If the instantaneous RF potentials on the two sides of a magnetron cavity are of opposite polarity, the operation is in the
A. $$\pi $$ mode
B. $$\frac{\pi }{2}$$ mode
C. $$2\pi $$ mode
D. $$\frac{\pi }{4}$$ mode
Answer: Option A
A. $$\pi $$ mode
B. $$\frac{\pi }{2}$$ mode
C. $$2\pi $$ mode
D. $$\frac{\pi }{4}$$ mode
Answer: Option A
Coupling into and out of a traveling-wave tube can be accompanied by a
A. Waveguide match
B. Cavity match
C. Direct coax-helix match
D. All of the above
A. A long time constant
B. Low-pass filters
C. The shortest possible time
D. The restricted high-frequency response
A. $${\text{S}} = \frac{{2\lambda {\text{R}}}}{{\text{L}}}$$
B. $${\text{S}} = \frac{{3\lambda {\text{R}}}}{{\text{L}}}$$
C. $${\text{S}} = \frac{{\lambda {\text{R}}}}{{\text{L}}}$$
D. $${\text{S}} = \frac{{\text{L}}}{{\lambda {\text{R}}}}$$
The aquadag coating on the inside of PPI tube is used
A. To focus the beam of primary electrons
B. To shield the electron beam from unidirectional magnetic
C. As a second anode and to prevent the build-up of secondary field
D. All of these
Join The Discussion