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โœฆ   LIBER   โœฆ
๐Ÿ“

Passive and active microwave circuits

โœ Scribed by J. Helszajn.

Publisher
Wiley,
Year
1978
Tongue
English
Leaves
288
Category
Library
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โœฆ Table of Contents

  1. The Scattering Matrix
    1.1 The Scattering Matrix
    1.2 The Scattering Matrix Eigenvalues
    1.3 Eigenvectors
    1.4 Diagonalization of Scattering Matrix
    1.5 Scattering Parameters of 2-port Networks
    1.6 The Unitary Condition
    1.7 The Dissipation Matrix
    1.8 Scattering Transfer Parameters
    1.9 Generalized 2-port Scattering Parameters
    1.10 Experimental Determination of Microwave Networks
    Problems
    References
    Further Reading
    1. Immittance Matrices
      2.1 Impedance Matrix
      2.2 The Admittance Matrix
      2.3 Eigennetworks
      2.4 Eigenvalues of Scattering and Immittance Matrices
      2.5 Relation Between S, Z, and Y Matrices
      2.6 Equivalent Circuit of Uniform Transmission Line
      2.7 Equivalent Circuit of Transmission Cavity Resonator
      Problems
      Further Reading
    2. Directional Couplers
      3.1 Scattering Matrix of Directional Coupler
      3.2 Hybrid Junctions
      3.3 Even and Odd Modes Theory of Directional Couplers
      3.4 Operation of Sidewall and Topwall Hybrids
      3.5 Eigenvalue Theory of Sidewall Waveguide Hybrid
      3.6 the Multibranch Directional Coupler
      Problems
      Further Reading
    3. Impedance and Mode Transducers
      4.1 Quarter-wave Impedance Transformer
      4.2 Stepped-impedance Transformers
      4.3 Matched Terminations
      4.4 Rotary Joint
      4.5 Mode Transducers
      4.6 Variable Shortcircuit
      4.7 Quarter Wave Plate
      Problems
      Further Reading
    4. Two-port Phase and Attenuation Networks
      5.1 Uncalibrated Waveguide Phase-shifters and Attenuators
      5.2 Variable Rotor Attenuator
      5.3 High-power Attenuator
      5.4 Variable Rotor Phase Shifter
      5.5 High-power Variable Phase Shifter
      Problems
    5. Cavity Resonators
      6.1 Unloaded, External, and Loaded Q-factors
      6.2 Resonant Circuit Using Distributed Transmission Lines
      6.3 Boundary Conditions of Rectangular Microwave Cavity Resonators
      6.4 Rectangular Waveguide Cavity Resonator
      6.5 Scattering Matrix of Series Resonator
      6.6 Scattering Matrix of Series Resonator with Damping
      6.7 Microivave Cavity Resonator Using Susceptances Spaced by Section of Line
      6.8 Impedance Matrix of Transformer-coupled Resonator
      Problems
      Further Reading
    6. Microwave Filters
      7.1 The Synthesis Procedure
      7.2 Butterworth Lowpass Filter Approximation
      7.3 Darlington Insertion Loss Filter Synthesis
      7.4 Frequency Transformations
      7.5 Lowpass to Bandpass Transformation
      7.6 Lowpass to Bandstop Transformation
      7.8 Impedance Scaling
      7.9 Immittance Inverters
      7.10 Microwave Bandpass Filter Configuration
      Problems
      References
      Further Reading
    7. Nonreciprocal Ferrite Devices
      8.1 Susceptibility Tensor in Infinite Medium
      8.2 Scalar Susceptibility
      8.3 Tensor Permeability
      8.4 Scalar Permeability
      8.5 Faraday Rotation
      8.6 Faraday Rotation Isolator
      8.7 Four-port Faraday Rotator Circulator
      8.8 Nonreciprocal Faraday Rotation Type Phase Shifter
      8.9 Circular Polarization in Rectangular Waveguide
      8.10 Nonreciprocal Propagation in Rectangular Waveguide
      8.11 Perturbation Theory of Nonreciprocal Rectangular Waveguide Phase Shifter
      8.12 Perturbation Theory of the Rectangular Waveguide Resonance Isolator
      8.13 Differential Phase Shift Circulator
      Problems
      References
      Further Reading
    8. Yig Filters
      9.1 Scattering Matrix of 2-port Gyrator Network
      9.2 Immittance Matrices of Gyrator Network
      9.3 Two-port Gyrator Using Orthogonal Loops Coupled by a Yig Sphere
      9.4 Equivalent Circuit of Coupled Yig Resonator Using Gyrator Network
      9.5 Scattering Matrix of Loop Coupled Yig Filter at Resonance
      9.7 Scattering Matrix of Loop-coupled Yig Filter with Damping
      9.8 Reflection Coefficient of Lossy Gyrator Circuit with One Port Terminated in Variable Shortcircuit
      9.9 Coincidence Limiting in Yig Spheres at Large Signal Power
      Problems
      Further Reading
      References
    9. The Junction Circulator
      10.1 Network Definition of Junction Circulator
      10.2 The Scattering Matrix Eigenvalues
      10.3 Scattering Matrix Eigenvectors
      10.4 Diagonalization of Scattering Matrix
      10.5 Lumped Element Circulator
      Problems
      Further Reading
    10. Variable Capacitance Diode Circuits
      11.1 Semiconductor Diodes
      11.2 Junctioncapa Citance
      11.3 Capacitance, Elastance, and Charge
      11.4 Frequency Multipliers
      11.5 the Parametric Amplifier
      11.6 Varactor Analogue Phase Shifter
      Problems
      Further Reading
    11. Pin Control Devices
      12.1 Basics Witching Circuits
      12.2 Dissipation in Pin Diodes
      12.3 Nonreflective Pin Diode Attenuators
      12.4 Single-pole Double-throw Pin Diode Switchusing Shunt Diodes
      12.5 Basic Construction of Sp3t Switch
      12.6 Pin Control Diode Phase Shifters
      Problems
      Further Reading
    12. Microwave Mixers (G.P. Riblet and G. Lo)
      13.1 Schottky Barrier Diode
      13.2 Resisti Ve Mixing
      13.3 Conversion Loss
      13.4 Image Frequency
      13.5 Balanced Mixer
      13.6 Noise Factor
      Problems
      Further Reading
    13. Transferred-electron Oscillators and Amplifiers
      14.1 Transferred Electron Transit Time Devices
      14.2 Domain Formation and the Gunn Effect
      14.3 Gain of Simple Negative Resistance Amplifier
      14.4 Gain-bandwidth Product of Negative Resistance Amplifier
      14.5 Gain Bandwidth of Wideband Negative Resistance Amplifier
      14.6 Coaxial Gunn Oscillator
      14.7 Waveguide-cavity Gunn-effect Oscillator
      Further Reading
      Problems
    14. Microwave-transistor Amplifier Design (with W.T. Nisbet)
      15.1 Stability of a 2-port Network
      15.2 Unconditional Stability
      15.3 Definition of Transducer Power Gain
      15.4 Complex Conjugate Image Matching
      15.5 Circles of Constant Unilateral Gain
      15.6 Unilateral Figure of Merit
      15.7 Example of Narrow-band Amplifier Design
      15.8 Nonunilateral Design
      15.9 Unilateral Design
      Problems
      Further Reading
      Index

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