DE1002814B - Traveling wave tube oscillator tunable in a wide frequency band - Google Patents

Description

GERMAN

In a wide frequency band
Tunable traveling wave tube oscillator

Applicant:

Compagnie Generale de Telegraphie
Sans FiI, Paris

Representative: Dipl.-Ing. E. Prinz, patent attorney,
Graefelfing near Munich, Aribostr. 14th

Claimed priority:
France January 17, 1955

Marien Wasserman, Paris,
has been named as the inventor

The invention relates to tunable traveling wave tube oscillators. Traveling wave tube oscillators with wide Tuning ranges in which the tuning takes place entirely electrically are known. This kind of Voting is generally very beneficial. However, under certain conditions it can happen that electrical tuning is undesirable and a simple mechanical tuning is preferable is.

The aim of the invention is to create a traveling wave tube oscillator with broadband properties in which the tuning is done entirely by mechanical means is made, which are attached outside the tube and operated from the outside.

Traveling wave tube arrangements are known in which mechanically tunable, outside the tubes Attached cavities are used. In these arrangements the cavities are connected in series connected between the load and the output of the tubes, and they then act mainly as band filters, since each arrangement actually contains two tunable cavities, followed by one tunable as well Are coupled to the slot.

In the devices according to the invention, η

tunable cavity resonators for one another

Purpose and used in a different way. Fig. 1 shows a first embodiment of the invention

The traveling wave tube oscillator according to the invention is an oscillator according to the invention. The tube contains in one provided with a delay arrangement, the at least vacuum bulb 1, a delay line 2 and a No dispersion electron guns for a certain frequency band 3. An electron beam 4, has properties. The load that is sent out by the electron gun 3 in a certain 30% The extent to which must be mismatched is to which one end is being accelerated by an anode 5 plants coupled to the delay line, while one continues parallel to the delay line 2 and becomes tunable cavity resonator with a high quality factor captured by a collecting electrode 6. Preferential its other end is coupled, with the delay line having as little means as possible are seen to attenuate any reflection at the latter end 35.

to connect. An output line is at the end of the collector

Further details of the invention emerge from the tube provided. For example, this is

the following description of some design-speaking end of the line 2 connected to a conductor 7

examples and on the basis of the drawing. Herein shows closed, which passes through a glass cap 8,

Fig. 1 shows a first embodiment of the invention 40 which closes the end of an output waveguide 8 °.

according to the oscillator in longitudinal section, the latter is always mounted so that it has a low

Mismatch between the line 2 and the consumer shown schematically at L causes. At the other end on the cathode side, the line 2 is connected to an absorption block 10 by means of an input conductor 9, which extends through an insulating seal II ⁶ and an input waveguide 11, which is located at the closed end of the waveguide 11 remote from the piston 1. Material and shape of the

Fig. 2 to 4 three modified embodiments,

Figures 5 and 6 are dispersion curves of delay lines used in the tube according to the invention can be

7 shows the cross section of another embodiment of the tube according to the invention,

FIG. 8 shows a simplified side view of the tube according to FIG. 7,

Fig. 9 Details of another tube according to the 50 block 10 must be chosen so that a practical

Invention and

10 to 13 are examples of delay lines for use in the oscillator according to the invention are suitable.

table results in perfect matching in the operating frequency band of the tube. The waveguide 11 is with a Lateral _Stichleitung 11 ° provided, which in a cavity resonator 14 opens with a high quality factor. One

609 836/324

3 4

Probe 12 with end loops 13 and 26 couples the hollow conduit possible, the entire phase shift of the

Conductor with the resonator 14. The latter can, for example, delay line 2 and the resonator 14 together

be tuned by means of a cover 15, which is equal to a desired oscillation frequency F ± ε

is unscrewed and to make a volume change of 2 % N , with the frequency shift

Permitted cavity. - _r · 5 is practically negligible. As this is for each frequency

The oscillator according to FIG. 1 can be tuned in a broad band that is related to one another within the tuning band of the cavity 14. This band can be tuned without any frequency gap, as long as a remarkable result can only be achieved if one is on the branch AB or EF of the delay when the delay line 2 is in the operating frequency band io line, which corresponds to a vanishing dispersion of the tube a practically vanishing dispersion. At the cavity 14 are matched, ie if the frequency of the speed absorbent to avoid any reflection on the speed of the beam 4 is practically independent. This applies to delay line coupled, which then applies when the delay line results in a dispersive single feedback loop which has the delay curve similar to FIG. 5 or 6. 15 line 2 and the cavity 14, while the

These figures show dispersion curves; H. the formation of other feedback loops, which the hollow

, f .., .. ,,. c, ",. . ,. room resonator 14 not included and therefore oscillating

Delay behavior - as a function of λ, where c ,, ... _Λ , ■ ,. , _£

⁰ ° v- cause regardless of its vote

the speed of light and ν the phase speed could be avoided.

The ability of a theory and experiment that propagates in the delay line show that the invented wave and λ the operating length of the oscillator of the tube according to the present invention are not only within a wide frequency range. As is well known, the curve branches AB band is continuously tunable, but also and DF is the spatial fundamental wave and the branches AC have excellent pulling properties, or EF is the first partial wave (space harmonics) which when the tube is to work in pulse mode

energy propagating in the delay line. It is also known that the branches AB and EF are provided with a dispersion curve as shown in FIG. This corresponds to a forward wave, ie a partial wave, which makes it possible to switch on every disturbance oscillation in the π-mode off phase velocity with the same sign as the one. As is well known, these vibrations correspond to the group velocity of the energy, while those to point A in Fig. 5 and point F in Fig. 6. They correspond to Asteyl-C and DF of a backward wave. H. a partial wave in which the phase velocity ν passes through the corresponding points corresponding to the opposite sign as the group values in which the curve tangent has the velocity of the energy. is vertical, i.e. the change in wavelength as

FIG. 5 corresponds, for example, to a helical line function of the phase velocity, the sign or to a ladder-like delay line according to FIG. 35 changes. Moreover, after they have been fanned out in FIG. 13, that is to say one with a base plate 50, these vibrations are able to continue for other values of ν and a step 51 in the vicinity of the central part of the so that interfering vibrations in the π-mode rungs 52 . very well with vibrations at the desired frequency

Fig. 6 corresponds, for example, to a line with a sequence that can be present at the same time, interlocking members and a base plate 53 40 right along the branch AB or EF which are connected according to FIG. 11, or a rung dispersion curve according to FIG. 5 or 6, ie from A to B line with two rung groups 54 and 55 according to FIG. 5 and from E. to F in Fig. 6. If the tube Fig. 12. 45 works in pulse mode, the electron

The operation of the oscillator according to the invention speed at 0, reaches a certain maximum can probably be explained as follows. value and returns to 0. In the case of FIG. 5, as is well known, in every traveling wave tube that at the apparently the electron velocity always goes through the cathode-side or collector-side end incorrectly to the value corresponding to point A , while is matched, by reflection at one or both ends 50 in the case of FIG 6 the operation along the branch EF in front of the tube a kind of vibrations are generated. can go without ever reaching point F. In known tubes of this type, however, it is not. Therefore, in the case of pulse operation, a delay is possible to achieve a broad, continuous, uninterrupted line with a delay curve according to FIG. 6, that is to say broken tuning range. This would only be possible with forward wave propagation for the first space if the electrical length of the 55 harmonic is preferred.

A feedback circuit comprising a delay line. Some modifications of the tube of FIG. 1 are shown in FIG

for each frequency of the band in question equal to 2πΝ Fig. 2, 3 and 4 shown, with only the changed would be, where N is an integer. This is physically parts are drawn.

not possible. In the embodiment of FIG. 2, the position is

It is now known that the phase jump which occurs at 60 of output 7-8 and resonator 14 interchanges. Corresponds to cavity resonator with a high quality factor. In the embodiment according to FIG.

as a function of frequency within a very narrow sorption block 10 is omitted. Its task is taken over by the band in the vicinity of the resonance frequency of a damping, which at the end part 24 of the cavity changes very quickly between -f- π and - π delay line 2 or at least in high frequency and that the phase jump change of the delay field 65 of the same is provided is. The probe 12 connects line with the frequency being much slower. If, in this case, the line 2 is connected directly to the entire phase resonator 14 for a given frequency F.

displacement of the delay line 2 is not the same. In the embodiment according to FIG. 4, the position is

π N , where N is an integer, it is interchanged by the output 7-8 and the resonator 14 with the damping addition of the resonator 14 to the delay 70 of FIG. 3, similar to FIG. 2 ,

FIGS. 7 and 8 show a further embodiment of the invention. The tube represents a familiar one Magnetron, which works with crossed magnetic and electric fields, and does not need im to be described individually. It includes a positively biased delay line 2, a negatively biased one Electrode 16, which carries the cathode 3, and a shield 17, which is connected to the bulb 1 is and serves to decouple the ends of the line 2 and as a collecting electrode for the beam. A A transverse magnetic field is generated by the pole shoes 18 shown in FIG. 8.

The output 7-8 and the resonator 14 can be arranged according to one of FIGS. 1 to 4. The order According to FIG. 7, for example, corresponds to that according to FIG. 1.

In Fig. 9, the invention is applied to a simplified tube in which the shield 17 ^a decouples only the ends of the line 2, while the electrode 16 ° represents a closed cylinder. This results in undesirable feedback from the beam. In order to avoid this, an electron-absorbing substance 19 is arranged in a manner known per se on the circumference of the cylinder 16 °. In one of the arrangements according to FIGS. 1 to 4, the invention can also be applied to this tube. For example, FIG. 9 shows the arrangement according to FIG. 2, in which the resonator 14 is connected to the collector-side end of the tube and the output 7-8 is located at the cathode-side end.

Of course, the invention can also be applied to other types of traveling wave tube oscillators.

Claims (9)

PATENT CLAIMS: 35 1. Traveling wave tube oscillator, tunable over a wide frequency band, in which an electron beam interacts with a forward wave running along a delay line with each other decoupled ends, characterized in that the delay line has a dispersion curve whose branch corresponding to the operating conditions has practically no dispersion in the desired frequency band, that one end of the line with little mismatch in the desired band to a consumer is coupled that the other end of the line with matched in the desired band Absorbing means (10, 24) for the radio frequency energy is coupled, and that a mechanically tunable High quality factor cavity (14) to the connection between the delay line and the absorption means is coupled, the tuning of the cavity the oscillation frequency determined in the desired frequency band. 2. Oscillator according to claim 1, characterized in that the absorption means (10) outside of the tubular piston are arranged. 3. Oscillator according to claim 1, characterized in that the absorption means (24) within of the tubular piston are arranged. 4. Oscillator according to claim 1, characterized in that the absorbent consists of a damping Layer (24) consist on a part of the delay line adjacent to the end. 5. Oscillator according to claim 1 to 4, characterized in that the delay line in its Main part is undamped. 6. oscillator according to claim 1 to 5, characterized in that the with the absorbent The coupled end of the delay line is on the side of the electron beam source. 7. oscillator according to claim 1 to 5, characterized in that the coupled to the consumer The end of the delay line is on the electron beam source side of the tube. 8. Oscillator according to claim 1 to 7, characterized in that the dispersion curve of the delay line a branch with negative dispersion, which corresponds to the spatial fundamental wave, and has a branch with practically vanishing dispersion, which corresponds to the first partial wave. 9. Oscillator according to claim 1 to 7, characterized in that the dispersion curve of the delay line a branch with practically vanishing dispersion, which corresponds to the spatial fundamental wave, and a branch with a negative one Has dispersion, which corresponds to the first partial wave. Considered publications:
French Patent No. 998 836. 1 sheet of drawings © 609 836/324 2.57