The group velocity is obtained separately for both the negative and positive propagation constants:
The phase velocity and group velocity are in opposite directions to each other, i.e. vg > 0, vp < 0 or vg < 0, vp > 0. This kind of wave is called the backward wave. If the power is moving from the source to load in the positive direction, the group velocity is in the positive direction from the source to the load, i.e. from the left side to the right side of Fig (3.28b). The power always flows from the source to load. Therefore, the direction of the power flow decides the direction of the EM‐wave propagation. Normally, the direction of the group velocity is in the direction of the power flow. However, the phase velocity appears to be from load to the source. It means at the end of a CL line section the leading phase shift is obtained. It is unlike the lagging phase shift for an LC line section.
Figure 3.28 Lumped elements models of short transmission line sections and dispersion diagram of CL line.
Figure (3.28c) shows the above results on the (ω − β) diagram. In both the quadrants, the slope ψ at the origin determines the phase velocity, and the local slopes ϕ at the points P and Q determine the group velocities. Both these slopes rapidly increase with an increase in frequency, showing the fast increase in both velocities as given by equations (3.4.17) and (3.4.18). Thus, the lossless CL‐line is a highly dispersive medium. The slope at the origin and the local slope have opposite sense, i.e. one is clockwise and another is anti‐clockwise, showing the antiparallel nature of the phase and group velocities. Such waves are the backward waves. The second quadrant with vg > 0, vp < 0 shows the positive direction of backward wave propagation, while the first quadrant with vg < 0, vp > 0 shows the negative direction of backward wave propagation, i.e. the reflected wave on the CL‐line. The wave in the shaded light‐cone region is fast‐wave, whereas outside the light‐cone it is the slow‐wave.
Equations (3.4.16) and (3.4.17) show that the propagation constant β decreases with an increase in frequency, whereas the phase velocity increases with an increase in frequency. Therefore, the CL‐line has an anomalous dispersion. It is a highly dispersive transmission line. In the case of the material medium, the backward wave with the anomalous dispersion is associated with the strong absorption region. It is discussed in the subsection (6.5.1) of chapter‐6 using the Lorentz model. The standard LPF type transmission line is known as the right hand, i.e. the RH‐transmission line and the HPF type transmission line supporting the backward wave is known as the left hand, i.e. the LH‐transmission line. The RH‐line corresponds to the double‐positive (DPS), i.e. both μ, ε positive medium, whereas the LH‐line corresponds to the double negative (DNG), i.e. both μ, ε negative medium. These media are discussed in section (5.5) of chapter 5. The composite RH‐LH (CRLH)‐transmission line, giving some unique transmission characteristics, models the so‐called metamaterials with negative permittivity and negative permeability [B.19, J.8]. This section considers only one isolated LC unit. The cascading of several such units forms the backward wave supporting LH‐transmission line known as the metalines. It is further discussed in chapter 22.
Figure 3.29 Inductor loaded CL‐line.
Series Connected Parallel Lsh‐C Type Line
The backward wave supporting CL‐line, discussed above, has no cut‐off frequency. Figure (3.29) shows the modified CL‐ line by adding a shunt inductor Lsh, inside the gray box, across the series‐connected capacitor C. It is an HPF type CL‐line that supports the backward wave with a cut‐off frequency. The propagation characteristics of this line are obtained from the series impedance and shunt admittance p.u.l.:
(3.4.19)
The propagation constant of the line is
(3.4.20)
The cut‐off frequency is
(3.4.21)
The inductor loaded CL‐line behaves like a high‐pass filter. The wave propagates for ω > ωc. For the frequency below cut‐off, i.e. for ω < ωc, the wave is in the evanescent mode. The (ω − β) diagram of the inductor loaded CL‐line is similar to the (ω − β) diagram of Fig (3.28c). However, the cut‐off frequency is not shown in Fig (3.28c). A reader can easily add the cut‐off frequency ωc in the dispersion diagram of Fig (3.28c). Unlike the unloaded CL, the present loaded CL line shows the cut‐off frequency behavior. The present HPF type loaded CL line also supports the dispersive backward wave with phase velocity and group velocity opposite to each other. The propagation constant β decreases with frequency, whereas the phase velocity increases with frequency. It shows that the loaded CL‐line has anomalous dispersion. The phase and group velocities of the backward wave are
In summary, the inductor loaded CL‐line shown in Fig (3.29) supports the backward wave. Above the cut‐off frequency, i.e. for ω > ωc, and for the limiting case ω → ∞, equations (3.4.22a) and (3.4.22b) reduce to equations (3.4.17) and (3.4.18),