SU61694A1 - Modulation method for the frequency of the electron-beam oscillator with volume circuits - Google Patents

Description

The known methods of frequency modulation of an electron-beam generator with internal volumetric circuits do not perform modulation at high modulating frequencies and cannot simultaneously modulate the carrier frequency of a number of high frequencies.

The described method provides these qualities, which is achieved by changing the time of flight of electrons through the drift space. In this case, less power is spent on modulation than in the known methods.

The device for implementing the method provides for switching the modulator consistently with sources of constant operating voltage on the volumetric circuits of the electron-beam generator, which are slightly distorted one to another by the small amount and connected to one or both resonant circuits. In addition, in order to reduce the power per modulation, an electrode is provided inside the device in the electron drift space, to which the modulating voltage is connected.

FIG. shows a diagram of a device (electron beam generator), in which the method is implemented with changing the time of flight of e.chektrons by changing the operating voltage; in fig. 2 is the same, with the electrode inserted into the drift space.

If the working (high) voltage on the electron beam generator | If you make it a little smaller than its optimal value, the electrons through the space / drift will fly more slowly, and the groups of electrons will arrive at the second resonator 2 with some delay. As a result, the natural frequency of the oscillatory system formed by the two cavity resonators, the antenna and the electronic field 61694-2, is slightly reduced. On the contrary, as the operating voltage rises, the natural frequency will increase. This phenomenon takes place in all self-excited oscillators, in which the time of flight of electrons is not small compared with the oscillation period. The magnitude of the change in frequency with the change in operating voltage will depend on many reasons. For example, the frequency change will be the greater, the more energy is brought by a separate troupe of electrons, compared with the stock of electromagnetic energy in the resonator; the change in frequency will depend on the radio-technical properties of the two resonator cavities, on the magnitude of the connection between them, and on the load and the method of communication with it.

The advantages of the proposed frequency modulation method are that modulation can be performed with a sufficiently large frequency (which cannot be done with mechanical methods of modulation of frequency) and it is possible to simultaneously modulate the carrier frequency of a number of high frequencies, i.e., the proposed method. frequency of the electron-beam oscillator provides an opportunity in the region of the microvolous. he can get all the advantages that frequency modulation has over the amplitude.

The study of the transit time can be achieved not only by changing the operating voltage (Fig. 1), but also by changing the voltage on the additional electrode 3 introduced into the drift space in order to modulate or focus.

The advantages of this method are in a small capacity, which must be spent on modulation. A1 modulating electrode 3 can be made in the form of qi; 1iidra, rings or other elements to increase the frequency change of the electron-beam generator with a change in time of flight | 1 of the electrons; .

This can also be achieved by attaching additional resonators appropriately tuned to one or both of the cavity resonators.

When the oscillation amplitude of the generator is modulated by a change in the electron transit time, the increase in modulation is achieved by the fact that a small change in the oscillation frequency causes a sharp redistribution, an increase in the amplitudes of the oscillations between the resonators.

P r d omete 3 o brete and

Claims (4)

1. A method of modulating the frequency of an electron-beam oscillator with internal volumetric circuits, characterized in that in order to perform modulation at high modulating frequencies, as well as simultaneous modulation at high frequencies, the time of flight of electrons through the drift space is changed. 2. Electron beam lamp with volumetric circuits for ocyiuect method in clause D, characterized in that the modulator is connected in series with the source of constant operating voltage on the volumetric contours of the electron beam generator. 3. The form of the lamp according to claim 2, characterized in that, in order to increase the depth of the frequency modulation, the volume contours , dispersed alone in relation to the other. I am on a small amount. 4. Forms of lamp manufacturing according to claims. 2 and 3, characterized in that