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A klystron is a specialized vacuum tube (evacuated electron tube) called a linear-beam tube. The pseudo-Greek word klystron comes from the stem form κλυσ- (klys) of a Greek verb referring to the action of waves breaking against a shore, and the end of the word electron. The Varian brothers (Russel and Sigurd) of Stanford University are generally considered to be the inventors of the klystron. Their prototype was completed in August 1937. Upon publication in 1939, news of the klystron immediately influenced the work of US and UK researchers working on radar equipment. The Varians went on to found Varian Associates (now known as Varian Medical Systems) to commercialize the technology. During the second World War, the Axis powers relied mostly on klystron technology for their radar system microwave generation, while the Allies used the far more powerful but frequency-drifting technology of the cavity magnetron for microwave generation. Klystron tube technologies for high-power applications such as synchrotrons and radar systems have since been developed. Explanation Klystrons are used as an oscillator or amplifier at microwave and radio frequencies to produce both low power reference signals for superheterodyne radar receivers and to produce high-power carrier waves for communications and the driving force for linear accelerators. It has the advantage (over the magnetron) of coherently amplifying a reference signal and so its output may be precisely controlled in amplitude, frequency and phase. Many klystrons have a waveguide for coupling microwave energy into and out of the device, although it is also quite common for lower power and lower frequency klystrons to use coaxial couplings instead. In some cases a coupling probe is used to couple the microwave energy from a klystron into a separate external waveguide. Two-cavity klystron amplifier
Two-cavity klystron oscillator The two-cavity amplifier klystron is readily turned into an oscillator klystron by providing a feedback loop between the input and output cavities. Two-cavity oscillator klystrons have the advantage of being among the lowest-noise microwave sources available, and for that reason have often been used in the illuminator systems of missile targeting radars. The two-cavity oscillator klystron normally generates more power than the reflex klystron—typically watts of output rather than milliwatts. Since there is no reflector, only one high-voltage supply is required; however, to cause the tube to oscillate, the voltage must be adjusted to a particular value. This is because the electron beam must produce the bunched electrons in the second cavity in order to generate output power. Voltage must be adjusted by varying the velocity of the electron beam to a suitable level due to the fixed physical separation between the two cavities. Often several "modes" of oscillation can be observed in a given klystron. Reflex klystron
Multicavity klystron In the multicavity klystron, multiple toroidal cavities surround a cylindrical acceleration tube. To achieve high efficiency the electron would have to be modulated by a saw-tooth signal, so that very small bunches enter the second cavity when the voltage peaks. The saw-tooth is synthesized by a fourier series. The harmonics needed for this series are usually generated from the beam itself, but wider bandwidth, efficiency and stability may be achieved by generating them before the klystron. Tuning a klystron Some klystrons have cavities that are tunable. Tuning a klyston is delicate business that if not done properly can cause damage to equipment (klystrons can cost as much as a house or a luxury car) or even injury to the technician. By adjusting the graduated knobs found on the body of the klystron, metal grids inside the klyston cavities change the resonant frequency that the cavities resonates at delivering peak transmitter power output (TPO) for the desired frequency. The technician is careful not to exceed the limits of the graduations, because the grid can fall off the corkscrew which the grid rides on, inside the cavity. This permanantly damages the klystron and may even result in a wave of improperly reflected power back into upstream equipment, causing further damage. Manufacturers generally send a card calibrated unique to that klystron's performance characteristics, that lists the graduations that are to be set, for any given frequency. No two klystrons are alike (even when comparing like part/model number klystrons) so that every card is specific to the individual unit. Klystrons have serial numbers on each of them that distinguishes them uniquely, and for which manufacturers may (hopefully) have the performance characteristics in a database. If not, loss of the calibration card may be an insoluble problem, making the klystron unusable. Other precautions taken when tuning a klystron include using nonferrous tools. If ferrous (magnetically reactive) tools come too close to the intense magnetic fields that contain the electron beam (even when turned off, these fields are present since they are due to permanent magnets) the tool can pulled into the unit by the intense magnetic force, smashing fingers, hurting the technician, or damaging the klystron. Special lightweight nonmagnetic tools made of beryllium alloy have been used for tuning U.S. Air Force klystrons. Precautions are routinely taken when transporting klystron devices freely in aircraft, as the intense magnetic field can interfere with magnetic navigation equipment. Special overpacks are designed to help limit this field "in the field," and thus transport the klystron safely. Optical klystron In an optical klystron the cavities are replaced with undulators. Very high voltages are needed. But the gun, the drift tube and the collector are still used. Floating drift tube klystron
Collector The used electron beam is sent through an electron spectrometer. Electrons with different energies are then retarded by different DC fields, so they all hit their collectors with low energy. This process provides several advantages: unused energy flows back to the power supply; unwanted X-rays and secondary electrons are minimized; and the system runs at a lower temperature, minimizing the need for cooling. Applications These amplifiers are used to produce UHF, SHF, and EHF signals where such high amplitude (power) is required that solid state devices are inadequate. Klystrons can be found at work in radar, satellite and wideband high-power communication (very common in television broadcasting and EHF satellite terminals), and high-energy physics (particle accelerators and experimental reactors). At SLAC, for example, klystrons are routinely employed which have outputs in the range of 50 megawatts (pulse) and 50 kilowatts (time-averaged) at frequences nearing 3 GHz * A misleadingly similarly named tube, the krytron, has been used in nuclear weapons, used as switches to detonate explosives at high speeds to start the fission process. They have also been used in Photocopiers. Klystron tube trivia/popular culture See also | |||||||||||||
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