband Antenna Design for Wearable Applications References 4 Design and Simulation of High Gain Microstrip Patch Antennas Using Fabricated Perovskite Manganite Added Polymer ... 4.1 Introduction to MPA 4.2 Miniaturization of MPA 4.2.1 Dielectric Constant for Miniaturization of MPA 4.2.2 PerPolyN for MPA Design 4.3 Introduction to Perovskite – a Dielectric Material 4.4 PerPolyN as A Dielectric Material of MPA 4.5 Global Impact of MPA 4.6 Methodology of Perovskite Synthesis 4.7 Results and Conclusion 4.7.1 Antenna Design Parameters 4.7.2 Validation of Antenna Parameters References 5 Compact Microstrip Patch Antenna Design With Three I-, Two L-, One E- and One F-Shaped Patch for Wireless Applications 5.1 Introduction 5.2 Importance of a Good Antenna Design 5.3 Review of the Existing Techniques 5.4 Antenna Design Considerations of Proposed Work 5.4.1 Antenna Structure 5.4.2 Antenna Design in IE3D 5.5 Results and Simulation 5.5.1 Voltage Standing Wave Ratio 5.5.2 S-Parameter/Return Loss 5.5.3 Gain 5.5.4 Directivity 5.5.5 Radiation Efficiency 5.5.6 Antenna Efficiency 5.5.7 Radiation Pattern 5.6 Conclusion References 6 Design of Elliptically Etched Circular and Elliptical Printed Antennas for Dual-Band 5G Mobile Applications 6.1 Introduction 6.2 Design Models of the Elliptically Etched Circular and Elliptical Printed Antennas 6.3 Results and Discussion of the Presented Antennas 6.4 Conclusions References 7 Design and Analyses of Dual-Band Microstrip Patch Antennas for Wireless Communications 7.1 Introduction 7.2 Design of a Dual-Band Patch Antenna With Double Slots (DBDS) 7.3 Radiation Performance Analysis 7.4 Directivity and Gain Analysis 7.5 Surface Current Analysis of Antenna 7.6 Design of a Dual-Band Patch Antenna With Square Ring (DBSR) 7.7 Radiation Performance Analysis 7.7.1 Directivity and Gain Analysis 7.7.2 Surface Current Analysis of Antenna 7.8 Design of a Dual-Band Antenna With Bend Slots (DBBS) 7.9 Radiation Performance Analysis 7.9.1 Directivity and Gain Analysis 7.9.2 Surface Current Analysis of Antenna 7.10 Antenna Radiation Performance Comparison 7.11 Conclusion References Part III Multiple-Input Multiple-Output (MIMO) Antenna Design and Its Applications 8 Multiple-Input Multiple-Output Antenna Design and Applications 8.1 Introduction 8.2 MIMO Technology 8.3 Implementation 8.3.1 Need of MIMO 8.3.2 The Need of Multiple Antennas 8.4 Diversity in MIMO 8.5 Design Challenges 8.6 Different Types of Antennas 8.6.1 Dipole and Monopole 8.6.2 Loop and Slot 8.6.3 Planar Antennas 8.6.4 Microstrip Antennas 8.6.5 Bow-Tie Antenna 8.6.6 Log Periodic Antenna 8.6.7 Leak Wave Antenna 8.6.8 Substrate Integrated Waveguide 8.7 Microstrip Antenna Design 8.7.1 The Transmission Line Technique 8.7.2 Cavity Mode 8.7.3 Antenna Shape 8.7.4 Single Component Antenna Without Spaces 8.7.5 H-Shaped Single Component 8.8 Diversity Technology in Mobile Communications 8.9 Antenna Arrays 8.9.1 Two-Component Cluster 8.9.2 Four-Component Antenna Cluster With Fixed Bar Controlling 8.9.3 N-Component Uniform Straight Exhibit 8.9.4 Structuring 8.9.5 Integrated Antenna 8.9.6 Phase Shifters 8.9.7 Fractal Antenna 8.10 Design of Handsets 8.11 Plan of Base Stations 8.12 MIMO Cellular Systems 8.13 Wideband 4G Communication 8.13.1 Multiband 5G Antenna Structure 8.13.2 MIMO in Cancer Recognition 8.13.3 Bluetooth MIMO 8.13.4 Antenna PDA 8.13.5 Designing Laptops 8.13.6 EBG 8.13.7 Photonic Bandgap 8.13.8 UWB MIMO Antenna 8.14 Conclusion References 9 A Survey of Fifth-Generation Cellular Communications Using MIMO for IoT Applications 9.1 Introduction 9.2 Key Capabilities of 5G Well-Defined By ITU-R 9.3 Features and Types of MIMOs 9.4 Multiple Access Techniques Used in 4G and 5G 9.5 Challenges and Solutions of 5G and MIMO 9.6 Development Scenario Towards 5G – IoT and MIMO 9.7 Conclusion Acronyms 10 Design Considerations in MIMO Antennas for Next-Generation 5G Wireless Communications 10.1 Introduction 10.2 Isolation Enhancement Techniques 10.2.1 Decoupling Network Technique 10.2.2 Parasitic Element Technique 10.2.3 Neutralization Line Technique 10.2.4 Isolation Through Metamaterial Techniques 10.3 Conclusion References 11 Design and Enhancement of MIMO Antennas for Smart 5G Devices 11.1 Introduction 11.1.1 Typical Applications 11.2 Inset Feeding 11.3 Design Calculations 11.4 Design and Simulation of MIMO Antennas 11.4.1 Design of MIMO Antenna Structures 11.4.2 Simulation Results 11.5 Conclusion References Part IV Fractal and Defected Ground Structure Microstrip Antennas 12 Compact Rhombus Rectangular Microstrip Fractal Antennas With Vertically Periodic Defected Ground Structure for Wireless ... 12.1 Introduction 12.2 Antenna Design and Configuration 12.2.1 Directivity 12.2.2 Gain 12.2.3 Bandwidth 12.2.4 Return Loss 12.2.5 Cross-Polarization 12.2.6 Antenna With VPDGS 12.2.7 Antenna With Fractal Geometry 12.3 Simulation and Experimental Results 12.4 Conclusion References 13 Design and Analysis of Heptagon-Shaped Multiband Antennas With Multiple Notching for Wireless Applications 13.1 Introduction 13.2 Proposed Antenna Design With Simulation Results 13.2.1 Design 13.2.2 Design 13.2.3 Design 13.3 Conclusion References Part V Microstrip Antennas in Vehicular Communication 14 Multifunctional Integrated Hybrid Rectangular Dielectric Resonator Antennas for High-Speed Communications 14.1 Introduction 14.2 Principle of Operation 14.3 Bandwidth Improvement Techniques 14.4 Structure of the Proposed Antenna 14.5 Results and Discussions 14.6 Conclusions References Part VI Importance and Use of Microstrip Antennas in IoT 15 Importance and Use of Microstrip Antennas in IoT: Opportunities and Challenges 15.1 Introduction 15.2 Importance and Use of Microstrip Antennas in IoT 15.2.1 Importance of Microstrip Antennas in IoT 15.2.2 Uses of Microstrip Antenna in IoT 15.2.3 Satellite Communication 15.2.4 Smart Home Applications 15.2.5 Real-Time Weather Monitoring Systems 15.2.6 Medical Applications 15.3 Multiband Microstrip Patch Antennas in IoT 15.4 Conclusion References 16 Importance and Use of Microstrip Antennas in IoT 16.1 Introduction to Microstrip Patch Antennas 16.2 Introduction to IoT 16.2.1 Importance of Antenna Design in a Wireless Or IoT Product 16.2.2 Fields Where the Term IoT Is Used 16.3 Microstrip Patch Antennas and IoT 16.3.1 Microstrip Patch Antenna Design for IoT Applications 16.3.2 Design Challenges of Antennas for IoT Applications 16.3.3 Current Trends in the Design of Antennas for IoT Applications 16.3.4 RF Energy Harvesting 16.3.5 Fractal Antennas 16.3.6 Compact Antenna for IoT Applications 16.3.7 Multiband Microstrip Patch Antennas for IoT Applications 16.3.8 Multiband Frequency Reconfigurable Antennas (WLAN, Wi-Max, and C-Band IoT Applications) 16.4 Conclusion References 17 Design of a Microstrip Patch Antenna Based On Fractal Geometry for IoT Applications 17.1 Introduction 17.1.1 Importance of Antenna Design for IoT-Based Wireless Applications 17.1.2 Different Types of Antennas 17.1.3 Isotropic Antenna 17.1.4 Dipole Antenna 17.1.5 Monopole Antenna 17.1.6 Array Antenna 17.2 Microstrip Patch Antennas for IoT Applications 17.2.1 Antenna Design 17.3 Simulation Results of Microstrip Antennas for IoT Applications 17.4 Conclusion Part VII Ultra-Wideband Antenna Design for Wearable Applications 18 UWB and NB Performance Integrated Antennas for Cognitive Radio Applications A Survey 18.1 Introduction 18.2 Reconfigurable Antenna for Cognitive Radio Applications 18.2.1 Ideal Switches 18.2.2 Pin Diodes 18.2.3 Varactor Diodes 18.2.4 FET Switches 18.2.5 MEMS Switches 18.2.6 Optical Switches 18.2.7 Comparison of Different Switches 18.3 Single-Port Reconfigurable Antenna 18.4 Multi-Port Reconfigurable Antenna 18.4.1 Reconfigurability Without Using Switches 18.5 Non-Reconfigurable Antennas for Cognitive Radio Applications 18.5.1 Single-Port Non-Reconfigurable Antennas 18.5.2 Multi-Port Non-Reconfigurable Antennas 18.6 TV White Space for Cognitive Radio Applications 18.6.1 Reconfigurable Antennas in TVWS 18.7 Conclusion References 19 Ultra-Wideband Wearable Vivaldi Antennas for Biomedical Applications 19.1 Introduction 19.2 Antenna Design and Configuration 19.2.1 Simulation Results of Vivaldi Antennas 19.3 Analysis and Comparison of Various Antenna Parameters (Calculated and Simulated) 19.4 Conclusion References 20 Ultra-Wideband Antenna Design for Wearable Applications 20.1 Introduction 20.2 Challenges in Designing Wearable UWB Antennas 20.3 Antenna Design 20.3.1 EBG-Based UWB Antenna Advantages Limitations 20.3.2 CPW Fed Tapered Slot UWB Antenna Advantages Limitations 20.3.3 Full Ground Plane UWB Antenna 20.3.4 UWB Antenna With Different Heights of the Ground Surface of CPW Feeding Advantages Limitations 20.3.5 Modified Circular UWB Antenna With DGS Advantages Limitations 20.3.6 UWB Antenna With Ashoka Chakra–Shaped Radiator Advantages Limitations 20.3.7 Circular UWB Antenna Advantages Limitations 20.3.8 Bending and Crumpling Analysis 20.3.9 Antenna Misalignment 20.3.10 SAR Analysis 20.3.11 Change in Substrate Parameters 20.4 Results 20.5 Substrate and Conductive Layer Used 20.6 Conclusion References 21 An Orthogonal Quad-Port Wearable MIMO Antenna for UWB Applications 21.1 Introduction 21.2 Antenna Design Structure 21.3 Analysis of the Proposed Structure 21.4 Specific Absorption Rate Analysis 21.5 Conclusion References Part VIII Microstrip Antenna Design for Miscellaneous Applications 22 Case Study: Design and Simulation of the 5G Microstrip Patch Antenna With a Phase Shifter and Dodecagonal Prism ... 22.1 Introduction 22.2 Single-Element MSA 22.2.1 Design Process 22.2.2 Simulation and Results 22.2.3 Four Sub-Array 5G MSA 22.2.4 Design Process 22.3 Simulation and Results 22.3.1 Phase Shift 22.3.2 Design Process 22.4 Simulation and Results 22.4.1 Base Station 22.4.1.1 Design Process 22.5 Conclusion References Index
Donate to keep this site alive
1. Disable the AdBlock plugin. Otherwise, you may not get any links.
2. Solve the CAPTCHA.
3. Click download link.
4. Lead to download server to download.