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9781259644696
Antenna Engineering Handbook / Edition 5 available in Hardcover, eBook
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- ISBN-10:
- 1259644693
- ISBN-13:
- 9781259644696
- Pub. Date:
- 12/04/2018
- Publisher:
- McGraw Hill LLC
- ISBN-10:
- 1259644693
- ISBN-13:
- 9781259644696
- Pub. Date:
- 12/04/2018
- Publisher:
- McGraw Hill LLC
![Antenna Engineering Handbook / Edition 5](http://img.images-bn.com/static/redesign/srcs/images/grey-box.png?v11.10.4)
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Overview
Publisher's Note: Products purchased from Third Party sellers are not guaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product.
The gold-standard reference on the design and application of classic and modern antennas—fully updated to reflect the latest advances and technologies
This new edition of the “bible of antenna engineering” has been updated to provide start-to-finish coverage of the latest innovations in antenna design and application. You will find in-depth discussion of antennas used in modern communication systems, mobile and personal wireless technologies, satellites, radar deployments, flexible electronics, and other emerging technologies, including 5G, terahertz, and wearable electronics. Antenna Engineering Handbook, Fifth Edition, is bolstered by real-world examples, hundreds of illustrations, and an emphasis on the practical aspects of antennas.
Featuring 60 chapters and contributions from more than 80 renowned experts, this acclaimed resource is edited by one of the world’s leading antenna authorities. This edition features all of the classic antenna types, plus new and emerging designs, with 13 all-new chapters and important updates to nearly all chapters from past editions.
Antenna Engineering Handbook, Fifth Edition, clearly explains cutting-edge applications in WLANs, automotive systems, PDAs, and handheld devices, making it an indispensable companion for today’s antenna practitioners and developers.
Coverage includes:
• Antenna basics and classic antennas• Design approaches for antennas and arrays• Wideband and multiband antennas• Antennas for mobile devices and PDAs, automotive applications, and aircraft• Base station and smart antennas• Beamforming and 5G antennas• Millimeter-wave and terahertz antennas• Flexible, wearable, thin film, origami, dielectric, and on-chip antennas• MIMO antennas and phased arrays• Direction-finding and GPS antennas• Active antennas• Low-profile wideband antennas• Nanoantennas• Reflectors and other satellite and radio-telescope antennas• Low-frequency, HF, VHF, UHF, ECM, and ESM antennas• Impedance-matching techniques and material characteristics• Metastructured and frequency selective surfaces• Propagation and guided structures• Computational techniques and toolsets• Indoor and outdoor measurements
The gold-standard reference on the design and application of classic and modern antennas—fully updated to reflect the latest advances and technologies
This new edition of the “bible of antenna engineering” has been updated to provide start-to-finish coverage of the latest innovations in antenna design and application. You will find in-depth discussion of antennas used in modern communication systems, mobile and personal wireless technologies, satellites, radar deployments, flexible electronics, and other emerging technologies, including 5G, terahertz, and wearable electronics. Antenna Engineering Handbook, Fifth Edition, is bolstered by real-world examples, hundreds of illustrations, and an emphasis on the practical aspects of antennas.
Featuring 60 chapters and contributions from more than 80 renowned experts, this acclaimed resource is edited by one of the world’s leading antenna authorities. This edition features all of the classic antenna types, plus new and emerging designs, with 13 all-new chapters and important updates to nearly all chapters from past editions.
Antenna Engineering Handbook, Fifth Edition, clearly explains cutting-edge applications in WLANs, automotive systems, PDAs, and handheld devices, making it an indispensable companion for today’s antenna practitioners and developers.
Coverage includes:
• Antenna basics and classic antennas• Design approaches for antennas and arrays• Wideband and multiband antennas• Antennas for mobile devices and PDAs, automotive applications, and aircraft• Base station and smart antennas• Beamforming and 5G antennas• Millimeter-wave and terahertz antennas• Flexible, wearable, thin film, origami, dielectric, and on-chip antennas• MIMO antennas and phased arrays• Direction-finding and GPS antennas• Active antennas• Low-profile wideband antennas• Nanoantennas• Reflectors and other satellite and radio-telescope antennas• Low-frequency, HF, VHF, UHF, ECM, and ESM antennas• Impedance-matching techniques and material characteristics• Metastructured and frequency selective surfaces• Propagation and guided structures• Computational techniques and toolsets• Indoor and outdoor measurements
Product Details
ISBN-13: | 9781259644696 |
---|---|
Publisher: | McGraw Hill LLC |
Publication date: | 12/04/2018 |
Pages: | 1424 |
Sales rank: | 504,292 |
Product dimensions: | 7.50(w) x 9.40(h) x 2.10(d) |
About the Author
John L. Volakis is the Dean of Engineering and Computing and Professor of Electrical & Computer Engineering at Florida International University (FIU) in Miami, FL. A native of Chios, Greece, Prof. Volakis obtained his Ph.D. from The Ohio State University in 1982. Prior to becoming a Dean at FIU, he was a Professor at The University of Michigan (1984-2003) and The Ohio State University (2003-2017). His publications include 8 widely used books, over 400 journal papers and nearly 800 conference papers.
In addition to the 4th Ed. Antenna Engineering Handbook, his other books include Approximate Boundary Conditions in Electromagnetics (IEE Press), Finite Element Method for Electromagnetics (IEEE Press-Wiley), and Frequency Domain Hybrid Finite Element Methods in Electromagnetics (Morgan & Claypool), Computational Methods for High Frequency Electromagnetic Interference (Verlag, 2009), Small Antennas:Miniaturization Techniques (McGraw Hill, 2010), Polymer-Ceramic Composites for Comformal Multilayer Antenna/RF Systems (LAP Lambert, 2010), Integral Equation Methods for Electromagnetics (Scitech Publishing, 2012).
Dr. Volakis is a Fellow of IEEE, and a former President of the IEEE Antennas and Propagation Society, and Chair of the USNC National Radio Science Union. He graduated/mentored nearly 90 Ph.D. students/post-docs, and was listed by ISI in 2004 among the top 250 most referenced authors in Engineering/Computer Science. Among his awards, he is the recipient of The Univ. of Michigan College of Engineering Research Excellence award (1993), The Ohio State Univ. Distinguished Scholar Award (2016) and the IEEE APS Distinguished Achievement award (2015).
In addition to the 4th Ed. Antenna Engineering Handbook, his other books include Approximate Boundary Conditions in Electromagnetics (IEE Press), Finite Element Method for Electromagnetics (IEEE Press-Wiley), and Frequency Domain Hybrid Finite Element Methods in Electromagnetics (Morgan & Claypool), Computational Methods for High Frequency Electromagnetic Interference (Verlag, 2009), Small Antennas:Miniaturization Techniques (McGraw Hill, 2010), Polymer-Ceramic Composites for Comformal Multilayer Antenna/RF Systems (LAP Lambert, 2010), Integral Equation Methods for Electromagnetics (Scitech Publishing, 2012).
Dr. Volakis is a Fellow of IEEE, and a former President of the IEEE Antennas and Propagation Society, and Chair of the USNC National Radio Science Union. He graduated/mentored nearly 90 Ph.D. students/post-docs, and was listed by ISI in 2004 among the top 250 most referenced authors in Engineering/Computer Science. Among his awards, he is the recipient of The Univ. of Michigan College of Engineering Research Excellence award (1993), The Ohio State Univ. Distinguished Scholar Award (2016) and the IEEE APS Distinguished Achievement award (2015).
Table of Contents
Part 1 Introduction and FundamentalsChapter 1. Fundamentals of Antennas, Arrays, and Mobile Communications1.1 Introduction1.2 Huygens’ and Equivalence Principles1.3 Hertzian and Fitzgerald Radiators1.4 Far-Field Antenna Properties, Power Transfer, and Reciprocity1.5 Antennas as Electromagnetic Circuits1.6 Polarization1.7 Directivity Patterns from Continuous Line Sources1.8 Directivity Patterns from Area Source Distributions1.9 Fundamentals of Antenna Arrays1.10 Basic Concepts in Mobile Communications1.11 ReferencesChapter 2. Frequency Bands for Military and Commercial Applications2.1 Introduction to Frequency Bands2.2 Commercial Frequency Bands2.3 Military and Satellite Frequency Bands2.4 Trends and Expected Future Paths2.5 ReferencesChapter 3. Arrays of Discrete Elements3.1 Introduction3.2 Antenna Array Factor and Antenna Indices3.3 Linear Arrays3.4 Planar Arrays3.5 3D and Conformal Arrays3.6 Array Synthesis Techniques3.7 Smart Antennas3.8 Element Pattern and Mutual Coupling3.9 ReferencesPart 2 Types and Design MethodsChapter 4. Classic Antennas: Dipole, Monopole, Loop, and Slot Antennas4.1 Introduction4.2 Dipole Antennas4.3 Loop Antennas4.4 Slot Antennas4.5 ReferencesChapter 5. Helical Antennas5.1 Introduction5.2 Axial-Mode Helical Antennas5.3 Normal-Mode Helical Antennas5.4 Array of Helical Antennas5.5 Fractional-Turn Resonant Quadrifilar5.6 Short Axial-Mode Helical Antennas5.7 Backfire Axial-Mode Helical Antennas5.8 Recent Trends Employing Helical Antennas5.9 ReferencesChapter 6. Small Antennas6.1 The Definition of Electrically Small6.2 The General Electrically Small Antenna6.3 Electrically Small Dipole and Loop Antennas6.4 Power Factor, Quality Factor, and Bandwidth6.5 The Effective Volume6.6 Fundamental Limits on Small Antenna Q6.7 ReferencesChapter 7. Microstrip Antennas7.1 Introduction7.2 Basic Principles of Operation7.3 CAD Model for the Input Impedance7.4 Radiation Patterns7.5 CAD Formulas for Rectangular Patch7.6 Results for Rectangular Patch7.7 CAD Formulas for Circular Patch7.8 Circular Polarization7.9 Microstrip Antennas with Improved Performance7.10 Acknowledgment7.11 ReferencesChapter 8. Multiband Planar Antennas for Wireless Communications8.1 Multiband Planar Antenna Arrays8.2 Multiband Antennas in the Smartphone8.3 ReferencesChapter 9. Wideband Microstrip Antennas9.1 Introduction9.2 Substrate Effect on Bandwidth9.3 Effect of Patch Shape on Bandwidth9.4 Proximity Coupled Microstrip Antennas9.5 Aperture Coupled Microstrip Antennas9.6 Stacked Microstrip Patch Antennas9.7 High-Gain Stacked Patch Antennas9.8 Slotted Wideband Patch Antennas9.9 Microstrip Patch Antennas with EBG9.10 Effects of Size Reduction on Wideband Antennas9.11 ReferencesChapter 10. Small Antennas and Miniaturization Techniques10.1 Introduction10.2 Antenna Miniaturization with Metamaterial Loadings10.3 Low-Profile Antennas Using EBG Structures10.4 Antenna Miniaturization Using Magnetodielectric Materials10.5 Volumetric Antennas10.6 Additive Manufacturing of Antennas10.7 Concluding Remarks10.8 ReferencesChapter 11. Flexible, Thin Film, and Wearable Antennas11.1 Introduction11.2 Flexible Antenna Designs and Operation Frequencies11.3 Thin Film (Non-Fabric) Antennas11.4 Fabric-Based Antennas11.5 Flexible Antenna Applications11.6 Future Directions11.7 ReferencesChapter 12. Origami Antennas12.1 Origami Monofilar Helical Antenna12.2 Morphing Origami Conical Spiral Antenna12.3 ReferencesChapter 13. On-Chip Antennas13.1 Introduction13.2 Radiation-Efficiency-Improved Millimeter-Wave On-Chip Antennas13.3 Miniaturized On-Chip Antenna for Biomedical Applications13.4 ReferencesChapter 14. Active Antennas14.1 Introduction and Basic Terms14.2 Frequency-Agile Active Antennas14.3 Oscillator Antennas and Arrays14.4 Amplifier Antennas and Arrays14.5 Frequency-Conversion Antennas14.6 Rectennas14.7 Other Active Antennas14.8 ReferencesChapter 15. Surface-Wave and Leaky-Wave Antennas15.1 Introduction15.2 Surface-Wave Antennas15.3 Leaky-Wave Antennas15.4 Acknowledgment15.5 ReferencesChapter 16. Waveguide Slot Antenna Arrays16.1 Introduction16.2 Waveguide Slot Radiators16.3 Slotted Waveguide Array Designs16.4 Slot Admittance or Impedance16.5 Design Parameters16.6 Power-Handling Capabilities16.7 Tolerance and Fabrication Techniques16.8 ReferencesChapter 17. MIMO Antenna Systems17.1 Introduction17.2 Performance Metrics of MIMO Antenna Systems17.3 MIMO Antennas for USB Dongles17.4 MIMO Antennas for Mobile Phones17.5 MIMO Antennas for Wireless Access Points17.6 Reconfigurable MIMO Antennas for Cognitive Radios17.7 MIMO Antennas for 5G Systems17.8 Conclusion17.9 ReferencesChapter 18. Frequency-Independent Antennas18.1 Spiral Antennas18.2 Log-Periodic Antennas18.3 Dual-Polarized Frequency-Independent Antennas18.4 Summary18.5 ReferencesChapter 19. Horn Antennas19.1 Introduction19.2 Basic Horn Types19.3 Other Classes of Horns19.4 Recent Developments in Horn Design and Technology19.5 Conclusion19.6 ReferencesChapter 20. Reflector Antennas20.1 Introduction20.2 Diffraction Analysis Techniques for Reflector Antennas20.3 Conventional Reflector Antennas20.4 Reflectors Other Than Parabolic20.5 Large-Aperture Reflector Antennas20.6 Diffraction Shaping20.7 Emerging Applications of Mesh Reflector Antennas20.8 ReferencesChapter 21. Dielectric Resonator Antennas21.1 Introduction21.2 Possible Methods of Analysis21.3 Progress in DRA Research21.4 DRA Arrays21.5 ReferencesChapter 22. Ultra-Wide Bandwidth Antenna Design22.1 Introduction22.2 Fundamentals of UWB Antenna Design22.3 Type-I UWB Antenna Design22.4 Type-II UWB Antenna Design22.5 Type-III UWB Antenna Design22.6 The Dual-Polarization UWB Dielectric Rod Probe Antenna22.7 The Dual-Polarization UWB Dielectric Horn Antenna Design22.8 ReferencesChapter 23. Phased Arrays23.1 Introduction23.2 Theory of Phased Arrays23.3 Pattern Control23.4 Radiating Element Design23.5 Phased Array Antenna Architectures23.6 Applications23.7 ReferencesChapter 24. Array Phase Shifters: Theory and Technology24.1 Introduction24.2 Semiconductor24.3 Thin Film Ferroelectric24.4 Micro-Electromechanical Systems24.5 Slow-Wave24.6 Ferrite24.7 Effect of Phase Shifter Behavior on Phased Array Bit Error Rate24.8 Trends24.9 Summary24.10 ReferencesChapter 25. Conformal and Low-Profile Arrays25.1 Introduction25.2 Fundamental Principles25.3 Antennas and Arrays on Cylinders25.4 Pattern Synthesis for Conformal Arrays25.5 ReferencesChapter 26. Millimeter-Wave Antennas26.1 Millimeter-Wave Applications26.2 Types of Millimeter-Wave Antennas26.3 ReferencesChapter 27. Terahertz Antennas and Arrays27.1 Terahertz Applications27.2 Quasi-Optical Coupling of Terahertz Radiation27.3 Terahertz Antennas27.4 THz Antenna Arrays27.5 ReferencesChapter 28. Nanoantennas28.1 Nanocircuits and Nanoantennas28.2 Metamaterial-Inspired Nanoantennas28.3 Optical Magnetism in Nanoantennas28.4 Nanoantenna Directivity28.5 Active Nanoantennas28.6 Nonlinear Nanoantennas28.7 Enhanced Emission and Quantum Responses with Nanoantennas28.8 Conclusions28.9 Acknowledgments28.10 ReferencesChapter 29. Ultra-Wideband Dipole, Monopole, and Loop Arrays29.1 Resistively Loaded Dipole and Monopole Arrays for Ground Penetrating Radar29.2 Cylindrical Dipole Arrays for Airborne Systems29.3 Vector Sensor Array Antennas29.4 ReferencesChapter 30. Ultra-Wideband Phased Arrays30.1 Applications of Ultra-Wideband Phased Arrays30.2 Tapered Slot Antenna30.3 Connected and Tightly Coupled Arrays30.4 ReferencesChapter 31. Smart Antennas31.1 Introduction31.2 Adaptive Beamforming31.3 ReferencesPart 3 ApplicationsChapter 32. Metamaterial Electronically Scanning Array32.1 Background32.2 Theory of MESA Antennas32.3 Realized K-Band MESA: Modeling and Measurements32.4 ReferencesChapter 33. Low- and Medium-Frequency Antennas33.1 Introduction33.2 Fundamentals of Vertical Monopole Antenna Radiation Properties33.3 Practical Low and Medium Antenna Structures: Design and Construction Basics33.4 Environmental Considerations33.5 ReferencesChapter 34. HF Antennas34.1 Introduction34.2 Specifying the Right Antenna for the Job34.3 Antennas Mounted Above Ground34.4 Major Forms of HF Communications Antennas34.5 Other Types of HF Communications Antennas34.6 Broadband Dipole Curtain Arrays34.7 References34.8 BibliographyChapter 35. VHF/UHF Antennas35.1 Introduction35.2 Antennas for the ISM Bands (Typically 433 MHz, 868/915 MHz, and 2.4/5 GHz)35.3 Antennas for Global Navigation Satellite Systems35.4 Antennas on Printed Circuit Laminates35.5 Antennas for Point-to-Point and Point-to-Multipoint Services35.6 Baluns35.7 Exposure to Electromagnetic Fields35.8 ReferencesChapter 36. Reconfigurable Antennas36.1 Introduction36.2 Reconfigurable Apertures36.3 Reconfigurable Traveling Wave Antennas36.4 Reconfigurable Arrays36.5 Reconfigurable Microstrip Antennas36.6 Reconfigurable Slot Antennas36.7 Reconfigurable Monopole/Dipole Antennas36.8 Concluding Remarks36.9 ReferencesChapter 37. Low-Profile Antennas on Engineered Electromagnetic Surfaces37.1 Introduction37.2 Characterizations and Designs of Electromagnetic Band-Gap Structures37.3 Low-Profile Wire Antennas on EBG Ground Plane37.4 Patch Antennas with Enhanced Performance Using EBG Structures37.5 Impedance and Magneto-Dielectric Substrates for Small Antenna Designs37.6 ReferencesChapter 38. Reflectarray Antennas38.1 Introduction38.2 Analysis and Design Techniques38.3 Techniques for Bandwidth Improvement38.4 Multifrequency Reflectarrays38.5 Contoured Beam Reflectarrays38.6 Beam Scanning Reflectarrays38.7 Recent Developments and Technological Challenges38.8 Summary38.9 Acknowledgments38.10 ReferencesChapter 39. Mobile Handset Antennas39.1 Introduction39.2 Handset Antenna Types39.3 Design Aspects of Handset Antennas39.4 Fabrication Technologies for Handset Antennas39.5 Active Handset Antennas39.6 Applications39.7 Conclusion and Remarks39.8 ReferencesChapter 40. Base Station Antennas40.1 Introduction40.2 Base Station Antenna Requirements40.3 Base Station Antenna Radiating Elements40.4 Multibeam Antennas40.5 ReferencesChapter 41. Antennas for CubeSats41.1 Traditional CubeSat Antennas41.2 Conformal Integrated Solar Panel Antennas41.3 High-Gain Antennas41.4 Acknowledgment41.5 ReferencesChapter 42. 3D Additive Manufacturing of Antennas42.1 Introduction42.2 Additive Manufacturing Techniques for Antenna Applications42.3 Additive Manufacturing–Enabled Antennas42.4 Additive Manufacturing of Antenna Arrays and Systems42.5 ReferencesChapter 43. Antennas for Medical Applications43.1 Overview43.2 The Environment43.3 Antennas for Medical Imaging43.4 Heating43.5 Biotelemetry43.6 Pulsed Electromagnetic Fields43.7 Sensing43.8 Future Directions43.9 Acknowledgments43.10 ReferencesChapter 44. Automobile Antennas44.1 Introduction44.2 AM/FM Antennas44.3 FM Diversity Antennas44.4 RKE and TPMS Antennas44.5 Mobile Telephone Antennas44.6 GNSS Antennas44.7 SDARS Antennas44.8 DSRC Antennas44.9 Emerging Technologies (Observed)44.10 Emerging Technologies (Predicted)44.11 Antenna Measurements44.12 ReferencesChapter 45. Aircraft Antennas45.1 Introduction45.2 Low-Frequency and High-Frequency Antennas45.3 Unidirectional Very-High-Frequency Antennas45.4 Omnidirectional VHF and UHF Antennas45.5 Omnidirectional L-Band Antennas45.6 GPS Antennas45.7 Traffic Collision Avoidance System Antennas45.8 Satellite Communication (SATCOM) Antennas45.9 Low Observable Antennas45.10 Nonmetallic Aircraft Antennas45.11 Small Aircraft Antennas45.12 Radar Antennas45.13 Electronic Warfare45.14 Antenna Performance and Aircraft Interaction45.15 Acknowledgments45.16 ReferencesChapter 46. Radiometer Antennas46.1 Introduction46.2 Basic Principles46.3 System Principles46.4 Radiometer Antenna Types46.5 Recent Developments and Trends in Radiometry46.6 ReferencesChapter 47. Antenna Tracking47.1 Introduction47.2 Tracking Requirements47.3 Open Loop Antenna Tracking47.4 Closed Loop Antenna Tracking47.5 Acquisition Issues47.6 Interferometric Systems47.7 Antenna Tracking Evaluation47.8 ReferencesChapter 48. Satellite Antennas48.1 Introduction48.2 Space Segment Antennas48.3 Ground Segment Antennas48.4 Interference Protection48.5 Satellite Antenna Testing48.6 ReferencesChapter 49. Earth Station Antennas49.1 Introduction49.2 Single-Beam Earth Station Antennas49.3 Multiple-Beam Earth Station Antennas49.4 Measurement Techniques49.6 Acknowledgment49.7 ReferencesChapter 50. Direction Finding Antennas and Systems50.1 Introduction50.2 Direction Finding Systems50.3 Direction Finding Algorithms50.4 DF Algorithm Performance50.5 Geolocation Algorithms50.6 ReferencesChapter 51. ESM and ECM Antennas51.1 Introduction51.2 Communication ESM and ECM System Antennas51.3 Radar ESM and ECM System Antennas51.4 ReferencesChapter 52. Radio-Telescope Antennas52.1 Introduction52.2 Single-Aperture Radio Telescopes52.3 The Two-Element Interferometer52.4 Aperture Synthesis52.5 Major Radio Telescopes52.6 Conclusion52.7 Acknowledgment52.8 References52.9 BibliographyChapter 53. Indoor Antenna Measurements53.1 Facilities53.2 Test Setup and Calibration53.3 Typical Antenna Measurement Properties53.4 Data Analysis Tools53.5 Conclusion53.6 ReferencesPart 4 Topics Associated with AntennasChapter 54. Printed Transmission Lines54.1 General54.2 Printed Transmission Lines54.3 List of Symbols54.4 ReferencesChapter 55. Impedance Matching, Broadbanding, and Baluns55.1 General Matching Techniques55.2 Impedance Matching with Lumped Elements55.3 Impedance Matching with Distributed Elements55.4 Combinations of Transformers and Stubs55.5 Tapered Lines55.6 Broadbanding55.7 Baluns55.8 ReferencesChapter 56. Propagation56.1 Introduction and Overview of Propagation Effects56.2 Free-Space Propagation56.3 Atmospheric Refraction56.4 Atmospheric Gas and Rain Attenuation56.5 Empirical Path Loss Models for Line-of-Sight Links56.6 Fading and Multipath56.7 Ionospheric Effects at Microwave Frequencies56.8 Ionosphere and Ground Wave Effects at Frequencies Less Than 50 MHz56.9 ReferencesChapter 57. Materials and Design Data57.1 Properties of Materials57.2 Absorbing Materials57.3 Nonsolid Surfaces57.4 Radio-Frequency Band Designations57.5 Antenna-Pattern Characteristics57.6 Electrically Small Horns57.7 ReferencesChapter 58. Frequency Selective Surfaces58.1 Introduction58.2 Single-Layer Surfaces58.3 Multilayer Surfaces58.4 Three-Dimensional Structures58.5 Active FSSs58.6 Conclusion58.7 ReferencesChapter 59. Advanced Huygens’ Metasurfaces for Beam Manipulation and Antenna Applications59.1 Introduction59.2 Scalar Huygens’ Metasurfaces59.3 Scalar (Omega) Bianisotropic Huygens’ Metasurfaces59.4 Concluding Remarks59.5 ReferencesChapter 60. Computational Electromagnetics for Antennas60.1 Introduction60.2 Electromagnetics for Antenna Engineering60.3 Integral Equation Formulations for Antenna Analysis60.4 MoM and FEM Procedure for Solving Linear Operator Equations60.5 Examples of MoM Discretizations of Integral Equations for Antennas60.6 Finite Element Method in Antenna Analysis and Design60.7 Finite-Difference Time-Domain Method for Antennas60.8 Postprocessing: Evaluation of Antenna Parameters60.9 Parallelization and High-Performance Computing for Antenna Modeling60.10 Commercial Codes for Antenna Analysis and Design60.11 Conclusion60.12 Acknowledgments60.13 ReferencesIndexFrom the B&N Reads Blog
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