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7. 4/20/20107R. Munden - Fairfield University The width, a, needs to be λ/2, while b is about half that. This is why waveguide is only used for high frequencies, otherwise the size would be far too large.

8. 4/20/20108R. Munden - Fairfield University Multiple modes may travel down a waveguide simultaneously

9. 4/20/2010R. Munden - Fairfield University9 http://www.falstad.com/embox/guide.html

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11. 4/20/2010R. Munden - Fairfield University11 RangeInternal GHz(inches)(mm. approx) U.S. (EIA)Narda 1.12 - 1.76.5 x 3.25165.0 x 83.0 WR650L 1.45 - 2.25.1 x 2.55131.0 x 65.0 WR510 1.7 - 2.64.3 x 2.15109.0 x 55.0 WR430LS 2.2 - 3.33.4 x 1.786.0 x 43.0 WR340 2.6 - 3.952.84 x 1.3472.0 x 34.0 WR284S 3.3 - 4.92.29 x 1.14559.0 x 29.0 WR229A(7.5cm) 3.95 - 5.851.872 x 0.87248.0 x 22.0 WR187C 4.9 - 7.051.59 x 0.79540.0 x 20.0 WR159 5.85 - 8.21.372 x 0.62235.0 x 16.0 WR137XN 7.05 - 10.01.122 x 0.49729.0 x 13.0 WR112XB 8.2 - 12.40.9 x 0.423.0 x 10.0 WR90X 10.0 - 15.00.75 x 0.37519.0 x 9.5 WR75 12.4 - 18.00.622 x 0.31116.0 x 7.9 WR62KU 15.0 - 22.00.510 x 0.25513.0 x 5.8 WR51 18.0 - 26.50.420 x 0.17011.0 x 4.3 WR42K 22.0 - 33.00.340 x 0.1708.6 x 4.3 WR34 26.5 - 40.00.280 x 0.1407.1 x 3.6 WR28V 33.0 - 50.00.224 x 0.1125.7 x 2.9 WR22Q 40.0 - 60.00.188 x 0.0944.8 x 2.4 WR19 50.0 - 75.00.148 x 0.0743.8 x 1.9 WR15M 60.0 - 90.00.122 x 0.0613.1 x 1.6 WR12E 75.0 - 110.00.100 x 0.0502.4 x 1.3 WR10 90.0 - 140.00.080 x 0.0402.0 x 1.0 WR8N 110.0 - 170.00.065 x 0.03251.7 x 0.82 WR7 140.0 - 220.00.051 x 0.02551.3 x 0.65 WR5A(7.5cm) 170.0 - 260.00.043 x 0.02151.1 x 0.55 WR4 220.0 - 325.00.034 x 0.0170.87 x 0.44 WR3R

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14. 4/20/2010R. Munden - Fairfield University14 As frequency goes down, wavelength goes up. As this approaches the cutoff wavelength, the wave must be travelling more perpendicular (theta near zero), which lowers the group velocity, eventually stopping propagation of energy when theta = 0 and Vg =0. At this condition in TE10 mode you have one half wavelength of E field across the a direction of the guide.

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17. 4/20/201017R. Munden - Fairfield University Circular waveguide Advantages: Simple to manufacture Rotationally symmetric – ideal for rotating radar installations Disadvantages: Twice the cross-section necessary Expensive Only 15% bandwidth as opposed to 50% BW for dominant mode

18. 4/20/201018R. Munden - Fairfield University Allow longer wavelengths (lower frequencies) with smaller outside dimensions. Allow larger bandwidth. More expensive to manufacture, so only used when space is a premium (i.e. satellites).

19. 4/20/201019R. Munden - Fairfield University Spiral wound ribbons of metal allow continuous flexing for special applications. Usually coated with rubber to maintain seal, and are often pressurized to prevent water or dust buildup or are coated with silver or gold to prevent corrosion

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21. 4/20/201021R. Munden - Fairfield University H lines are bentE lines are bentE lines polarization plane is changed These are used to mechanically move the wave around corners, or to change its polarization. Often governed by “plumbing” considerations.

22. 4/20/201022R. Munden - Fairfield University Shunt – A+B add in phase to C, or C splits equally into A & B Series – D splits equally, but opposite phase, into A and B. D can be used with a piston for a short circuit stub. Hybrid or Magic Tee – combines the two previous forms, many interesting applications

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24. 4/20/201024R. Munden - Fairfield University Similar to shorted stub in a transmission line. If less than ¼ wave it looks capacitive, if longer it looks inductive. Can be used to match loads. a)Is like a single-stub tuner b)Is like a double-stub tuner

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26. 4/20/201026R. Munden - Fairfield University Graphite Sand or a high resistance rod or wedge at the end will serve to dissipate the energy as heat, preventing reflections back up the waveguide

27. 4/20/201027R. Munden - Fairfield University a)Flap attenuator, insertion of a resistive card causes attenuation, this is varied by how much the card is inserted. b)Vane attenuator positions the vanes near the edges for low attenuation or the center for high attenuation

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30. 4/20/201030R. Munden - Fairfield University The coax probe should be at the center of a and a ¼ wavelength from the end of the guide for maximum coupling

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32. 4/20/201032R. Munden - Fairfield University Provide electric, magnetic, or EM field coupling

33. 4/20/201033R. Munden - Fairfield University Cavity Resonators are used at microwave frequencies in place of standard LC resonant circuits, just like transmission lines can be used in place of LC resonators in RF applications.

34. 4/20/201034R. Munden - Fairfield University Cavity volume can be tuned. Decreasing d increases f, and increasing d decreases f Tuning can also be accomplished by inserting a non-ferrous screw or paddle near maximum H to increase or decrease the inductance inversely decreasing or increasing f.

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36. 4/20/201036R. Munden - Fairfield University Speed of light, c = 186000 mi/s or 162000 nautical mi/s (6076 ft/s) Radar mile is 2000 yards (6000 ft). Range found from time, 6.18us to travel 1 radar mile. Range = t/12.36 Can be calculated from speed of light

37. 4/20/201037R. Munden - Fairfield University Max unambiguous range = PRT/12.2 Minimum Range = 150 PW Duty cycle = PW / PRT

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