1. Figure 4.1 (p. 163) Electric and magnetic field lines for an arbitrary two-conductor TEM line.
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2. Figure 4.2 (p. 163) Electric field lines for the TE10 mode of a rectangular waveguide.
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3. Figure 4.3 (p. 167) Geometry of a partially filled waveguide and its transmission line equivalent for Example 4.2.
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4. Figure 4.4 (p. 168) An arbitrary one-port network.
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5. Figure 4.5 (p. 169) An arbitrary N-port microwave network.
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6. Figure 4.6 (p. 173) A two-port T-network.
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7. Figure 4.7 (p. 175) A photograph of the Hewlett-Packard HP8510B Network Analyzer. This test instrument is used to measure the scattering parameters (magnitude and phase) of a one- or two-port microwave network from 0.05 GHz to 26.5 GHz. Built-in microprocessors provide error correction, a high degree of accuracy, and a wide choice of display formats. This analyzer can also perform a fast Fourier transform of the frequency domain data to provide a time domain response of the network under test. Courtesy of Agilent Technologies.
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8. Figure 4.8 (p. 176) A matched 3B attenuator with a 50 Ω Characteristic impedance (Example 4.4).
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9. Figure 4.9 (p. 181) Shifting reference planes for an N-port network.
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10. Figure 4.10 (p. 181) An N-port network with different characteristic impedances.
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11. Figure on page 183
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12. Figure 4.11 (p. 184) (a) A two-port network; (b) a cascade connection of two-port networks.
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13. Figure (p. 188) A coax-to-microstrip transition and equivalent circuit representations. (a) Geometry of the transition. (b) Representation of the transition by a “black box.” (c) A possible equivalent circuit for the transition [6].
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14. Figure (p. 188) Equivalent circuits for a reciprocal two-port network. (a) T equivalent. (b) π equivalent.
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15. Figure (p. 189) The signal flow graph representation of a two-port network. (a) Definition of incident and reflected waves. (b) Signal flow graph.
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16. Figure (p. 190) The signal flow graph representations of a one-port network and a source. (a) A one-port network and its flow graph. (b) A source and its flow graph.
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17. Figure 4. 16 (p. 191) Decomposition rules. (a) Series rule
Figure (p. 191) Decomposition rules. (a) Series rule. (b) Parallel rule. (c) Self-loop rule. (d) Splitting rule.
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18. Figure 4.17 (p. 192) A terminated two-port network.
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19. Figure (p. 192) Signal flow path for the two-port network with general source and load impedances of Figure 4.17.
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20. Figure 4. 19 (p. 192) Decompositions of the flow graph of Figure 4
Figure (p. 192) Decompositions of the flow graph of Figure 4.18 to find Γin = b1/a1 and Γout = b2/a2. (a) Using Rule 4 on node a2. (b) Using Rule 3 for the self-loop at node b2. (c) Using Rule 4 on node b1. (d) Using Rule 3 for the self-loop at node a1.
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21. Figure 4.20 (p. 193) Block diagram of a network analyzer measurement of a two-port device.
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22. Figure 4.21a (p. 194) Block diagram and signal flow graph for the Thru connection.
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23. Figure 4.21b (p. 194) Block diagram and signal flow graph for the Reflect connection.
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24. Figure 4.21c (p. 194) Block diagram and signal flow graph for the Line connection.
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25. Figure 4.22 (p. 198) Rectangular waveguide discontinuities.
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26. Figure 4. 23 (p. 199) Some common microstrip discontinuities
Figure (p. 199) Some common microstrip discontinuities. (a) Open-ended microstrip. (b) Gap in microstrip. (c) Change in width. (d) T-junction. (e) Coax-to-microstrip junction.
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27. Figure 4.24 (p. 200) Geometry of an H-plane step (change in width) in rectangular waveguide.
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28. Figure 4.25 (p. 203) Equivalent inductance of an H-plane asymmetric step.
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29. Figure on page 204 Reference: T. C
Figure on page 204 Reference: T.C. Edwards, Foundations for Microwave Circuit Design, Wiley, 1981.
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30. Figure (p. 205) An infinitely long rectangular waveguide with surface current densities at z = 0.
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31. Figure (p. 206) An arbitrary electric or magnetic current source in an infinitely long waveguide.
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32. Figure 4.28 (p. 208) A uniform current probe in a rectangular waveguide.
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33. Figure (p. 210) Various waveguide and other transmission line configurations using aperture coupling. (a) Coupling between two waveguides wit an aperture in the common broad wall. (b) Coupling to a waveguide cavity via an aperture in a transverse wall. (c) Coupling between two microstrip lines via an aperture in the common ground plane. (d) Coupling from a waveguide to a stripline via an aperture.
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34. Figure (p. 210) Illustrating the development of equivalent electric and magnetic polarization currents at an aperture in a conducting wall (a) Normal electric field at a conducting wall. (b) Electric field lines around an aperture in a conducting wall. (c) Electric field lines around electric polarization currents normal to a conducting wall. (d) Magnetic field lines near a conducting wall. (e) Magnetic field lines near an aperture in a conducting wall. (f) Magnetic field lines near magnetic polarization currents parallel to a conducting wall.
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35. Figure (p. 213) Applying small-hole coupling theory and image theory to the problem of an aperture in the transverse wall of a waveguide. (a) Geometry of a circular aperture in the transverse wall of a waveguide. (b) Fields with aperture closed. (c) Fields with aperture open. (d) Fields with aperture closed and replaced with equivalent dipoles. (e) Fields radiated by equivalent dipoles for x < 0; wall removed by image theory. (f) Fields radiated by equivalent dipoles for z > 0; all removed by image theory.
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36. Figure 4.32 (p. 214) Equivalent circuit of the aperture in a transverse waveguide wall.
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37. Figure 4.33 (p. 214) Two parallel waveguides coupled through an aperture in a common broad wall.
Microwave Engineering, 3rd Edition by David M. Pozar
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