Introduction To Modern Planar Transmission Lines. Anand K. Verma
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2 Chapter 3Figure 3.1 Two‐port network to determine [Z] and [Y] parameters.Figure 3.2 Lumped T‐network.Figure 3.3 A transmission line section.Figure 3.4 Two‐port network for transmission parameter.Figure 3.5 Cascading of two networks to get one equivalent network.Figure 3.6 Series impedance.Figure 3.7 Shunt admittance.Figure 3.8 Basic networks.Figure 3.9 Two‐port network for evaluation of S‐parameter.Figure 3.10 A section of the multiport network. Port is shown extended with ...Figure 3.11 N‐port network showing power variables (ai, bi) in terms of volt...Figure 3.12 At the ith port, the load is terminated in port characteristic i...Figure 3.13 N‐port network showing phase‐shifting property.Figure 3.14 A two‐port network with arbitrary termination.Figure 3.15 Network of series impedance.Figure 3.16 Network of shunt admittance.Figure 3.17 A transmission line circuit with an arbitrary characteristic imp...Figure 3.18 Network for Z‐parameter.Figure 3.19 Network for [ABCD] parameter.Figure 3.20 Calibration process in the measurement of S‐parameters of a devi...Figure 3.21 Nature of normal (positive) dispersion.Figure 3.22 Nature of anomalous (negative) dispersion.Figure 3.23 Description of phase and group velocities of a forward‐moving mo...Figure 3.24 Formation of a wave‐packet.Figure 3.25 ω − β diagram to get phase and group velocities.Figure 3.26 Nature of dispersion on (ω − β) the diagram.Figure 3.27 Shunt inductor loaded line and its characteristics.Figure 3.28 Lumped elements models of short transmission line sections and d...Figure 3.29 Inductor loaded CL‐line.Figure 3.30 Series capacitor loaded LC‐line.
3 Chapter 4Figure 4.1 The unit vector is in the direction normal to the surface.Figure 4.2 Response of nonlinear medium showing generation of harmonics.Figure 4.3 Inhomogeneous medium showing a step variation of relative permitt...Figure 4.4 The crystal axes (ξ, η, ς) and the physical axes (x, y, z) of a p...Figure 4.5 Classification of bianisotropic and bi‐isotropic materials.Figure 4.6 Circuit model, parameters of a dielectric medium.Figure 4.7 Circuit model and frequency response of lossy magnetic material....Figure 4.8 Surfaces and volume used in the integral form of Maxwell equation...Figure 4.9 TEM mode wave in an unbounded medium.Figure 4.10 Type of polarizations.Figure 4.11 Polarizing device described by Jones matrix.Figure 4.12 The (y–z) and rotated (e1–e2) Coordinate systems.Figure 4.13 Wave propagation uniaxial media.Figure 4.14 Dispersion diagrams of the wave propagating in the z‐direction i...Figure 4.15 Dispersion diagrams in the uniaxial anisotropic medium.
4 Chapter 5Figure 5.1 Normal incidence of TM‐polarized plane wave at the interface of t...Figure 5.2 Oblique incidence of a plane wave with TE‐polarization at the int...Figure 5.3 Oblique incidence of a plane wave with TM‐polarization at the int...Figure 5.4 Dispersion diagrams of refracted waves.Figure 5.5 Oblique incidence of plane wave at three different angles of inci...Figure 5.6 Plane‐wave incident on a dielectric slab.Figure 5.7 Electrical grouping of the materials media in the (μr, εr)‐plane....Figure 5.8 RH and LH‐coordinate systems for the DPS and DNG media.Figure 5.9 Refraction of the obliquely incident EM‐wave at the interface of ...Figure 5.10 Circuit models of four kinds of the medium on the (μ, ε)‐plane....Figure 5.11 EM‐wave propagation through the DNG and composite DPS‐DNG slabs....Figure 5.12 Creation of image using wave optics.Figure 5.13 Ray diagram of a DNG flat lens.Figure 5.14 Doppler effect in the DPS and DNG media. The source receding the...Figure