RU2288519C1 - Noise-like broadband microwave signal generator built around virtual cathode - Google Patents

Abstract

FIELD: microwave electronics; various chaotic-signal based radar, counterradio, and communication systems, industrial installations, and medical instruments.

SUBSTANCE: proposed generator designed to produce noise-like broadband superhigh- and ultrahigh-frequency oscillations of medium power depending for its operation on non-relativistic electron beam in virtual cathode generation mode has electron source, electrodynamic system with energy output and collector, as well as at least one grid disposed between electron source and collector perpendicular to electron beam direction for shaping virtual cathode in electromagnetic system between grid and collector. Electron source is made in the form of electron gun and collector, in the form of electrode disposed at generator output. In addition, generator is provided with second grid disposed between first grid and collector for shaping virtual cathode between grids. Electrodynamic system can be made in the form of spiral slow-wave structure section. Electron gun is provided with thermionic cathode, modulating grid, and anode.

EFFECT: reduced power level of noise-like broadband signals produced by generator.

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Description

The invention relates to non-relativistic microwave electronics, in particular to devices for generating broadband noise-like microwave oscillations of an average power level, and can be used in various radar systems, radio countermeasures, communication systems based on chaotic signals, industrial applications, as well as in medical devices destination.

In microwave electronics, there are a number of devices used to generate chaotic noise-like oscillations, the so-called chaos generators (Afanasyev V.V., Trubetskov DI Dynamic chaos in electronic microwave devices. Part I. Vacuum non-relativistic devices. Reviews on electronic technology. Series 1. Microwave electronics. - issue 3 (1614). - 1991 - 40 s. - part II. Relativistic electronics devices. - issue 4 (1615) - 1991 - 32 s.). First of all, these are TWT-generators with delayed feedback - noise generators (Kislov V.Ya., Myasin EA, Zalogin E.N. Study of stochastic self-oscillating modes in delayed oscillators // Radio Engineering and Electronics. - 1979. - T. 24. - N 6. - p.1118) and solid-state microwave noise generators (Kalyanov EV. Synchronous and stochastic self-oscillations in a transistor microwave generator with delayed feedback under the parametric action of an external force // Radio engineering and electronics. - 1987. - v.32. - No. 4. - p.784).

However, all these sources of a chaotic microwave signal are characterized by a very narrow frequency band of noise-like oscillations, which does not exceed 20%. This is a serious drawback of such devices, because in applications, it becomes necessary to create sources of noise-like oscillations with a frequency bandwidth of one or two octaves.

One of the solutions to this problem is to create sets of narrow-band noise-like signal generators that are tuned to different frequency ranges in such a way as to obtain the necessary frequency bandwidth of the noise-like signal.

However, this approach leads to a complication of the design and a decrease in the reliability of the devices. In addition, such schemes cannot be used in modes when it is necessary to control the spectral composition of radiation.

Thus, the development of devices for broadband noise-like oscillations with a characteristic frequency band of one or two octaves and with the ability to control the spectral composition of radiation is currently relevant.

Closest to the claimed is a microwave generator on a virtual cathode - vircator. The vircator type devices contain the following main structural elements: a powerful electron source made in the form of a metal disk (the design of the device allows the use of different cathode geometry), an anode made in the form of either a grid or a foil transparent to the electron flow, an electrodynamic system made in the form waveguide, as well as energy output, made in the form of a horn. In this case, the collector is the walls of the waveguide onto which the spent electron beam settles. These devices belong to powerful relativistic microwave electronics, the generation method of which is that a pulsed relativistic electron beam is formed in the high-current vacuum diode of the device and injected with a current above the limit vacuum into the equipotential cavity of the waveguide. An unsteady virtual cathode is formed in the cavity, the oscillations of which are a source of powerful microwave radiation. Such devices are characterized by a wide complex spectral composition of the radiation, which allows us to consider them as possible prototypes of noise-like radiation sources (US Patent No. 4345220, IPC: H 03 B 9/01, Alyokhin BV, Dubinov AE, Selemir VD et al. Theoretical and experimental studies of virtual cathode microwave devices // IEEE Trans. Plasma Sc., 1994, v. 22, No. 5, p. 945).

However, for the operation of the vircator it is fundamentally necessary to use high-current relativistic electron beams, since the starting currents of such devices are very high. The magnitude of the starting current is determined by the limiting vacuum current. In addition, this device is characterized by a narrow generation band and the inability to control the output radiation bandwidth.

The objective of the invention is to create a source of controlled broadband (with a bandwidth of more than an octave) noise-like oscillations of a small power level of the centimeter and millimeter wavelength ranges based on a nonrelativistic electron beam in modes with the formation of a virtual cathode.

The problem is solved in that in the generator of a noise-like broadband microwave signal on a virtual cathode containing an electron source, an electrodynamic system with an energy output and a collector, according to the proposed solution, at least one grid located between the electron source and the collector (perpendicular to the direction of the electron beam) with the possibility of forming a virtual cathode in the electrodynamic system between the grid and the collector, while the source of elec thrones made in the form of an electron gun, and the collector - in the form of an electrode located at the output of the generator.

The generator further comprises a second grid located between the first grid and the collector, with the possibility of forming a virtual cathode between the grids.

In this case, the electrodynamic system can be made in the form of a segment of a spiral decelerating system or in the form of a segment of a coaxial line, or in the form of a strip line.

The electron gun is made with a thermal cathode, a modulating grid and anodes. The energy output is made in the form of a coaxial transmission line.

The technical result achieved in the proposed non-relativistic microwave generator with a virtual cathode is that it is possible to significantly reduce the starting current of the electron beam at which a virtual cathode is formed compared to the prototype (vircator with a high-current relativistic beam) with the simultaneous ability to control the bandwidth of the generated chaotic oscillations. In the implemented device, the design is such that a non-stationary virtual cathode is formed in a nonrelativistic beam with additional braking and there is the possibility of expanding the band of generated frequencies to one or two octaves.

The invention is illustrated by drawings, where Fig. 1 schematically shows the inventive microwave generator, Fig. 2 shows the experimental dependence of the integral power P of the output signal taken from a segment of an electrodynamic system (ECO) on the normalized potential difference between the grids. Figure 3 - experimental dependence of the characteristic generation frequency and bandwidth of broadband noise-like oscillations in a beam with a virtual cathode, depending on the normalized potential difference between the grids. The positions in the drawings indicate: 1 - non-relativistic electron beam, 2 - thermal cathode, 3 - focusing electrode, 4 - modulating grid, 5 - accelerating anode, 6 - first grid, 7 - second (braking) grid, 8 - segment of the electrodynamic system (ECO ), made in the form of a spiral, 9 — an absorbing insert, 10 — energy output, 11 — collector, 12 — virtual cathode formed in the electron beam.

The proposed vacuum non-relativistic microwave generator of broadband noise-like oscillations contains the following main structural elements (figure 1). As the source of the axially symmetric electron beam 1, an electron gun is used, which includes a thermal cathode 2, a focusing electrode 3, a modulating grid 4 and an anode 5, to which an accelerating potential V ₀ is supplied. After the electron gun, the electron beam with the initial electron velocity dispersion falls into the grid gap, consisting of the first (input) grid 6 and the second (output) grid 7. The grid gap is placed in the broadband segment of the electrodynamic system 8 (OES), used to output the generated high-frequency power. The OES is loaded onto the absorbing insert 9 and the energy output 10. Next, the spent electron beam was deposited on the collector 11.

The device operates as follows.

An intense electron beam is injected into the grid gap, which is formed by an electron gun with a modulating grid 4 (see Fig. 1), to which the potential is higher than the natural one. The modulating grid increases the spread of electrons along the longitudinal and transverse velocities, which contributes to the creation of the most efficient virtual cathode and increases the output power, expanding the band of generated frequencies. The potential of the first grid 6 of the grid gap is equal to the potential of the anode V ₀ , the braking potential V _brake is applied to the second grid 7, which can vary from V _brake / V ₀ = 1 (no electron braking) to V _brake / V ₀ = 0 (full braking electronic flow). With an increase in the braking potential of the second grid at a certain critical value of the potential in the electron beam, a virtual cathode 12 appears (see Fig. 1), whose oscillations in time and space modulate the electron beam in speed and density, and some of the electrons are reflected back from the virtual cathode to the first grid. As a result, chaotic oscillations appeared in the system, the bandwidth and power of which depends on the potential of the second grid. To output a broadband chaotic signal, OES 8 is used, which allows you to remove microwave power in the frequency band of more than two octaves.

As experimental studies and numerical modeling of such a circuit have shown, by varying the inhibitory potential, it is possible to control both the amplitude of chaotic microwave oscillations and the frequency bandwidth (from narrow-band, close to single-frequency vibrations, and to broadband noise-like vibrations with a bandwidth of more than an octave) .

Presented in figure 2 and 3, the experimental dependences confirm the possibility and efficiency of generating broadband chaotic signals using the proposed generator. Figure 2 shows the dependence of the integral power of oscillations on the normalized potential difference between the grids, from which it can be seen that there is an optimal value of the braking potential at which the integral power of oscillations in the beam with a virtual cathode is maximum. Figure 3 presents the dependences of the normalized bandwidth of the generation system, measured by the spectra of power oscillations recorded by the ECO. Figure 3 also shows the dependence of the characteristic (most intense in the power spectrum) generation frequency in the system on the magnitude of the braking potential difference between the grids. It can be seen that the normalized lasing bandwidth in the proposed generator increases with the growth of the braking potential difference. Thus, we can talk about two characteristic operating modes of the proposed generator of broadband noise-like oscillations on a virtual cathode: a narrow-band mode close to regular oscillations, which is realized at small excesses of the beam perveance of a critical value (small beam braking in the grid gap) and the regime of developed chaotic lasing with broadband spectrum (the latter is realized at large perveances of the electron beam, i.e., with significant deceleration of the beam).

Thus, using the proposed generator, it is possible to significantly reduce the starting current of the electron beam, at which a virtual cathode is formed, with the simultaneous possibility of obtaining broadband noise-like microwave radiation with a bandwidth of more than an octave, which achieves the solution of the problem.

Claims (3)

1. A generator of a noise-like broadband microwave signal on a virtual cathode, containing an electron source, an electrodynamic system with an energy output and a collector, characterized in that it contains at least one grid located between the electron source and the collector perpendicular to the direction of the electron beam with the possibility of forming a virtual cathode in the electrodynamic system between the grid and the collector, while the electrodynamic system is made in the form of a segment of a spiral retarding system, the energy output is made in the form of a waveguide transmission line, the electron source is made in the form of an electron gun, and the collector is in the form of an electrode located at the output of the generator. 2. The microwave generator according to claim 1, characterized in that it further comprises a second grid located between the first grid and the collector, with the possibility of forming a virtual cathode between the grids. 2. The microwave generator according to claim 1, characterized in that the electron gun is made with a thermal cathode, a modulating grid and anodes.

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