DE1136424B - Strophotron oscillator tube - Google Patents

Description

The invention relates to strophotronic oscillator tubes, ei. H. Multi-transit electron tubes used for application in the high and maximum frequency range, especially in the meter and decimeter wave range, are suitable.

A strophotronic oscillator tube with an elongated plane of symmetry to a longitudinal plane has already become symmetrical acceleration electrode and with two elongated, symmetrical to the mentioned Flat reflector electrodes arranged in the longitudinal plane of symmetry, and thus also to the acceleration electrode proposed in which the reflector electrodes facing cross-sectional side of the acceleration electrode according to a Branch of an at least approximately equilateral hyperbola is formed and that of the acceleration electrode facing cross-sectional sides of the two reflector electrodes along the to the hyperbolic branch belonging asymptotes.

In this case, the cathode is usually adjacent in a slot in one of the reflector electrodes attached to one end of the accelerating electrode, while the collector is adjacent to the is arranged at the other end of the accelerating electrode. Between the two reflector electrodes a load is coupled. The acceleration electrode is opposite the reflector electrodes kept at a high positive equal potential, and as a result of the described training the Electrodes have a hyperbolic potential distribution in that of the acceleration electrode and the Adjusts reflector electrodes limited area.

In this area, a uniform magnetic field is also generated, the field vector in a Direction perpendicular to the longitudinal plane of symmetry points.

The electrons emitted by the cathode then travel along a curved path the collector and have the characteristic strophotron behavior, d. i.e., the projection of this Orbit on the longitudinal plane of symmetry resembles successive cycloids or trochoid, while the projection of this path onto a longitudinal plane perpendicular to the longitudinal plane of symmetry of a damped one Simis wave, which runs along an axis determined by the intersection of the two planes.

However, the tube according to the older proposal has deficiencies in that the required magnetic field strength for a certain position of the cathode increases with increasing oscillator frequency and ultimately becomes unacceptably high.
The required magnetic field strength could

Applicant:

Sylvania Electric Products Incorporated,
a society according to the law

of the State of Delaware,
New York, NY (V. St. A.)

Representative: Dipl.-Ing. H. Görtz, patent attorney,
Frankfurt / M., Schneckenhofstr. 27

Claimed priority:
V. St. v. America 6 September 1957 (No. 682 458)

Ralph Herbert Bartram, Nöw York, N. Y. (V. St. A.), has been named as the inventor

can be decreased by the vertical distance between the cathode and the vertex of the hyperbolic shaped cross-sectional side of the accelerating electrode is increased. However, this takes Distance increases, the DC potential increases at the points where the emitted electrons die Cut the longitudinal plane of symmetry, and finally becomes practically equal to the reflector equal potential. Since the output power of the strophotronic oscillator tube changes (for a fixed tube geometry and fixed Values of the applied DC potentials) directly with the DC potential difference between the reflector electrodes and these intersection points changes, thus increasing when the vertical distance between the Cathode and the apex of the hyperbolic cross-sectional side of the accelerating electrode increases, also the output power of the strophotronic oscillator tube.

The invention is intended to avoid these disadvantages and to create a strophotronic oscillator tube, which is designed to operate at a given frequency within the frequency range of the tube required magnetic field strength is reduced or with the (for a fixed tube geometry and fixed values of the applied DC potentials) a higher output power is achieved.

The invention is a strophotron oscillator tube, with an elongated to a

20 »640/269

3 4

Longitudinal symmetry plane symmetrical acceleration - the reflector electrodes limited area becomes a

generation electrode and generated with two elongated, symmetrically uniform magnetic field, whose

metric to the named longitudinal plane of symmetry, and field vector H in a direction perpendicular to the longitudinal

thus also points towards the acceleration electrode, plane of symmetry. To create this field

arranged reflector electrodes, in which the means of FIG. 5 are customary (not illustrated here)

Reflector electrodes facing cross-sectional side 'used. The between in the circumferential direction

Asymptotes lying on the acceleration electrode corresponding to a neighboring hyperbolic branch

Branch of an equilateral hyperbola is formed. 26, 28, 30 and 32 of the hyperbolic branches of the

According to the invention, it is characterized in that the acceleration and reflector electrodes are correct compared to the mentioned (first) acceleration io coincide with one another.

The two acceleration electrodes 10, 12 are drie-plane symmetrical, elongated (second) loading on a positive DC potential + F ₁ , the two acceleration electrode is arranged and both reflector electrodes 18, 20 on a negative one facing the reflector electrodes Cross-equal potential - V ^ held. As a result, the cross-sectional side of the second acceleration electrode 15 generates the electric constant field occurring between the acceleration and the reflectors and the two acceleration electrodes gate electrodes, a cross-sectional side of each reflector-electric hyperbolic electric potential distribution in the electrode, likewise corresponding to a branch of an electron interaction area. (The acceleration equilateral hyperbola is formed, and that the electrodes and the reflector electrodes extend between circumferentially adjacent hyperbolic ²⁰ to be sufficiently eliminate far outwards, Irish to interfering elekzweigen lying asymptotes of Hyperbelzweige fringing fields.) Match, and thus all asymptotes in a slot the reflector electrode 18 is per se in one of the longitudinal plane of symmetry belonging to one end of which intersect at the level of the apex 22 an intersection point. Cathode 34 arranged. In a further embodiment of the invention, the hyperbolic branches are identical to one another at the same constant potential for the sake of simplicity, and, like the acceleration electrodes 10, 12, are held in pairs opposite one another, is located adjacent to the other end of the electrodes the same potential. Reflector electrode 18. Between the reflector electrode 18, 20 a load 38 is coupled, which can be an ohmic resistance for a given output power, but mostly a field strength compared to the previously required on the oscillator frequency tuned resonance is to reduce or vice versa for a circle.

Given magnetic field strength the output From the cathode 34 the electrons are with

performance compared to the previously achievable substantially an extremely low speed emitted

to increase. 35 and enter the interaction area.

The invention will be described in the following on the basis of a. Many of these electrons then migrate along one

Embodiment in connection with the curved path to the collector 36 and

Drawings explained in more detail. It shows the characteristic strophotron behavior

Fig. 1 is an isometric view of a stropho-. That is, the projection of this curved one

tronoszillatorröhre according to the invention, 40 track resembles the longitudinal plane of symmetry, as in

Fig. 2 is a diagram of the electrical potential Fig. 3a illustrates successive cycles

distribution between the acceleration electrodes' kloiden, while the projection of this path onto a

and the reflector electrodes according to FIG. I ^- and the longitudinal plane perpendicular to the longitudinal plane of symmetry

FIGS. 3a and 3b are graphs showing the movement of a damped sine wave corresponding to FIG. 3b

Electrons with a favorable phase relationship in 45 is similar. The frequency of the sine wave is the oscillator

Interaction area between the acceleration frequency, which is primarily determined by the between the

supply electrodes and the reflector electrodes. Acceleration electrodes and the reflector elec-

In the case of a tube according to FIG. 1, an electric field that does not trode is determined.

illustrated) evacuated piston two vertically The cycloid frequency is determined by both the above-

Elongated accelerations offset from one another, as well as by the magnetic field mentioned above

supply electrodes 10 and 12 and two in the same aforementioned electric field and determined by the

Directional, horizontally mutually independent oscillator frequency. (The magnetic

offset, elongated reflector electrodes 18 and field strength is set to a value at which

20 arranged. The acceleration electrodes and it is prevented that electrons on the acceleration

the reflector electrodes have a uniform 55 supply electrodes impinging on or entering from them.

Cross-section, and both of which will catch the two reflector.)

The cross-sectional side of each electrode facing the cross-sectional side of each acceleration electrode as well as the cross-sectional reflector electrodes facing the two between the acceleration electrodes and the acceleration electrodes is graphically shown in FIG. As can be seen from this figure, the branch of an equilateral hyperbola is formed. The electrical potential V for a corrected point P hyperbolic branches of the acceleration electrodes 10, between the acceleration electrodes and the 12 have vertices 14, 16, the hyperbolic branches of the reflector electrodes proportionally (jβ - x ² ), where y reflector electrodes 18, 20, vertices 22, 24. The vertical distance between the point P and acceleration electrodes 10, 12 and the reflector 65 the asymptotic intersection and χ of the horizontal electrodes 18, 20 are symmetrical to a longitudinal distance between the point / * and the asymptotic plane of symmetry, which the vertex 14 , 16 belong. Intersection is. The equipotential surfaces 54 form In the through the acceleration electrodes and groups of equilateral hyperbolas with the lines y

= ± χ as asymptotes 26, 28, 30 and 32. Since the acceleration electrodes 10, 12 determine surfaces with the potential + F ₁ and the reflector electrodes 18, 20 surfaces with the potential -F ₂ , the asymptotes 26, 28, 30 and 32 lines of intermediate potential F ₃ .

The electrons induce as they move towards the reflector electrodes 18, 20 to and from them away an alternating voltage of the oscillator frequency at the load 38 (Fig. 1). This tension works in turn back to the electrons and causes the damping. In particular, an electron vibrates when it leaves the cathode and enters the interaction region at times in which it is "in phase" with the induced alternating voltage (such an electron is called a Electron with a favorable phase relationship), between the reflector electrodes in the in Fig. 3 indicated way back and forth. The electrons that enter the interaction area at times during which they are "out of phase" with the induced alternating voltage, hit after the first or second passage through the longitudinal plane of symmetry on one of the reflector electrodes and are thereby removed from the interaction area. So only the electrons remain with a favorable phase relationship for a larger period of time in the interaction area, and the Oscillator voltage occurring at load 38 is caused by the out-of-phase electrons practically not affected.

The initial amplitude of the sinusoidal motion of an electron is through the vertical Distance of this electron from the vertex of the associated acceleration electrode determined; this amplitude decreases with increasing distance. As a result of the hyperbolic electrical potential distribution however, the oscillator frequency remains constant when this vertical distance changes.

From FIGS. 1 and 2 it can be seen that the potential of the points at which the electrons emitted by the cathode 34 intersect the longitudinal plane of symmetry, depending on the vertical distance between the cathode 34 and the apex of the associated acceleration electrode, between the limits + F ₁ and F ₃ lies.

In known strophotronic oscillator tubes, the reflector electrodes are kept at ground potential (zero potential). Therefore, when the vertical distance between the cathode and the vertex of the accelerating electrode is increased, the potential of the electron intersection points with the longitudinal symmetry plane approaches the earth potential, and the output power, which changes directly with the potential difference between these points and the reflector electrodes, goes towards zero. In contrast, in the subject matter of the invention, the reflector electrodes z. B. held at a constant potential -F ₂ . If the vertical distance between the cathode and the apex of the associated acceleration electrode is increased here, the output power decreases to a much smaller extent and finally reaches an appropriately large final value.

For a given output power, in known strophotronic oscillator tubes, the vertical Distance between the cathode and the apex of the acceleration electrode is essential be smaller than the tube according to the invention. Hence that for the tube according to the invention required magnetic field strength significantly lower than with known strophotron oscillator tubes.

It should be understood that the present invention is not limited to that specifically described and illustrated Embodiment is limited, but numerous modifications are possible without from Deviate inventive ideas.

Claims (2)

PATENT CLAIMS: 1. Strophotronoszillatorröhre with an elongated, elongated to a longitudinal plane of symmetry symmetrical acceleration electrode and with two symmetrically with respect to said longitudinal plane of symmetry, and thus also to the acceleration electrode, reflector arranged electrodes, wherein the reflector electrodes facing cross-sectional side of the acceleration electrode is formed corresponding to a branch of an equilateral hyperbola, characterized characterized in that opposite the mentioned (first) acceleration electrode a further elongated (second) acceleration electrode, symmetrical to the said longitudinal plane of symmetry, is arranged and both the cross-sectional side of the second acceleration electrode facing the reflector electrodes and the cross-sectional side of each reflector electrode facing the two acceleration electrodes also correspond to a branch of a equilateral hyperbola is formed and that the adjacent between in the circumferential direction n hyperbolic branches asymptotes of the hyperbolic branches coincide, and thus all asymptotes also intersect at an intersection point belonging to the longitudinal plane of symmetry. 2. Strophotronoszillatorröhre according to claim 1, characterized in that the hyperbolic branches are identical to one another and have electrodes lying opposite one another in pairs are on the same potential. Considered publications:
Swiss Patent No. 311963;
"Proceedings IRE", 1954, p. 1239 if .;
"Ericsson Technics", No. 2, 1956, pp. 165 ff .;
"L'Onde Electrique", 1957, p. 159 ff. 1 sheet of drawings © 209 640/2 »9.62 '