Coplanar waveguide circuits, components, and systems /

Coplanar waveguide circuits, components, and systems /

"Up-to-date coverage of the analysis and applications of coplanar waveguides to microwave circuits and antennas. The unique feature of coplanar waveguides, as opposed to more conventional waveguides, is their uniplanar construction, in which all of the conductors are aligned on the same side of...

Πλήρης περιγραφή

Λεπτομέρειες βιβλιογραφικής εγγραφής
Κύριος συγγραφέας: Simons, Rainee, 1949- (Συγγραφέας)
Μορφή: Ηλ. βιβλίο
Γλώσσα:English
Έκδοση: New York : Wiley Interscience, [2001]
Σειρά:Wiley series in microwave and optical engineering.
Θέματα:
Microwave transmission lines.
Wave guides.
Antennas (Electronics)
TECHNOLOGY & ENGINEERING > Microwaves.
Electronic books.
Διαθέσιμο Online:http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=81919
Πίνακας περιεχομένων:
  • 1. Introduction
  • 1.1. Advantages of Coplanar Waveguide Circuits
  • 1.2. Types of Coplanar Waveguides
  • 1.3. Software Tools for Coplanar Waveguide Circuit Simulation
  • 1.4. Typical Applications of Coplanar Waveguides
  • 1.5. Organization of This Book
  • 2. Conventional Coplanar Waveguide
  • 2.1. Introduction
  • 2.2. Conventional Coplanar Waveguide on a Multilayer Dielectric Substrate
  • 2.3. Quasi-static TEM Iterative Techniques to Determine seff and Zb0s
  • 2.4. Frequency-Dependent Techniques for Dispersion and Characteristic Impedance
  • 2.5. Empirical Formula to Determine Dispersion Based on Spectral Domain Results
  • 2.6. Synthesis Formulas to Determine [epsilon]eff and Zb0s Based on Quasi-static Equations
  • 2.7. Coplanar Waveguide with Elevated or Buried Center Strip Conductor
  • 2.8. Coplanar Waveguide with Ground Plane or Center Strip Conductor Underpasses
  • 2.9. Coplanar Waveguide Field Components
  • 2.10. Coplanar Waveguide on a Cylindrical Surface
  • 2.11. Effect of Metalization Thickness on Coplanar Waveguide Characteristics
  • Appendix 2A. Spectral Domain Dyadic Green's Function Components
  • Appendix 2B. Time Average Power Flow in the Three Spatial Regions
  • 3. Conductor-Backed Coplanar Waveguide
  • 3.1. Introduction
  • 3.2. Conductor-Backed Coplanar Waveguide on a Dielectric Substrate of Finite Thickness
  • 3.3. Effect of Conducting Lateral Walls on the Dominant Mode Propagation Characteristics of CBCPW and Closed Form Equations for Zb0s
  • 3.4. Effect of Lateral Walls on the Higher-Order Mode Propagation on CBCPW
  • 3.5. Channelized Coplanar Waveguide
  • 3.6. Realization of Lateral Walls in Practical Circuits
  • 4. Coplanar Waveguide with Finite-Width Ground Planes
  • 4.1. Introduction
  • 4.2. Conventional Coplanar Waveguide with Finite- Width Ground Planes on a Dielectric Substrate of Finite Thickness
  • 4.3. Conductor-Backed Coplanar Waveguide with Finite- Width Ground Planes on a Dielectric Substrate of Finite Thickness and Finite Width
  • 4.4. Simple Models to Estimate Finite Ground Plane Resonance in Conductor-Backed Coplanar Waveguide
  • 5. Coplanar Waveguide Suspended inside a Conducting Enclosure
  • 5.1. Introduction
  • 5.2. Quasi-static TEM Iterative Technique to Determine seff and Zb0s of Suspended CPW
  • 5.3. Frequency-Dependent Numerical Techniques for Dispersion and Characteristic Impedance of Suspended CPW
  • 5.4. Dispersion and Higher-Order Modes of a Shielded Grounded CPW
  • 5.5. Dispersion, Characteristic Impedance, and Higher-Order
  • 5.6. Dispersion and Characteristic Impedance of Suspended CPW on Multilayer Dielectric Substrate
  • 6. Coplanar Striplines
  • 6.1. Introduction
  • 6.2. Analytical Expressions Based on Quasi-Static TEM Conformal Mapping Techniques to Determine Effective Dielectric Constant and Characteristic Impedance
  • 6.3. Coplanar Stripline Synthesis Formulas to Determine the Slot Width and the Strip Conductor Width
  • 6.4. Novel Variants of the Coplanar Stripline.
  • 7. Microshield Lines and Coupled Coplanar Waveguide
  • 7.1. Introduction
  • 7.2. Microshield Lines
  • 7.3. Edge Coupled Coplanar Waveguide without a Lower Ground Plane
  • 7.4. Conductor-Backed Edge Coupled Coplanar Waveguide
  • 7.5. Broadside Coupled Coplanar Waveguide
  • 8. Attenuation Characteristics of Conventional, Micromachined, and Superconducting Coplanar Waveguides
  • 8.1. Introduction
  • 8.2. Closed Form Equations for Conventional CPW Attenuation Constant
  • 8.3. Influence of Geometry on Coplanar Waveguide Attenuation
  • 8.4. Attenuation Characteristics of Coplanar Waveguide on Silicon Wafer
  • 8.5. Attenuation Characteristics of Coplanar Waveguide on Micromachined Silicon Wafer
  • 8.6. Attenuation Constant for Superconducting Coplanar Waveguides
  • 9. Coplanar Waveguide Discontinuities and Circuit Elements
  • 9.1. Introduction
  • 9.2. Coplanar Waveguide Open Circuit
  • 9.3. Coplanar Waveguide Short Circuit
  • 9.4. Coplanar Waveguide MIM Short Circuit
  • 9.5. Series Gap in the Center Strip Conductor of a Coplanar Waveguide
  • 9.6. Step Change in the Width of Center Strip Conductor of a Coplanar Waveguide
  • 9.7. Coplanar Waveguide Right Angle Bend
  • 9.8. Air-Bridges in Coplanar Waveguide
  • 9.9. Coplanar Waveguide T-Junction
  • 9.10. Coplanar Waveguide Spiral Inductor
  • 9.11. Coplanar Waveguide Capacitors
  • 9.12. Coplanar Waveguide Stubs
  • 9.13. Coplanar Waveguide Shunt Inductor
  • 10. Coplanar Waveguide Transitions
  • 10.1. Introduction
  • 10.2. Coplanar Waveguide-to-Microstrip Transition
  • 10.3. Transitions for Coplanar Waveguide Wafer probes
  • 10.4. Transitions between Coplanar Waveguides
  • 10.5. Coplanar Waveguide-to-Rectangular Waveguide Transition
  • 10.6. Coplanar Waveguide-to-Slotline Transition
  • 10.7. Coplanar Waveguide-to-Coplanar Stripline Transition
  • 10.8. Coplanar Stripline-to-Microstrip Transition
  • 10.9. Coplanar Stripline-to-Slotline Transition
  • 10.10. Coplanar Waveguide-to-Balanced Stripline Transition
  • 11. Directional Couplers, Hybrids, and Magic-Ts
  • 11.1. Introduction
  • 11.2. Coupled-Line Directional Couplers
  • 11.3. Quadrature (90�) Hybrid
  • 11.4. 180� Hybrid
  • 11.5. Standard 3-dB Magic-T
  • 11.6. Active Magic-T
  • 12. Coplanar Waveguide Applications
  • 12.1. Introduction
  • 12.2. MEMS Coplanar Waveguide Capacitive Metal Membrane Shunt Switch
  • 12.3. MEMS Coplanar Waveguide Distributed Phase Shifter
  • 12.4. High-Temperature Superconducting Coplanar Waveguide Circuits
  • 12.5. Ferroelectric Coplanar Waveguide Circuits
  • 12.6. Coplanar Photonic-Bandgap Structure
  • 12.7. Coplanar Waveguide Patch Antennas.

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