DE912979C - Traveling field limiter tube - Google Patents

Description

ISSUED JUNE 8, 1954

W 77 ^ 3 VIII c j3ig

has been named as the inventor

Traveling-field limiter tube

The invention relates to traveling wave tubes, which for certain ranges of the input amplitude Exercise limiting effect.

The invention consists in the creation of a traveling wave tube that is in a receiver or Amplifier can be used and with which one can do that when receiving high frequency signals can reduce interference noise that occurs.

The advantages of a microwave transmission system include the ability to handle a large number of channels of communication to be able to transmit at the same time, and the possibility in the receiving or repeater station renew the received signal pulses, d. H. to be able to practically rebuild in order to to decipher them or to transmit them further, free of the obscuring background noises, with which the pulses have been mixed during the transmission process. The realization these possibilities requires, among other things, that the equipment used is capable of to be able to transmit a large bandwidth and operate at very high frequencies. The requirements are met by a so-called high-frequency traveling-field limiter tube. The limiter tube works in such a way that high-frequency signal pulses within a certain Amplitude range are transmitted, while for signal pulses below and above this area is completely or partially blocked. In this way, the unwanted noise, that arrives with and between the signal pulses and that generally above and below the signal level is eliminated. The present invention is implemented in the following Explanation and the drawings explained more fully:

Fig. Ι shows a traveling-wave helical tube as an example of the invention, in which a narrow axial electron beam is used;

FIG. 2 is a diagram used to explain the mode of operation of a tube according to FIG serves;

FIG. 3 illustrates an embodiment of the invention which operates in the same way as the tube in FIG Fig. I, but in which a hollow tubular Electron beam is used.

In Fig. Ι the inner parts of a limiter tube are enclosed in a vacuum-tight piston 1, which can consist of glass or another suitable insulating material. The tubular cathode 2 with a disk-shaped part 3, which can be concave and which is coated with emission material, is heated by the filament 4. The base of the cathode 2 is connected to the focusing electrode 8, which is held in the piston 1 by the precisely fitted disks 11. One end of the filament 4 is connected to the cathode at part 3, from there the connection goes via the electrode 8 and the conductor 5 to the connection point between one pole 5 of the battery 7 and the negative pole of the battery 29. The other pole of the battery 7 is connected by the conductor 6 to the other end of the filament 4, so that the cathode is heated and the part 3 is caused to emit electrons. The acceleration electrode 9 is connected to the positive pole of the battery 29 via the helix 13 and the conductor 27. The electrons withdrawn from the cathode surface 3 by the positive electrode 9 are focused by the electrodes 8 and 9 and pass through a small limiting opening 10 which is located in the center of the electrode 9. The helix 13 is supported against the piston 1 by two or more ceramic rods 14. At the left end, namely at the entrance, the helix 13 is connected to the electrode 9 via a straight piece of the coupling conductor 17 and from there through the piston 1 via the bridging capacitance between the electrode 9 and the waveguide flange 22 to one side of the input waveguide 23 . At the right end, namely at the exit, the helix 13 is over a straight piece of the coupling conductor 20 to the tubular electrode 21 and from there through the piston 1 through the bridging capacitance between the electrode 21 and the waveguide flange 24 to one side of the output waveguide 25 connected. The coil 13 is held at the potential of the positive pole of the battery 29 by the conductor 27. This potential is set so that the electron speed along the filament is substantially equal to the wave propagation speed along the filament. An input signal applied to the waveguide 23 is transmitted via the coupling conductor 17 to the input of the helix on the left and travels to the right. The radio-frequency energy absorbing waste material 12, which is arranged on the holding rods 14 in the vicinity of the center of the coil, prevents a substantial amount of the electromagnetic energy on the coil from being able to pass from the left side of this point to the right side. The material thus divides the helix into two waveguide sections between which there is no substantial coupling, namely the input section between the input coupling conductor 17 and the loss material 12 and the output section between the loss material 12 and the output coupling conductor 20. Each on the right-hand side of the helix Occurring wave is transmitted into the output waveguide 25 via the coupling conductor 20.

The electron beam emerging from the opening 10 is focused on a small disc located in the middle or on an obstacle 15 which is held in the helix axis and connected to the helix by a wire 16. The obstacle 15 is located in the area of the lost material 12 or somewhat to the left of it. It is so large that if there is no input signal on the filament, all or almost all of the electron beam will be intercepted by the obstacle. The beam emerging from the opening 10 electron beam 19 can be focused on the obstacle 15 by means of a small focusing coil 18 or the larger _go solenoid. These coils can be excited by a suitable direct current source, not shown, to generate a magnetic field in a constant direction.

Since a magnetic wave advancing on the helix to the left of the lost material 12 is caused by the Material is captured, and because the electron beam at a very low level of the input signal is caught by the obstacle 15 located near the center of the helix, small ones become Signals applied to the input of waveguide 23 do not produce output signals in waveguide 25. However, as the level of the input signal increases, the field of the helix becomes to the left of the The center of the filament acts so strongly on the electron beam that the electrons are deflected radially will. Some electrons will miss the obstacle 15 in the process. The electrons that are the obstacle do not meet and get to the right end of the spiral, a signal no induce, which is derived as an output signal in the waveguide 25. These electrons will collected by the collecting electrode 26, which is connected to the battery 29 via the conductor 28 is. Since the output signal therefore depends on the electrons that are deflected by the input signal so that they miss the obstacle 15, the output power will be a function of the Change the input power roughly as shown in FIG. If the input power is small no output power available (see at 34). With a slightly higher input power you get one small output power (see at 35). After that, the output power increases rapidly with the input power (see at 36). With an even larger entrance power, the output power increases as a result of the

Non-linearity becomes less rapid with the input power, and finally becomes a maximum at 37 Output power reached. Thereafter, an increase in the input power results in a decrease in the output power (see at 38).

The characteristic curve of the tube shown in FIG. 2 is for the recovery of pulses whose Amplitudes distorted by noise are desirable; because usually it will be between the Noise present in the input pulses may be so weak that no corresponding output occurs • can; a noise which would like to generate a peak amplitude can be eliminated as a result of the limiting effect. Each the amplitude of one The irregularity related to the output pulses becomes a smaller irregularity in the output pulses cause when the energy of the input pulses is such that the generated output pulse amplitude is in the region of 37 according to FIG.

FIG. 3 shows an embodiment of the invention which operates in a manner similar to that in FIG. 1 at however, which uses a tubular electron beam and a different type of construction.

The evacuated piston 41 of the tube is made of metal. He is pumped out through the tube 70, which can consist of glass fused to the flask. The cathode 42 is annular and has a recessed annular surface 43 which

coated with emission material and heated by the filament 44. The filament 44 is connected to one side of the battery 47 via the conductor 45 and to the other side of this battery via the cathode 42 and conductor 46, the cathode at the same time being connected to the negative side of the battery 69 via the conductor 46. The annular accelerating electrode 49 is connected via conductor 48 to a tap on battery 69 which is positive with respect to the cathode. The electrons withdrawn by the positive electrode 49 from the cathode surface 43 in the form of a tubular beam pass through the almost complete narrow circular slit 50 in the accelerating electrode 49 and fly along the outer surfaces of the cylindrical electrodes 71 and the helical coil 53. The helical coils 53 and 72 and the metal lock washer 55 connecting the two coils are held by two or more ceramic rods 54, the ends of which are supported by the cylindrical electrodes 71 and 61. The electrodes 71 and 61 are secured against the piston by a number of parts, e.g. B. Head 67, supported and insulated, which are fused in the flask by glass beads, such. B. the conductor 67 by the glass bead 73. The conductor 45, the cathode 42, the electrode 49 and the collecting electrode 66 are held in the same way by glass beads and insulated, as shown in the figure.

At the input on the left, the helix 53 is connected to the electrode 71 via the coupling line 57 and from there via the bridging capacitance between the electrode 71 and the metal ring 62 connected to the bulb and to one side of the input waveguide 63. On the right The output is the coil 72 via the coupling conductor 60 to the electrode 61 and from there j about the bridging capacity between the! Electrode 61 and the metal ring 64 on the piston ι and on one side of the output waveguide 65, closed. About the conductor 67, the helix 53 and 72 and the electrodes 61 and 71 are with a J tap of the battery 69 connected and thereby have a potential which is positive with respect to the Cathode is. This potential is dimensioned so that the electron speed on the filament im is essentially equal to the phase velocity of the waves advancing along the helix. Of the The tubular piston is connected to a tap on the battery 69. As shown is the electron collection electrode 66 connected via the conductor 68 to the same tap of the battery 69 as the Conductor 67, but it can also be connected to another point on the battery. An input signal wave, which enters the input waveguide through window 51 is through the Coupling conductor 57 is transmitted to the left end of the helix 53 and migrates to the right. The lost material 52, which can absorb radio frequency energy, and which is on the rods 54 on the other Located at the end of the helix 53, the helix terminates with its wave resistance. Through this Resistance termination 52 and through the lock 55 no substantial part of the goes along the helix 53 progressing input energy to the helix 72. The helix 53 and 72 therefore represent two transmission line sections between which there is no substantial electromagnetic coupling. They correspond to the input and output line sections the helix 13 in FIG. 1.

The tubular electron beam exiting the circular slot 50 is very narrow. It is focused on the edge of the disk 55. For this purpose, the electrical focusing between the electrode 49 and the electrodes 71 and 62 can be used. Furthermore, a magnetic longitudinal field, as it is generated by the electromagnets 58 and 59, and a voltage difference between 71 and 62 can be used. The electromagnets 58 and 59 can be excited with the aid of a suitable direct current source, not shown. The electron beam is focused on the disk 55 in such a way that the latter blocks the beam completely when there is no high-frequency input signal on the input waveguide 63. On the other hand, if a high frequency input signal of sufficient amplitude is applied, the beam will be deflected inwards and outwards. As a result of the outward deflection, some electrons generally pass the disk and continue to fly along the outer surface of the helix 72. These induce a signal in the helix "] 2 which is propagated on the helix and transmitted through the coupling conductor 60 to the output waveguide 65, which it can leave through the melted-down window 74. The

Helix 72 is at the other end by the Rods 54 attached loss material 56 completed. The electrons at lock 55 pass, are collected by the collecting electrode 66. How the tube works in Fig. 3 is the same as that of the tube in Fig. I. The output power changes with the Input power as shown in FIG. As a result, the tube separates that Noise and other irregularities in the signal in the same way as it was with the above Explanation of Fig. 1 was given.

Although the invention on the basis of special embodiments has been described, other arrangements can of course also be proposed without deviating from the essence and aim of the invention.

Claims (3)

Patent claims: i. High-frequency traveling wave tube, which has two sections of a waveguide connected in series within an evacuated flask, each section being a plurality of wavelengths in length and an electrode is arranged between the two sections by way of the electron beam is, characterized in that between the line sections and in the path of the electron beam arranged electrode is connected directly to the waveguide and such Has shape that it blocks essentially all electrons when used as an input line section serving a lower signal level is applied, while at higher Signal levels an increasing proportion of electrons passes the barrier electrode continue to fly along the other line section. 2. The high-frequency traveling wave tube according to claim i, wherein the waveguide is made of helical shape guided conductors, characterized in that the blocking electrode is inside the helix is arranged at the junction of the two line sections of essentially the same size and is dimensioned so that between its circumference and the inner surface of the helical conductor an annular one Passage remains free. 3. The high-frequency traveling wave tube according to claim i, wherein the waveguide is made of helical shape There are guided conductors and the electron beam has the shape of a helical one Conductor enclosing hollow cylinder, characterized in that the blocking electrode has the shape of a disk and is essentially the same at the junction of the two large line sections arranged transversely to the helical conductors and dimensioned is that between its circumference and the piston of the tube there is an annular passage remains free. Referred publications:
French patent specification No. 934 220, 735; U.S. Patent No. 2,367,295. 1 sheet of drawings © 9506 5.54