RU2768373C1 - Device for generation of directed narrow-band radiation of the decimeter band - Google Patents

Abstract

FIELD: radiophysics

SUBSTANCE: invention relates to the field of radiophysics, HF and microwave technology, high-current electronics, etc., and can be used to generate powerful directional narrow-band electromagnetic radiation in the decimeter range when testing the electromagnetic compatibility of various infrastructure facilities, as well as in other research activities. The device for generating directional narrow-band radiation of the decimeter range contains an initial microwave signal source, the output of which is connected in parallel to the inputs of two microwave radiation amplifiers, the outputs of which, in turn, are connected to the inputs of two transmitting antennas. Parallel to the source of the original microwave signal, a second source of the original microwave signal is connected, one diode is installed in front of the amplifier inputs, and the polarities of the diodes are opposite. Between the output of one of the amplifiers and the input of the corresponding transmitting antenna, a long cable line and a polarity switch of the amplified signal are connected in series.

EFFECT: expanding the functionality of the device for generating directional narrow-band radiation of the decimeter range by providing the possibility of forming radiation, which is composed of various combinations of two bands.

1 cl, 2 dwg

Description

The invention relates to the field of radiophysics, RF and microwave technology, high-current electronics, etc., and can be used to generate powerful directional narrow-band electromagnetic radiation in the decimeter range when testing the electromagnetic compatibility of various infrastructure facilities, as well as in other research activities

Devices for generating microwave radiation based on systems with a virtual cathode are known from the prior art. These devices contain electron sources made in the form of vacuum chambers with a cathode and an anode, drift chambers, and horn antennas for outputting radiation into open space [1, 2]. Microwave radiation in such systems is generated by electron oscillations in the gap between the real and virtual cathode, and its temporal characteristics are set by the geometrical parameters of the drift chamber.

In addition to low generation efficiency (≈1%) and a large radiation divergence angle (up to 90°), devices with a virtual cathode have a very narrow set of functionality, in particular, the ability to form microwave radiation with only one frequency.

Known devices based on relativistic klystrons with explosive cathodes that generate pulsed microwave radiation [3, 4]. These devices, in addition to klystrons, also contain vacuum systems and special modulators that generate pulses with a duration of no more than 1 μs with a pulse frequency of the order of I kHz. The maximum operating resource of such devices is limited by the resource of the klystron cathode and, as a rule, does not exceed 10 million pulses.

Radiation generators based on relativistic klystrons are characterized by a complex bulky design, high cost and low reliability. Also, when carrying out a number of research works, the determining factor limiting the practical use of such generators is often a very limited set of functional capabilities, which include the inability to form microwave radiation with two or more frequencies.

Closest to the claimed device is a source of microwave radiation, which includes one source of the original microwave signal connected in parallel to two amplifiers of microwave radiation, the outputs of which are connected to the inputs of two antennas, through which the directional output of radiation into the surrounding space is carried out [5]. Each amplifier contains two klystrons, a modulator, a phase shifter and an attenuator, as well as one resonant compressor of microwave radiation. The source of the original microwave signal provides a constant frequency of the reference microwave signal coming to the inputs of the amplifiers.

The disadvantage of this device is that. that the source of the initial microwave signal generates a reference signal with only one frequency arriving at the inputs of the amplifiers. As a result, the source of microwave radiation generates directional narrow-band microwave radiation with a sinusoidal pulse shape of only one frequency, which greatly limits its functionality.

The task to be solved by the claimed invention is the creation of a device for generating directional narrow-band radiation of the decimeter range with wider functionality.

The technical result of the proposed invention is the expansion of the functionality of the device for generating directional narrow-band radiation of the decimeter range by providing the possibility of generating radiation, consisting of various combinations of two bands.

The technical result is achieved by the fact that in a device for generating directional narrow-band radiation of the decimeter range, containing a source of the original microwave signal, the output of which is connected in parallel to the inputs of two microwave amplifiers, the outputs of which, in turn, are connected to the inputs of two transmitting antennas, what is new is that parallel to the source of the original microwave signal, a second source of the original microwave signal is connected, one diode is installed in front of the inputs of the amplifier, and the polarities of the diodes are opposite, and a long cable line and a polarity switch of the amplified signal are connected in series between the output of one of the amplifiers and the input of the corresponding transmitting antenna.

Connecting the second source of the original microwave signal in parallel to the first one makes it possible to form complex signals with two independent frequencies at the inputs of the microwave amplifiers and, as a result, allows generating microwave radiation containing two bands, and thereby expands the functionality of the proposed device.

The use of oppositely directed diodes installed in front of the microwave amplifier inputs makes it possible to separate bipolar signals from sources of original microwave signals in such a way that a positive component of the original bipolar signal comes to the input of one microwave amplifier, and a negative component of the original bipolar signal comes to the input of another. This separation further makes it possible to form delays between the two components of the amplified electrical signal, as well as control their polarity, and thereby expands the functionality of the proposed device.

Connecting to the output of one of the amplifiers of a long cable line allows, by changing its length, to obtain the necessary time delay between the fixed phases of the two components of the amplified electrical signals coming to the inputs of the transmitting antennas from the microwave amplifiers. This makes it possible to form radiation pulses of complex shape, which expands the functionality of the proposed device.

The inclusion of a polarity switch in the section of the circuit between the cable line and the corresponding transmitting antenna allows you to control the polarity of the amplified electrical signal passed through this line, which, together with the adjustment of the delay between the two components of the amplified electrical signals, makes it possible to form radiation with various complex shapes of unipolar and bipolar pulses, and thereby expanding the functionality of the proposed device.

On FIG. 1 shows a circuit diagram of the device, where 1 are sources of initial microwave signals, 2 are diodes, 3 are microwave radiation amplifiers, 4 is a long cable line, 5 is a polarity switch, 6 are transmitting antennas.

On FIG. Figure 2 shows oscillograms of two primary sinusoidal pulses at the outputs of sources of initial microwave signals with frequencies of 500 MHz a), as well as with frequencies of 500 and 750 MHz d), and the radiated power pulses obtained on their basis b), c) and e), f) , respectively.

The device for generating directional narrow-band radiation of the decimeter range (Fig. 1) contains two parallel-connected microprocessor sources of initial microwave signals 1, the common output of which is connected through two oppositely directed semiconductor switching microwave diodes 2 to the inputs of two broadband microwave radiation amplifiers 3. The output of one of of the microwave radiation amplifier 3 is connected to the input of one of the transmitting antennas 6 through a long cable line 4 connected in series, which forms a delay of the amplified signal component passing through it, and a mechanical polarity switch of this signal component 5. and the output of another microwave radiation amplifier 3 is connected directly to input of another transmitting antenna 6.

The device works as follows. When a single digital control signal is applied, identical sources of initial microwave signals 1, made on the basis of commercially available medium-class microwave signal generators, form independent sequences of ~1 mW bipolar sinusoidal signals with fixed frequencies of ~1 GHz at their outputs. These signals are summed at a common point and form a single two-band bipolar signal, which, after passing through the oppositely directed switching microwave diodes 2 (2A511A). is transmitted to the inputs of two identical commercially available high-frequency solid-state power amplifiers 3 (~1 kW, ~1 GHz). At the same time, only the positive component of the total signal comes to the input of one of the amplifiers 3, and only the negative component of the total signal comes to the input of the other. Further, these components are amplified by the same number of times (~60 dBm) and transmitted to the inputs of identical combined log-periodic directional antennas 6 with a gain of ~10 dB, which generate decimeter radiation corresponding to the components in open space.

Electric power from the output of one of the microwave amplifiers 3 goes directly to one of the transmitting antennas 6, and from the output of the other it is first transferred to a long cable line 4, made from a piece of cable of the RK-50-3-26 brand. When passing through the cable line 4, a time delay is formed for this component of the amplified electrical signal relative to the component that goes directly to the antenna 6. The length of the cable line is selected from the condition that it takes about 3.3 ns to pass one meter of this cable.

After passing through a long cable line 6, the unipolar component of the amplified electrical signal is transmitted to the corresponding transmitting antenna 6 through a mechanical polarity switch 5, made on the basis of a standard industrial two-position toggle switch, designed for a maximum voltage of 380 V and a current of 10 A. With one position of the toggle switch of the amplified signal component passes through the polarity switch 5 without change, and with the other - with inversion.

Upon reaching the components of the amplified electrical signals of the inputs of the respective transmitting antennas 6, the latter in combination with each other generate at a given point in the open space two-band radiation of the decimeter range with pulses of a given complex shape and constant time characteristics, resulting from a superposition of independent unipolar radiation pulses of individual antennas 6.

Calculations and preliminary experiments have shown that the claimed device can generate both pulsed and continuous directional two-band radiation of the decimeter range with a power of about one kilowatt. As an illustrative example, in Fig. Figure 2 shows some oscillograms of the radiated power obtained by numerical simulation of the operation of this device in an anechoic chamber. It is assumed that the claimed device will be used when testing the electromagnetic compatibility of various objects of modern microelectronic infrastructure and in other experimental research activities.

Sources of information:

[1] M. Haworth, B. Anderson, et. el, "Operation of repetitively pulsed virtual cathode oscillators on the TEMPO pulser" // IEEE Trans, on Plasma Science, 1991, vol. 19, No. 4, pp. 655-659.

[2] H. Sze, J. Benford, et. el. "Dynamics of a virtual cathode oscillator driven by a pinched diode" // Phys. Fluids, 29(11), Nov. 1986, pp. 3873-3880.

[3] RU No. 2343584, prior. 07/17/2007, Stepanov H.V., Selemir V.D., Voronin B.V., Alekhin B.V., Klistron, publ. 01/10/2009.

[4] RU No. 2507625, prior. 08/01/2012, Ptitsyn B.G., Selemir V.D., Yachny A.V., Klistron, publ. 20.02.2014.

[5] RU No. 191221, prior. 09/28/2018, Maslennikov O.Yu., Microwave radiation source, publ. 07/30/2019.

Claims (1)

A device for generating directional narrow-band radiation of the decimeter range, containing a source of the original microwave signal, the output of which is connected in parallel to the inputs of two microwave radiation amplifiers, the outputs of which, in turn, are connected to the inputs of two transmitting antennas, characterized in that a second source is connected in parallel to the source of the original microwave signal of the original microwave signal, one diode is installed in front of the inputs of the amplifiers, and the polarities of the diodes are opposite, and a long cable line and a polarity switch of the amplified signal are connected in series between the output of one of the amplifiers and the input of the corresponding transmitting antenna.

Images