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... generation and transmission, the electric power available is usually an a.c. supply. The supply voltage varies sinusoidally and has a frequency of 50 Hz. It is used for lighting, heating and electric motors. But there are many applications where d.c. supply is needed. When such a d.c. supply is requ ...
... generation and transmission, the electric power available is usually an a.c. supply. The supply voltage varies sinusoidally and has a frequency of 50 Hz. It is used for lighting, heating and electric motors. But there are many applications where d.c. supply is needed. When such a d.c. supply is requ ...
08 2018 Electrons - Go With the Flow!.
... Glass is a good electrical insulator. Copper is a good electrical conductor. Alternating current is the name for a current that reverses direction on a regular basis. Frequency is the term describing the number of times per second that an alternating current reverses direction. Rectifier d ...
... Glass is a good electrical insulator. Copper is a good electrical conductor. Alternating current is the name for a current that reverses direction on a regular basis. Frequency is the term describing the number of times per second that an alternating current reverses direction. Rectifier d ...
Lecture Notes (6 and 7
... decreased. Consequently, tuning arrangements for the shorter drift angles will have more cavities tuned above band center to counteract the effect of the zeros. The klystron frequency response will generally fall off more sharply at the high end of the band, due to the presence of zeroes there. The ...
... decreased. Consequently, tuning arrangements for the shorter drift angles will have more cavities tuned above band center to counteract the effect of the zeros. The klystron frequency response will generally fall off more sharply at the high end of the band, due to the presence of zeroes there. The ...
Ph12-Lab5F
... the current polarity reverses: (1 mark) electron flow: ___flows back and forth_________________ magnetic field: ___reverses each time the polarity reverses_ In your home, the current completes a complete cycle (from forward -> to reverse -> back to ...
... the current polarity reverses: (1 mark) electron flow: ___flows back and forth_________________ magnetic field: ___reverses each time the polarity reverses_ In your home, the current completes a complete cycle (from forward -> to reverse -> back to ...
Cavity magnetron
The cavity magnetron is a high-powered vacuum tube that generates microwaves using the interaction of a stream of electrons with a magnetic field while moving past a series of open metal cavities (cavity resonators). Bunches of electrons passing by the openings to the cavities excite radio wave oscillations in the cavity, much as a guitar's strings excite sound in its sound box. The frequency of the microwaves produced, the resonant frequency, is determined by the cavities' physical dimensions. Unlike other microwave tubes, such as the klystron and traveling-wave tube (TWT), the magnetron cannot function as an amplifier, increasing the power of an applied microwave signal, it serves solely as an oscillator, generating a microwave signal from direct current power supplied to the tube.The first form of magnetron tube, the split-anode magnetron, was invented by Albert Hull in 1920, but it wasn't capable of high frequencies and was little used. Similar devices were experimented with by many teams through the 1920s and 30s. On November 27, 1935, Hans Erich Hollmann applied for a patent for the first multiple cavities magnetron, which he received on July 12, 1938, but the more stable klystron was preferred for most German radars during World War II. The cavity magnetron tube was later improved by John Randall and Harry Boot in 1940 at the University of Birmingham, England. The high power of pulses from their device made centimeter-band radar practical for the Allies of World War II, with shorter wavelength radars allowing detection of smaller objects from smaller antennas. The compact cavity magnetron tube drastically reduced the size of radar sets so that they could be installed in anti-submarine aircraft and escort ships.In the post-war era the magnetron became less widely used in the radar role. This was because the magnetron's output changes from pulse to pulse, both in frequency and phase. This makes the signal unsuitable for pulse-to-pulse comparisons, which is widely used for detecting and removing ""clutter"" from the radar display. The magnetron remains in use in some radars, but has become much more common as a low-cost microwave source for microwave ovens. In this form, approximately one billion magnetrons are in use today.