DE1295098B - Deflection amplifier tubes working without a magnetic field - Google Patents

Description

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The invention relates to an elongated quasi-stationary without fields between the twisted plates Magnetic field working deflection amplifier tube with are.

a constant beam current instead of the twisted capacitor plates can

Electron beam generating system, a coupling in and the coupling out parts also from each part in which the beam electrons pass through cross-field 5 two delay lines with such a taxation there is a degree of delay corresponding to the input signal that the axial propagation deflection from the axis of the unmodulated elec- tric speed along this delay line tron beam experience, a decoupling part, in which advancing signal waves equal to the Triftdas amplified input signal due to the influence of the speed of the electrons. As an embodiment, the electron beam is decoupled and a double meander line can be used for this purpose Collecting electrode. Find a turn.

Such a tube is already known (one can use twisted plates as single equals For example, the German patent coupling part, the electron beam enters the Ver-1 033 342). Despite its simple structure, it has a stronger part in the form of an expanding funnel this known tube because of its very low distortion. The individual electrons, all one only radially Strengthening cannot prevail. To this man-directed deflection from the axis of the unmodulating gel To be able to remedy the low gain that th ray possesses, are on the circumference of the Trichwurde also already distributed in the German patent ters, the cross-section of which is circular. Each 1 215 819 an elongated cyclotron wave ar- electron is generated when entering the amplifier part in The parametric cathode ray tube in the direction of the pair of electrodes with the more positive one beat. Such a tube, however, needed to accelerate the voltage. The electrons get there operation a longitudinal magnetic field around which, depending on its position, in addition to its only radial next translational deflection of the electrons in directional deflection a deflection in azimuthal to transfer a rotational movement. Next to it direction. After a certain running distance in However, in these known deflection amplifier tubes 25, the amplifier section has the electrons again because of the rotational movement of the electrons, the same deflection movement direction as in the one-phase relationship between the cyclotron wave im enters the amplifier section. The length of the amplifier electron beam and the pump shaft. Only in the case of riehteiles is therefore advantageously dimensioned in such a way that a The phase position of the electrons in relation to the pump field is the same as the electron exiting the amplifier part a gain of the input signal. 30 The direction of deflection has as with its entry

The invention has now set itself the task of entering the amplifier part.

a simply structured, working without a magnetic field because the electron beam emerges from the

Creating a tube that diverges a sufficiently high amplifier-amplifier section is advantageous between The effect of a coupled-in signal makes it possible to use electrons without an amplifier part and a decoupling part the complicated structure and the relative converging optical lens can be provided. It is suitable Narrow band of a parametric cyclotron - especially an electrostatic single lens, having to accept corrugated tube. The invention is based on the schematic

To solve this problem, a deflection figure of the drawing, which relates to an execution amplifier tube of the type mentioned in the introduction according to the example of the deflection amplifier according to the invention Invention proposed that relates between the single 40 tube, will be explained in more detail: coupling part and the decoupling part with electrical F i g. 1 shows a section through the booster statics Fields working amplifier part in the form of a tube between coupling and amplifier part. as a quadrupole is provided, in which the coupling-in part are twisted capacitor plates past signal by increasing the deflection of the turns. The two capacitor plates will do that Beam electrons is amplified. The amplifier part 45 is supplied with an input signal. The effect of the distraction can from four axially symmetrical around the elec- tric field one can understand in the following way, electron beam arranged to the electron beam We think of it as usual the sinusoidal itself convexly curved signal voltage that changes straight in the direction of the beam and consists of two opposite directions fenden plate-shaped electrodes. equal angular velocity rotating pointers

Assembled for the proposed deflection amplifier tube 50. By suitably twisting the Coupling parts can also be used to advantage. Plates can be achieved that the one pointer the one, which in a further development of the invention from twist "stops", while the other with double ten capacitor plates exist. So that a possible angular velocity rotates. The standing pointer gives good coupling between the input signal for a given electron velocity and the electrons can be achieved, an in according to the "angular frequency of twisting" about the direction of the beam moving forward, its direction chosen equal to the signal frequency. Under »Circle Retaining Vector. The second pointer acts as a frequency of twisting ”is understood to mean the disturbance, which is, however, negligibly small if spatial repetition of a full revolution of the signal voltage over a period of several Coupling part. With the required equality of 60 periods, one electron acts. The single in "Angular frequency of twisting" and signal frequency of beam direction moving electron is located - What with a given signal frequency and coupling part - so in a deflection field in which it is as in twisting is essentially a condition of a plate capacitor with a static field or Equal velocity of the beam electrons as in the deflection system of a traveling field oscilloscope - The graph transported in the coupling part thus runs only in the radial direction with a constant Signal field conforming to the deflection and movement force is deflected. The single electron runs against it of the beam electrons. The length of the in and long of a parabola. An electron that becomes a spä-Auskoppelteiles is dimensioned so that the direct point in time occurs in the capacitor takes place

a different phase position of the signal voltage and thus a different direction of the electrical vector before and is deflected in a corresponding manner along a parabolic path. As an overall picture for the electron beam the result is a funnel with a circular cross-section and a parabolic surface line. The arrows 1 to 7 in FIG. 1 show the deflection direction of some electrons of this beam upon entry in the amplifier part. The amplifier part consists of the plate pairs 8 and 9 or 10 and 11. The plate ίο th 8 and 9 or 10 and 11 of a pair of plates must have the same potential for a Quadrupole field forms. If the plates 8 and 9 have a more positive DC potential than the plates 10 and 11, there is an accelerating effect for electrons with the direction of deflection of arrow 3, and an accelerating one for electrons with a deflection direction according to arrow 6, a retarding force. Electrons with one direction of deflection according to the arrows 1, 2, 4, 5 and 7 are deflected in the direction of the plate 8 and the plate 9, respectively.

In Fig. 2, the image of the paths of some individual electrons in the amplifier part is shown in cross section. Electrons with a deflection direction according to arrow 3 in FIG. 1 are accelerated in a straight line. It results the path 14. electrons with a deflection direction according to arrows 1 and 5 of FIG. 1 will be in Direction of the plate 8 of FIG. 1 is deflected and the more it accelerates, the more it moves away from the path 14 approaching. The paths 15 and 16 result for these electrons. This results in an analogous manner to path 14 a path 17. Electrons, which with a deflection direction approximated to the direction of the arrow 6 in FIG. 1 in the Entering the amplifier part will also be deflected laterally. This results in the tracks 18 and 19. It can be seen that thus all electrons entering the amplifier part from the axis of the unmodulated beam can be accelerated away. After a certain period of time, the electrons have again the same direction of deflection as when entering the amplifier part (for electrons according to arrows 1 and 5 at point 20 or for electrons in the vicinity of arrow 6, points 21 and 22). Of the The amplifier part is similar in this respect to a klystron amplifier, in which the amplifier also determines has excellent lengths.

In Fig. 3 schematically shows a cross section through a deflection amplifier tube according to the invention. Here, 23 denotes the coupling part, 24 the amplifier part and 26 the decoupling part. 25 represents an electron-optical collecting lens, the task of which is to bring the electrons into the coupling-out part to enter converging.

The use of twisted capacitor plates for the coupling part requires that the angular frequency the twist must be approximately equal to the signal frequency if there is sufficient coupling between the input signal and the electron beam is to be achieved. This coupling part is very broadband, as shown in FIG. 4 is to be shown. If there is a match between Signal frequency and angular frequency of the twist results in a deflection z. B. in the direction of Lane 27. The more the signal frequency deviates from the angular frequency of the twist, the stronger it is the curvature of the electron paths 28, 29 and 30. The shorter the coupling-in distance, the better it can be these curved paths can be regarded as straight lines. The circle 31 indicates the length of the Coupling section. The exit paths 32 to 34 from the coupling part of the curves 28 to 30 give way then only slightly depends on a radius vector.

The invention is not limited to the use of couplers with twisted capacitor plates. Each arrangement, one on a continuous Single electron rectified force is generated in the deflection amplifier tube according to the invention applicable. In the event that delay lines with transverse fields are used as the coupling part the result is a ribbon-shaped electron beam, which expands in a parabolic shape in the direction of the beam. You will then place the amplifier part so that the electrons of this beam only in radial Direction to be distracted further.

The main advantage of the deflection amplifier tube according to the invention is that there is no magnetic field and thus no magnetic field generation system is required. There is also a phase relationship between electrons and quadrupole field is obsolete. Since no pump frequency is required, this can be done Generate the quadrupole field very easily and there is also no need for an additional pump oscillator.

Claims (9)

Patent claims: 1. Elongated deflection amplifier tube operating without a magnetic field with a constant one Electron gun emitting beam current, a coupling part in which the beam electrons a deflection corresponding to the input signal by transverse field control from the axis of the unmodulated electron beam, a decoupling part in which the amplified input signal is decoupled from the electron beam by an influence effect and a collecting electrode, characterized in that between the coupling part and an amplifier part operating with electrostatic fields in the coupling-out part Form of a quadrupole is provided in which the input signal by increasing the deflection the beam electrons is amplified. 2. deflection amplifier tube according to claim 1, characterized in that the amplifier part from four axially symmetrical around the electron beam, curved convex to the electron beam, consists of plate-shaped electrodes running straight in the direction of the beam. 3. deflection amplifier tube according to claim 1 or 2, characterized in that the one and the coupling-out part consist of twisted plates. 4. deflection amplifier tube according to claim 3, characterized in that the »angular frequency the twist «is approximately equal to the signal angular frequency. 5. deflection amplifier tube according to claim 4, characterized in that the length of the input and the decoupling part is dimensioned so that the fields between the twisted plates are quasi-stationary are. 6. deflection amplifier tube according to claim 1 or 2, characterized in that the input and output coupling parts each consist of two delay lines with such a delay that the axial propagation speed of the signal waves propagating along these delay lines is equal to Is the drift speed of the electrons. 7. deflection amplifier tube according to claim 6, characterized in that the delay lines are meander lines. 8. deflection amplifier tube according to claim 2 and one of claims 3 to 5, characterized in that that the length of the amplifier part is dimensioned so that an emerging from the amplifier part Electron has the same direction of deflection as when it entered the amplifier part. 9. deflection amplifier tube according to one of claims 1 to 8, characterized in that an electrical converging lens, in particular between the amplifier part and the coupling-out part an electrostatic single lens is arranged. 1 sheet of drawings