RU2595797C1 - Device for testing electromagnetic field of secondary emitters - Google Patents

Abstract

FIELD: wireless communications.

SUBSTANCE: present invention relates to radio communication and can be used in solving the problem of electromagnetic compatibility of radio-electronic equipment, as well as the analysis of parameters of secondary radiation of different media. Device includes a clock pulse generator, a radiation spectrum, a receiving-transmitting antennae, a receiving antenna system, upper and lower parts of a high-voltage irradiating system, a high-voltage source, an adaptive converter, a secondary emitter radiation information generator, a frequency spectrum converter, a filter unit, a radiation spectrum analysis unit, a unit for analysing secondary radiation spectrum.

EFFECT: technical result: automation of analysis of frequency properties of the secondary radiation field of tested objects and their levels.

18 cl, 23 dwg

Description

The invention relates to the field of radio communications and can be used to solve the problem of electromagnetic compatibility of electronic equipment, as well as the study of the parameters of the secondary radiation of various environments.

The well-known "Method for the detection of moving electrically conductive objects", patent RU 2303290, G08B 13/24 from 07.20.2007. The invention relates to the field of security and is intended for the detection of moving electrically conductive objects. It consists of a generator exciting electromagnetic radiation using an antenna system. For registration of excited currents in moving electrically conductive objects, receiving antenna systems connected to recording equipment are used. However, it cannot be used for non-moving objects and non-conductive media, and also to determine the parameters of the secondary radiation, for example, the frequency of the secondary emitter, the polarization of the vector and the field level.

The well-known "Device for the simultaneous detection of several explosives and drugs in baggage", patent 2128832 RU, G01N 24/00, G01R 33/20 from 04/10/1999. The device comprises a reference frequency unit, a receiver and a storage device, a unit of frequency synthesizers for nuclear quadrupole resonance, and an adjustable key. However, it cannot be used to determine the parameters of the secondary radiation, for example, the frequency of the secondary emitter, the polarization of the vector and the field level.

Known patents 2488100 RU, 2157002 RU, 2205386 RU, 2303290 RU, 2128832 RU, 2527315 RU, 2538318 RU H010Q 23/00, G01N 24/00 from 11/19/2014. The devices contain blocks for determining the frequencies of nuclear quadrupole resonance. However, they cannot be used to determine the parameters of the secondary radiation, for example, the frequency of the secondary emitter, the polarization of the vector and the field level.

The basic object can be “A device for the detection and recognition of substances by nuclear quadrupole resonance (NQR)” patent 2488100 RU G01N 24/00, G01R 33/20 according to application 2010102971 published on 08/10/2011. The device contains a high-frequency generator, a pulse modulator, a first coil inductors, signal sensor, low-noise amplifier, logarithmic amplifier with amplitude detector and indicator, signal divider, first and second controlled attenuators, first and second controlled phase shifters, second inductor, oscilloscope raff. The base object has the following disadvantages:

- low efficiency of emitters of inductance coils (two orders of magnitude lower than an electric emitter);

- a strong dependence of the inductors on the frequency, the inductors relate to tuned emitters operating at the same frequency;

- the use of inductors does not allow to evaluate the polarization properties of secondary radiation in NQR;

- closely spaced frequencies of secondary NQR radiation do not allow their difference and identification of the type of substance;

- lack of automation in determining the parameters of secondary radiation in NQR;

- the inability to determine the parameters of weak secondary emitters.

The aim of the present invention is the automation of the analysis of the frequency properties of the secondary radiation field of the studied objects and their levels; the introduction of the irradiator in the form of a high-voltage source of direct current with superimposed voltage of the high-frequency component; the introduction of broadband receiving antenna systems for receiving the secondary radiation field of the studied objects; introduction of a model for the frequency conversion of the spectrum of secondary radiation to improve recognition and increase the sensitivity of the device by introducing adaptive signal processing of secondary emitters, improving the methodology for studying the polarization properties of the secondary radiation field.

To achieve this goal, a device consisting of a clock pulse generator 1, a radiation spectrum shaper 2, additionally includes: a transmitter-receiver antenna switch 3, a receiving antenna system 4, an adaptive converter 5, a radiation information shaper of the secondary emitters 6, a frequency spectrum converter 7 , filter unit 8, radiation spectrum analysis unit 9, secondary radiation spectrum analysis unit 10, high-voltage irradiated system 11 (11-1 and 11-2), high voltage source 12.

In FIG. 1 shows a device for studying the electromagnetic field of secondary emitters, where 1 is a clock pulse generator, 2 is a radiation spectrum shaper, 3 is an antenna switcher, 4 is a receiving antenna system, 5 is an adaptive converter, 6 is a radiation information shaper of secondary emitters, 7 is a frequency converter spectrum, 8 is a block of ten filters, 9 is a block for analyzing the spectrum of secondary radiation, 10 is a block for studying the spectrum of secondary radiation, 11 is a high-voltage irradiated system (11-1 and 11-2), 12 is a source of high voltage Niya.

In FIG. Figure 2 shows the radiation spectrum shaper 2, where 13 is the first trigger at 0.01 μs, 14 is the I element, 15 is the discrete delay line at 0.01 μs, 18 is the second trigger at 0.02 μs, 16 is the discrete delay line at 0.02 μs, 17 - discrete delay line at 0.01 μs, 21 - third trigger at 0.05 μs, 20 - discrete delay line at 0.05 μs, 19 - discrete delay line at 0.02 μs, 24 - fourth trigger at 0.1 μs, 23 - discrete delay line at 0.1 μs, 22 - discrete delay line at 0.05 μs, 27 - fifth trigger at 1 μs, 26 - discrete delay line at 1 μs, 25 - line discrete delay by 0.1 μs, 28 - voltage amplifier, twenty-eight discrete delay lines 29 for 1 ms, thirty-eight valves from B.1 to B.38, switch Bk.1 to start the first trigger 13; five generators of the shaper of the emission spectrum 2 are started sequentially by the first trigger 13 synchronized through the element And 14 the clock generator 1 (Fig. 1 and 2); the first packet generator of two pulses of 0.01 μs A1 contains: two valves B.1 and B.2 and a discrete delay line 15 by 0.01 μs (Fig. 17); the second generator of a package of two pulses of 0.02 μs A2 contains: two valves B.3 and B.4, a discrete delay line 16 by 0.02 μs, a discrete delay line 17 by 0.01 μs, a second trigger 18 by 0.02 μs; the third packet generator of two pulses of 0.05 μs A3 contains: two valves B.5 and B.6, a discrete delay line 19 at 0.02 μs, a discrete delay line 20 at 0.05 μs, a third trigger 21 at 0.05 μs; the fourth packet generator of two pulses of 0.1 µs A4 each contains: two valves B.7 and B.8, a discrete delay line 22 by 0.05 µs, a discrete delay line 23 by 0.1 µs, a fourth trigger 24 by 0, 1 μs; the fifth packet generator of two pulses 1 μs A5 contains: two valves B.9 and B.10, a discrete delay line 25 by 0.1 μs, a discrete delay line 26 by 1 μs, a fifth trigger 27 by 1 μs; the pulse switch contains twenty-eight gates from B.11 to B.38 and twenty-eight discrete delay lines for 1 ms - 29.

In FIG. 3 shows the antenna switch - 3, where 30 are two switching control units for receiving and transmitting antennas (30-1 and 30-2); 31 - two switches for fourteen inputs (31-1 and 32-2), and two gates B.1 and B.2.

In FIG. 4 shows the switch - 31, where 32 is the transmitting diode-capacitive bridge, 33 is the receiving diode-capacitive bridge, 34 is the element NOT.

In FIG. 5 shows the switching control unit of the transceiver antenna system 30, where Tr.1 - transformer, 1 - fourteen primary windings of the transformer; 2 - secondary winding of the transformer, B.1 - valve, 35 - voltage amplifiers.

In FIG. 6 shows a diode-capacitive bridge - 32 or 33 (the execution diagrams are identical), where R ₁ and R ₂ are high-resistance resistances, B.1 and B.2 are valves, C ₁ and C ₂ are capacitances.

In FIG. 7 shows the receiving antenna system 4, where from 1 to 28 vibrators of different polarization (or vibrators located in a circle, creating a circular polarization of electromagnetic waves), 36 is the load of each vibrator.

In FIG. Figure 8 presents 36 - the load of the vibrators of the receiving antenna system 4, where it is shown that each of the vibrators 1 to 28 has a load at the end in the form of capacitance C and inductance Lk, to increase the electrical length of the antenna.

In FIG. Fig. 9 shows adaptive converter 5, which presents: 37 - generator of the studied frequency range from 1000 Hz to 1 MHz, 38 - current corrector for each of the 28 channels of adaptive converter 5, Vk.1 - type of work switch for two positions for 28 boards (position when the converter is on or off) for each of the 28 channels.

In FIG. 10 shows the current corrector - 38, where 39 is a phase detector, 40 is a phase corrector.

In FIG. 11 shows a shaper of radiation information of secondary emitters 6, where Tr. 1 is a transformer with twenty-eight primary windings 1 (input terminals of windings “ab”) and one secondary winding 2 (terminals “sd”), 41 is an amplifier in each of 28 channels.

In FIG. Figure 12 shows the frequency spectrum converter - 7, where 42 is a 10 kHz generator, 43 is a mixer (converter), a switch Bk.1 for two positions, for switching the converter into the operating mode of research (which is necessary in the high-frequency field of research) and for turning it off .

In FIG. 13 shows a filter block for ten channels - 8, where 44-1 is a filter at frequencies of 1-10 kHz, 44-2 is a filter at frequencies of 10-50 kHz, 44-3 is a filter at frequencies of 50-100 kHz, 44-4 - filter at frequencies of 100-200 kHz, 44-5 - filter at frequencies of 200-400 kHz, 44-6 - filter at frequencies of 400-800 kHz, 44-7 - filter at frequencies of 800-1000 kHz, 44-8 - filter at a frequency of 1-10 MHz, 44-9 - a filter at a frequency of 10-20 MHz, 44-10 - a filter at a frequency of 20-40 MHz, 45-1 - a narrow-band amplifier for a frequency band of 1-10 kHz., 45-2 - narrow-band amplifier in the frequency band of 10-50 kHz, 45-3 - narrow-band amplifier in the frequency band of 50-100 kHz, 45-4 - narrow-band amplifier in the band for frequencies 100-200 kHz, 45-5 - narrow-band amplifier for the frequency band 200-400 kHz, 45-6 - narrow-band amplifier for the frequency band 400-800 kHz, 45-7 - narrow-band amplifier for the frequency band 800-1000 kHz, 45 -8 - narrow-band amplifier in the frequency band 1-10 MHz, 45-9 - narrow-band amplifier in the frequency band 10-20 MHz, 45-10 - narrow-band amplifier in the frequency band 20-40 MHz.

In FIG. 14 block of analyzers of the spectrum of the secondary radiation into ten channels - 9, where 46-1 is the vibrational system in the frequency band 1-10 kHz, 46-2 is the vibrational system in the frequency band 10-50 kHz, 46-3 is the vibrational system in the frequency band 50-100 kHz, 46-4 - vibrational system in the frequency band 100-200 kHz, 46-5 - vibrational system in the frequency band 200-400 kHz, 46-6 - vibrational system in the frequency band 400-800 kHz, 46-7 - an oscillatory system in the frequency band 800-1000 kHz, 46-8 - an oscillatory system in the frequency band 1-10 MHz, 46-9 - an oscillatory system in the frequency band 10-20 MHz, 46-10 - olebatelnaya system bandwidth 20-40 MHz; I.1-1, I.1-2, I.1-3, I.1-4, I.1-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-1; I.2-1, I.2-2, I.2-3, I.2-4, I.2-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-2; I.3-1, I.3-2, I.3-3, I.3-4, I.3-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-3; I.4-1, I.4-2, I.4-3, I.4-4, I.4-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-4; I.5-1, I.5-2, I.5-3, I.5-4, I.5-5 - frequency indicators of the secondary radiation of the oscillatory system 46-5; I.6-1, I.6-2, I.6-3, I.6-4, I.6-5 - frequency indicators of the secondary radiation of the oscillatory system 46-6; I.7-1, I.7-2, I.7-3, I.7-4, I.7-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-7; I.8-1, I.8-2, I.8-3, I.8-4, I.8-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-8; I.9-1, I.9-2, I.9-3, I.9-4, I.9-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-9; I.10-1, I.10-2, I.10-3, I.10-4, I.10-5 - indicators of the frequencies of the secondary radiation of the oscillatory system 46-10.

In FIG. 15 - vibrational system 46 (any of 46-1, 46-2, 46-3, ..., 46-10), where each of ten vibrational systems contains five vibrational bridges: 1, 2, 3, 4 and 5; each bridge contains a high-resistance R and four parallel oscillatory circuits: two with parameters L ₁ and C ₁ and two with parameters L ₂ and C ₂ .

In FIG. 16 is a block for studying the spectrum of secondary radiation 10, where a spectrum analyzer 47 and a switch for ten switching positions Vk.1.

In FIG. 17 - the upper part of the high-voltage irradiating system 11-1, containing N lines of emitters, from the first line - L1 to N line - Ln, each line of emitters contains twenty-eight separation tanks C ₁ , twenty-eight flat radiating metal plates in each line and twenty eight valves B1.

In FIG. 18 shows the lower part of the high-voltage irradiating system 11-2, containing a grounded metal plate "A" connected to the input of the lower part of the high-voltage irradiating system 11-2, the dimensions of the grounded metal plate "A" are not less than the dimensions of the upper part of the high-voltage irradiating system 11-1.

In FIG. 19 is a high voltage source 12 containing six up transformers, with the first to sixth Tr.1 Tr.6, five high-voltage rectifier composed of a high-voltage gate BBB, the inductance L of the filter _F and the filter capacitance C _F, and two switches Vk.1 Bk. 2.

, где два импульса длительностью 0,01 мкс и с разносом на 0,01 мкс или

; второй генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 0,02 мкс каждый с разносом в 0,02 мкс или

; третий генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 0,05 мкс каждый с разносом в 0,05 мкс или

; четвертый генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 0,1 мкс каждый с разносом в 0,1 мкс или

; пятый генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 1 мкс каждый с разносом в 1 мкс или

; таким образом полоса частот создаваемая генераторами находится в пределах от 1 МГц до 100 МГц.In FIG. 20 temporary arrangement in the pulse packet, formed for the irradiation of the studied media; the first generator creates two pulses with an alignment -

where two pulses with a duration of 0.01 μs and a spacing of 0.01 μs or

; the second generator creates two pulses with an alignment -

where

- two pulses with a duration of 0.02 μs each with a spacing of 0.02 μs or

; the third generator creates two pulses with an arrangement -

where

- two pulses with a duration of 0.05 μs each with a spacing of 0.05 μs or

; the fourth generator creates two pulses with an alignment -

where

- two pulses with a duration of 0.1 μs each with a spacing of 0.1 μs or

; the fifth generator creates two pulses with an alignment -

where

- two pulses of 1 μs duration each with a separation of 1 μs or

; thus, the frequency band created by the generators is in the range from 1 MHz to 100 MHz.

In FIG. 21 temporary structure of the voltage distribution created on the emitting plates of the lines: from the first line L1 to N, the line Ln, twenty-eight radiating plates in each line, on each radiating plate the total voltage U is equal to the static electricity voltage U _CTAT and the voltage of the pulse generator U _IMP or U = U _STAT + U _IMP .

In FIG. 22, the temporal distribution of the burst of media pulses along twenty-eight channels, where the time offset in each subsequent channel is a shift of 1 ms compared to the previous channel.

In FIG. 23 shows the placement of irradiating and receiving antenna systems for studying the radiation of electromagnetic fields of secondary emitters, where 4 is a receiving antenna system, 11 is a high-voltage irradiated system (11-1 and 11-2).

A device for studying the electromagnetic field of secondary emitters (Fig. 1) contains a clock pulse generator 1 connected by the output to the input of the shaper of the radiation spectrum 2; twenty eight outputs of the shaper 2 are connected to twenty eight of the inputs of the antenna switch 3, from the first to twenty-eighth; twenty-eight outputs of the antenna switch 3, from the first to the twenty-eighth, connected in parallel with the twenty-eight inputs of the upper part of the high-voltage irradiating system 11-1; twenty eight inputs of the antenna switch 3, from twenty-ninth to fifty-sixth, connected in parallel with twenty-eight outputs of four receiving antenna systems 4; twenty-eight outputs of the antenna switch 3, from twenty-ninth to fifty-sixth, are connected to twenty-eight inputs of the radiation driver of radiation of the secondary emitters 6 through twenty-eight inputs of the adaptive converter 5; the output of the information shaper 6 is connected through the frequency spectrum converter 7, through ten outputs of the filter unit 8 with ten inputs of the secondary radiation spectrum analyzer 9; ten outputs of the analyzer 9 are connected to ten inputs of the unit for studying the spectrum of secondary radiation 10; a high voltage source 12 with a first output connected to the twenty-ninth input of the upper part of the high voltage irradiating system 11-1, and a second output of the high voltage source 12 is connected with the lower part of the high voltage irradiating system 11-2.

The radiation spectrum shaper 2 (Fig. 2) contains: 13 — the first trigger at 0.01 μs, 14 — the I element, 15 — the discrete delay line at 0.01 µs, 18 — the second trigger at 0.02 µs, 16 — the line discrete delay by 0.02 μs, 17 - discrete delay line by 0.01 μs, 21 - third trigger by 0.05 μs, 20 - discrete delay line by 0.05 μs, 19 - discrete delay line by 0.02 μs 24 - the fourth trigger at 0.1 μs, 23 - the line of discrete delay at 0.1 μs, 22 - the line of discrete delay at 0.05 μs, 27 - the fifth trigger at 1 μs, 26 - the line of discrete delay at 1 μs, 25 - discrete delay line n and 0.1 μs, 28 - voltage amplifier, twenty-eight discrete delay lines 29 for 1 ms, thirty-eight valves from B.1 to B.38, switch Bk.1 to start the first trigger 13; five generators of the shaper of the emission spectrum 2 are started sequentially by the first trigger 13 synchronized through the element And 14 the clock generator 1 (Fig. 1 and 2); the first packet generator of two pulses of 0.01 μs A1 contains: two valves B.1 and B.2 and a discrete delay line 15 by 0.01 μs (Fig. 17); the second generator of a package of two pulses of 0.02 μs A2 contains: two valves B.3 and B.4, a discrete delay line 16 by 0.02 μs, a discrete delay line 17 by 0.01 μs, a second trigger 18 by 0.02 μs; the third packet generator of two pulses of 0.05 μs A3 contains: two valves B.5 and B.6, a discrete delay line 19 at 0.02 μs, a discrete delay line 20 at 0.05 μs, a third trigger 21 at 0.05 μs; the fourth packet generator of two pulses of 0.1 µs A4 each contains: two valves B.7 and B.8, a discrete delay line 22 by 0.05 µs, a discrete delay line 23 by 0.1 µs, a fourth trigger 24 by 0, 1 μs; the fifth packet generator of two pulses 1 μs A5 contains: two valves B.9 and B.10, a discrete delay line 25 by 0.1 μs, a discrete delay line 26 by 1 μs, a fifth trigger 27 by 1 μs; the pulse switch contains twenty-eight valves from B.11 to B.38 and twenty-eight discrete delay lines for 1 ms - 29; wherein the first input of the radiation spectrum shaper 2 is connected in parallel with the second input of the And 14 element directly, and with the first input of the And 14 element through Vk.1 and through the first trigger 13 by 0.01 μs; the output of the element And 14 is connected to the input of the first pulse packet generator A1; the input of the first packet generator of two pulses of 0.01 μs A1 is connected to the output in parallel through the first valve B.1 and through the first delay line 15 by 0.01 μs, and also through the second valve B.2, the output of the first generator A1 is connected to the first terminal of the collection line; the input of the second packet generator of two pulses 0.02 μs A2 is connected to the output of the first generator A1, the input of the second generator A2 is connected to the second trigger 18 through the second discrete delay line 17 by 0.02 μs, the output of the second trigger 18 is connected to the output of the second packet generator of two pulses 0.02 μs A2 through the third gate B.3, through the third discrete delay line 16 to 0.02 μs and in parallel through the fourth gate B.4, the output of the second packet generator from two pulses of 0.02 μs A2 is connected to the second terminal of the collective line and parallel with the input of the third packet generator of two pulses of 0.05 μs A3; the input of the third packet generator of two pulses of 0.05 μs A3 is connected to the third trigger 21 through the fourth discrete delay line 19 by 0.05 μs, the output of the third trigger 21 is connected to the output of the third packet generator of two pulses of 0.05 μs A3 through the fifth valve B.5, through the fifth discrete delay line 19 at 0.05 μs and in parallel through the sixth gate B.6, the output of the third packet generator from two pulses of 0.05 μs A3 is connected to the third terminal of the collective line and in parallel with the input of the fourth packet generator from two pulses n about 0.1 μs A4; the input of the fourth packet generator of two pulses of 0.1 μs A4 each is connected to the fourth trigger 24 through the sixth discrete delay line 22 by 0.1 μs, the output of the fourth trigger 22 is connected to the output of the fourth packet generator of two pulses of 0.1 μs A4 through the seventh valve B.7, through the seventh discrete delay line 23 by 0.1 μs and in parallel through the eighth valve B.8, the output of the fourth packet generator from two pulses of 0.1 μs A4 is connected to the fourth terminal of the collective line and in parallel with the input of the fifth packet generator of two to 1 microsecond pulses A5; the input of the fifth packet generator of two pulses of 1 μs A5 is connected to the fifth trigger 27 through the eighth discrete delay line 25 by 1 μs, the output of the fifth trigger 27 is connected to the output of the fifth packet generator of two pulses of 1 μs A5 through the ninth valve B.9, through the ninth discrete delay line 26 by 1 μs and in parallel through the tenth gate B.10, the output of the fifth packet generator from two pulses of 1 μs A5 is connected to the fifth terminal of the collective line; the input of the voltage amplifier 28 is connected to a collective line; the output of the amplifier 28 is connected to the first output of the radiation spectrum shaper 2 and in parallel with the input of the pulse commander consisting of twenty-eight gates and twenty-eight delay lines for 1 ms connected in series; the output of amplifier 28 is connected through the tenth discrete delay line 29 by 1 ms and through the eleventh gate B.11 to the second output of the radiation spectrum shaper 2 and in parallel to the input of the eleventh discrete delay line 29 by 1 ms; the output of the eleventh line 29 for 1 ms is connected through the twelfth gate B.12 to the third output of the radiation spectrum shaper 2 and in parallel to the input of the twelfth discrete delay line 29 for 1 ms; the output of the twelfth line 29 for 1 ms is connected through the thirteenth valve B.13 to the fourth output of the radiation spectrum shaper 2 and in parallel to the input of the thirteenth line of discrete delay 29 for 1 ms; the output of the thirteenth line 29 for 1 ms is connected through the fourteenth gate B.14 to the fifth output of the radiation spectrum shaper 2 and in parallel to the input of the fourteenth line of discrete delay 29 for 1 ms; the output of the fourteenth line 29 for 1 ms is connected through the fifteenth gate B.15 to the sixth output of the radiation spectrum shaper 2 and in parallel to the input of the fifteenth discrete delay line 29 for 1 ms; the output of the fifteenth line 29 for 1 ms is connected via the sixteenth gate B.16 to the seventh output of the radiation spectrum shaper 2 and in parallel to the input of the sixteenth discrete delay line 29 for 1 ms; the output of the sixteenth line 29 for 1 ms is connected through the seventeenth valve B.17 to the eighth output of the radiation spectrum shaper 2 and in parallel to the input of the seventeenth discrete delay line 29 for 1 ms; the output of the seventeenth line 29 for 1 ms is connected through the eighteenth gate B.18 to the ninth output of the shaper of the radiation spectrum 2 and in parallel to the input of the eighteenth line of discrete delay 29 for 1 ms; the output of the eighteenth line 29 for 1 ms is connected through the nineteenth gate B.19 to the tenth output of the radiation spectrum shaper 2 and in parallel to the input of the nineteenth line of the discrete delay 29 for 1 ms; the output of the nineteenth line 29 for 1 ms is connected through the twentieth valve B.20 to the eleventh output of the radiation spectrum shaper 2 and in parallel to the input of the twentieth discrete delay line 29 for 1 ms; the output of the twentieth line 29 for 1 ms is connected through the twenty-first valve B.21 to the twelfth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-first discrete delay line 29 for 1 ms; the output of the twenty-first line 29 for 1 ms is connected through the twenty-second gate B.22 to the thirteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-second discrete delay line 29 for 1 ms; the output of the twenty-second line 29 for 1 ms is connected through the twenty-third gate B.23 to the fourteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-third discrete delay line 29 for 1 ms; the output of the twenty-third line 29 for 1 ms is connected through the twenty-fourth gate B.24 to the fifteenth output of the radiation spectrum shaper 2 and in parallel to the input of the twenty-fourth discrete delay line 29 for 1 ms; the output of the twenty-fourth line 29 for 1 ms is connected through the twenty-fifth gate B.25 to the sixteenth output of the radiation spectrum shaper 2 and in parallel to the input of the twenty-fifth discrete delay line 29 for 1 ms; the output of the twenty-fifth line 29 for 1 ms is connected through the twenty-sixth valve B.26 to the seventeenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-sixth line of discrete delay 29 for 1 ms; the output of the twenty-sixth line 29 for 1 ms is connected through the twenty-seventh gate В.27 to the eighteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-seventh line of discrete delay 29 for 1 ms; the output of the twenty-seventh line 29 for 1 ms is connected through the twenty-eighth gate B.28 to the nineteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-eighth line of discrete delay 29 for 1 ms; the output of the twenty-eighth line 29 for 1 ms is connected via the twenty-ninth valve В.29 to the twentieth output of the radiation spectrum shaper 2 and in parallel to the input of the twenty-ninth discrete delay line 29 for 1 ms; the output of the twenty-ninth line 29 for 1 ms is connected through the thirtieth gate B.30 to the twenty-first output of the radiation spectrum shaper 2 and in parallel to the input of the thirtieth discrete delay line 29 for 1 ms; the output of the thirtieth line 29 for 1 ms is connected through the thirty-first gate B.31 to the twenty-second output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-first discrete delay line 29 for 1 ms; the output of the thirty-first line 29 for 1 ms is connected through the thirty-second gate B.32 to the twenty-third output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-second discrete delay line 29 for 1 ms; the output of the thirty-second line 29 for 1 ms is connected through the thirty-third B.33 gate to the twenty-fourth output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-third discrete delay line 29 for 1 ms; the output of the thirty-third line 29 for 1 ms is connected through the thirty-fourth gate B.34 to the twenty-fifth output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-fourth discrete delay line 29 for 1 ms; the output of the thirty-fourth line 29 for 1 ms is connected through the thirty-fifth gate B.35 to the twenty-sixth output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-fifth discrete delay line 29 for 1 ms; the output of the thirty-fifth line 29 for 1 ms is connected through the thirty-sixth valve B.36 to the twenty-seventh output of the shaper of the radiation spectrum 2 and in parallel to the input of the thirty-sixth line of discrete delay 29 for 1 ms; the output of the thirty-sixth line 29 for 1 ms is connected through the thirty-seventh valve B.37 to the twenty-eighth output of the shaper of the radiation spectrum 2 and in parallel to the input of the thirty-seventh line of discrete delay 29 for 1 ms; the output of the thirty-seventh line 29 for 1 ms is connected through the thirty-eighth gate B.38 to the input of the first trigger 13.

The antenna switch 3 (Fig. 3) contains two identical switches for fourteen inputs 31 (31-1 and 31-2), two control units for switching the transceiver antenna system for fourteen inputs 30 (30-1 and 30-2) and two Valve B.1 and B.2; while fourteen inputs of the antenna switch 3, from the first to fourteenth inputs, are connected in parallel with the fourteen inputs of the first switch 31-1 and with the fourteen inputs of the first switching control unit of the transceiver antenna system 30-1; fourteen inputs of the antenna switch 3, from the fifteenth to the twenty-eighth, are connected in parallel with fourteen inputs of the second switch 31-2 and fourteen inputs of the second switching control unit of the transceiver antenna system 30-2; fourteen outputs of the first switch 31-1, from the first to fourteenth, connected to fourteen outputs, from the forty-third to fifty-sixth, antenna switch 3; fourteen outputs of the second switch 31-2 are connected to fourteen outputs, from twenty-ninth to forty-second, antenna switch 3; the output of the first 30-1 and second 30-2 switching control units of the transceiver antenna system is connected to terminal “a” through valves B.1 and B.2, terminal “a” is connected in parallel with the twenty-ninth inputs of the first 31-1 and second 31-2 switches; fourteen outputs of the first switch 31-1, from the fifteenth to twenty-eighth outputs, connected to fourteen outputs, from the first to fourteenth, of the antenna switch 3; fourteen outputs of the second switch 31-2, from the fifteenth to twenty-eighth outputs, connected to fourteen outputs, from the fifteenth to twenty-eighth, of the antenna switch 3; fourteen inputs of the first switch 31-1, from the fifteenth to twenty-eighth, are connected to fourteen inputs, from the twenty-ninth to forty-second, of the antenna switch 3; fourteen inputs of the second switch 31-2, from the fifteenth to twenty-eighth, are connected to fourteen inputs, from the forty-third to fifty-sixth, of the antenna switch 3.

The switch 31 (31-1 or 31-2) (Fig. 4) contains: fourteen receiving diode-capacitive bridges 33 (on the receiving side of the antennas) and fourteen transmitting diode-capacitive bridges 32 (on the transmitting side of the antennas) and an element 34, while fourteen inputs from the first to fourteenth switch 31 are connected in parallel with the first inputs of fourteen transmitting diode-capacitive bridges 32, and the second inputs of fourteen transmitting diode-capacitive bridges 32 are connected in parallel to the output of the element 34; the outputs of fourteen transmitting diode-capacitive bridges 32 are connected to fourteen outputs, from the fifteenth to the twenty-eighth, of the switch 31; the first inputs of the fourteen receiving diode-capacitive bridges 33 are connected in parallel with the twenty-ninth input of the switch 31; the second inputs of fourteen receiving diode-capacitive bridges 33 are connected in parallel with fourteen inputs, starting from the fifteenth to twenty-eighth inputs, of the switch 31; for example, the first transmitting channel is formed by a connection - the first input of the switch 31 is connected to the first input of the first transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the HE 34 element, and the input of the HE 34 element is connected to the twenty-ninth input of the switch 31 , the output of this first bridge 32 is connected to the fifteenth output of the switch 31; the first channel of the first receiving diode-capacitive bridge 33 is formed by a connection - the fifteenth input of the switch 31 is connected to the second input of the second input of the receiving bridge 33, and the first input of the receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the first receiving bridge is connected to the first the output of the switch 31; the second transmitting channel is formed by a connection - the second input of the switch 31 is connected to the first input of the second transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the HE 34 element, and the input of the HE 34 element is connected to the twenty-ninth input of the switch 31, the output the second transmitting diode-capacitive bridge 32 is connected to the sixteenth output of the switch 31; the second receiving channel is formed by a connection - the sixteenth input of the switch 31 is connected to the second input of the second receiving bridge 33, and the first input of the second receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the second receiving bridge 33 is connected to the second output of the switch 31; the third transmitting channel is formed by a connection - the third input of the switch 31 is connected to the first input of the third transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the HE 34 element, and the input of the HE 34 element is connected to the twenty-ninth input of the switch 31, the output the third transmitting diode-capacitive bridge 32 is connected to the seventeenth output of the switch 31; the third receiving channel is formed by a connection - the seventeenth input of the switch 31 is connected to the second input of the third receiving bridge 33, and the first input of the third receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the third receiving bridge 33 is connected to the third output of the switch 31; the fourth transmitting channel is formed by a connection - the fourth input of the switch 31 is connected to the first input of the fourth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the fourth transmitting diode-capacitive bridge 32 is connected to the eighteenth output of the switch 31 ; the fourth receiving channel is formed by a connection - the eighteenth input of the switch 31 is connected to the second input of the fourth receiving bridge 33, and the first input of the fourth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the fourth receiving bridge 33 is connected to the fourth output of the switch 31; the fifth transmitting channel is formed by a connection - the fifth input of the switch 31 is connected to the first input of the fifth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the fifth transmitting diode-capacitive bridge 32 is connected to the nineteenth output of the switch 31 ; the fifth receiving channel is formed by a connection - the nineteenth input of the switch 31 is connected to the second input of the fifth receiving bridge 33, and the first input of the fifth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the fifth receiving bridge 33 is connected to the fifth output of the switch 31; the sixth transmitting channel is formed by the connection — the sixth input of the switch 31 is connected to the first input of the sixth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the sixth transmitting diode-capacitive bridge 32 is connected to the twentieth output of the switch 31 ; the sixth receiving channel is formed by a connection - the twentieth input of the switch 31 is connected to the second input of the sixth receiving bridge 33, and the first input of the sixth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the sixth receiving bridge 33 is connected to the sixth output of the switch 31; the seventh transmitting channel is formed by the connection - the seventh input of the switch 31 is connected to the first input of the seventh transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the seventh transmitting diode-capacitive bridge 32 is connected to the twenty-first output of the switch 31; the seventh receiving channel is formed by a connection - the twenty-first input of the switch 31 is connected to the second input of the seventh receiving bridge 33, and the first input of the seventh receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the seventh receiving bridge 33 is connected to the seventh output of the switch 31; the eighth transmitting channel is formed by the connection - the eighth input of the switch 31 is connected to the first input of the eighth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the eighth transmitting diode-capacitive bridge 32 is connected to the twenty second output of the switch 31; the eighth receiving channel is formed by a connection - the twenty second input of the switch 31 is connected to the second input of the eighth receiving bridge 33, and the first input of the eighth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the eighth receiving bridge 33 is connected to the eighth output of the switch 31; the ninth transmitting channel is formed by a connection - the ninth input of the switch 31 is connected to the first input of the ninth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the ninth transmitting diode-capacitive bridge 32 is connected to the twenty-third output of the switch 31; the ninth receiving channel is formed by a connection - the twenty-third input of the switch 31 is connected to the second input of the ninth receiving bridge 33, and the first input of the ninth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the ninth receiving bridge 33 is connected to the ninth output of the switch 31; the tenth transmitting channel is formed by a connection - the tenth input of the switch 31 is connected to the first input of the tenth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the tenth transmitting diode-capacitive bridge 32 is connected to the twenty-fourth output of the switch 31; the tenth receiving channel is formed by a connection - the twenty-fourth input of the switch 31 is connected to the second input of the tenth receiving bridge 33, and the first input of the tenth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the tenth receiving bridge 33 is connected to the tenth output of the switch 31; the eleventh transmitting channel is formed by the connection - the eleventh input of the switch 31 is connected to the first input of the eleventh transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the eleventh transmitting diode-capacitive bridge 32 is connected to the twenty-fifth output of the switch 31; the eleventh receiving channel is formed by a connection - the twenty-fifth input of the switch 31 is connected to the second input of the eleventh receiving bridge 33, and the first input of the eleventh receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the eleventh receiving bridge 33 is connected to the eleventh output of the switch 31; the twelfth transmitting channel is formed by the connection - the twelfth input of the switch 31 is connected to the first input of the twelfth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the twelfth transmitting diode-capacitive bridge 32 is connected to the twenty-sixth output of the switch 31; the twelfth receiving channel is formed by a connection — the twenty-sixth input of the switch 31 is connected to the second input of the twelfth receiving bridge 33, and the first input of the twelfth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the twelfth receiving bridge 33 is connected to the twelfth output of the switch 31; the thirteenth transmitting channel is formed by a connection - the thirteenth input of the switch 31 is connected to the first input of the thirteenth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the thirteenth transmitting diode-capacitive bridge 32 is connected to the twenty-seventh output of the switch 31; the thirteenth receiving channel is formed by a connection - the twenty-seventh input of the switch 31 is connected to the second input of the thirteenth receiving bridge 33, and the first input of the thirteenth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the thirteenth receiving bridge 33 is connected to the thirteenth output of the switch 31; the fourteenth transmitting channel is formed by a connection — the fourteenth input of the switch 31 is connected to the first input of the fourteenth transmitting diode-capacitive bridge 32, and the second input of this transmitting bridge 32 is connected to the output of the element 34, the output of the fourteenth transmitting diode-capacitive bridge 32 is connected to the twenty-eighth output of the switch 31; the fourteenth receiving channel is formed by a connection - the twenty-eighth input of the switch 31 is connected to the second input of the fourteenth receiving bridge 33, and the first input of the fourteenth receiving diode-capacitive bridge 33 is connected to the twenty-ninth input of the switch 31, the output of the fourteenth receiving bridge 33 is connected to the fourteenth output of the switch 31; the switching control unit of the transceiver antenna system 30 (30-1 and 30-2) (Fig. 5) comprises a transformer Tr-1 with fourteen primary 1 and one secondary winding 2, a voltage amplifier 34, valve B.1; while fourteen inputs of the switching control unit of the transceiver antenna system 30 are connected in parallel with terminal “a” of the fourteen primary windings 1 of the transformer Tr.1, and terminal “b” of the fourteen primary windings 1 of the transformer Tr.1 is grounded; the secondary windings with terminal “0” are grounded, and terminal “c” is connected to the output of the switching control unit 30 through valve B.1 and a voltage amplifier 35.

The diode-capacitive bridge is made the same for both the transmitting bridge 32 and the receiving bridge 33 (Fig. 6), where R ₁ and R ₂ are the active resistances of equal magnitude and high resistance at least one hundred megohms, B.1 and B.2 - valves, C ₁ and C ₂ - capacitance, while the first input of the diode-capacitive bridge is connected in parallel to the diagonal of the bridge, to points "a" and "b", so the first bridge input is connected through the first active resistance R ₁ to the point "a ", And through the second resistance R ₂ to the point" b "; the second input of the diode-capacitive bridge is connected to point “d”, point “d” is connected to point “c” in parallel in two circuits: the first through the second capacitance C ₂ and the first valve B.1, and the second through the second valve B. 2 and a first container C ₁ ; point "c" is connected to the output of the diode-capacitive bridge.

The receiving antenna system 4 contains twenty-eight receiving antennas (vibrators) (Fig. 7 and Fig. 8), on the one hand, each of the twenty-eight vibrators is connected to one of the twenty-eight inputs of the receiving antenna system 4, and on the other hand, each of twenty-eight antennas connected to a grounded load capacity With 36, providing an increase in the electric length of the vibrator (Fig. 8).

Adaptive converter - 5 (Fig. 9), containing a switch Vk.1 for twenty-eight boards, each board for two switching positions with a common control unit - “Vk-off.” 37 — generator of the range of frequencies under study, 38 — current corrector own to each of the 28 channels of the adaptive transducer 5, while twenty eight inputs of the adaptive transducer 5 are connected to the zero terminal on the twenty-eight circuit boards of the switch Vk.1, own card in each of the 28 channels, in the Vk.1 position in the "Vk." zero terminal in each channel, on each and twenty eight boards, connected to the first terminal, while the input of each of the 28 channels of the adaptive converter 5 is connected to its output of the converter 5 in each of the 28 channels through the zero terminal, the first terminal, through the first input of the current corrector 38 in each of the 28 channels of the adaptive converter 5; when the switch Vk.1 is turned on to the “Off” position, each input 28 of the channels of the adaptive transducer 5 is connected to its output of the adaptive transducer 5 through the terminal zero and terminal two; the output of the generator of the studied frequency range 37 is connected in parallel with the second inputs of the current corrector 38 in each of the 28 channels of the adaptive converter 5.

The current corrector 38 of each of the 28 channels (Fig. 10) contains a phase detector 39 and a phase corrector 40, while the first input of the current corrector - 38 is connected in parallel with the second inputs of the phase detector 39 and the phase corrector 40, and the second input of the current corrector 38 is connected through the first input of the phase detector 39, the output of the detector 39 is connected through the first input to the phase corrector 40 with the output of the current corrector 38.

The shaper of radiation information of the secondary emitters - 6 (Fig. 11), containing Tr. 1 - a transformer with twenty-eight primary windings - 1 and one secondary winding - 2, a broadband amplifier 41, while twenty eight inputs of the shaper of radiation information of the secondary emitters 6 form twenty eight parallel independent channels, in each of the twenty-eight channels the input of the secondary radiation emitter information generator 6 is connected via a broadband amplifier 41 to the terminal “a” of the primary winding of the transformer pa Tr.1 and terminal "b" in each of the twenty-eight Tr.1 primary windings of the transformer is grounded; the output of the radiation information generator of the secondary emitters 6 is connected to the terminal “c” of the secondary winding of the transformer Tr.1, and the terminal “d” of the secondary winding of the transformer Tr.1 is grounded.

The frequency spectrum converter 7 (FIG. 12), comprising a 10 kHz generator 42, a mixer 43, and a switch Bk. 1 for two switching positions, wherein the input of the frequency spectrum converter 7 is connected to the output of the frequency spectrum converter 7 through a first position of the switch Bk.1 and through the first input of the mixer 43, and the second input of the mixer 43 is connected to the output of the generator 42; in addition, the input of the frequency spectrum converter 7 is connected to the output of the frequency spectrum converter 7 through the second position of the switch Bk.1, in the case of disconnecting the converter 7 from the analysis of the frequency spectrum of the secondary radiation field.

A block of filters for ten channels 8 (Fig. 13), containing ten filters from 44-1 to 44-10 and ten narrow-band amplifiers from 45-1 to 45-10, while the input of the block of filters for ten channels 8 is connected to its ten outputs in parallel through the inputs of ten filters and through the inputs of ten narrow-band filters; for example, the input of the filter unit 8 through the input of the first filter 44-1 with a passband from 1 kHz to 10 kHz and through a narrowband amplifier 45-1 with a gain band from 1 kHz to 10 kHz is connected to the first output of the filter unit 8; the input of the filter unit 8 through the input of the second filter 44-2 with a passband from 10 kHz to 50 kHz is connected to the second output of the filter unit 8 through a narrow-band amplifier 45-2 with a gain band from 10 to 50 kHz; the input of the filter unit 8 through the input of the third filter 44-3 with a passband from 50 kHz to 100 kHz is connected to the third output of the filter unit 8 through a narrow-band amplifier 45-3 with a gain band from 50 kHz to 100 kHz; the input of the filter unit 8 through the input of the fourth filter 44-4 with a passband from 100 kHz to 200 kHz is connected to the fourth output of the filter unit 8 through a narrow-band amplifier 45-4 with a gain band from 100 kHz to 200 kHz; the input of the filter unit 8 through the input of the fifth filter 44-5 with a passband from 200 kHz to 400 kHz is connected to the fifth output of the filter unit 8 through a narrow-band amplifier 45-5 with a gain band from 200 kHz to 400 kHz; the input of the filter unit 8 through the input of the sixth filter 44-6 with a passband from 400 kHz to 800 kHz is connected to the sixth output of the filter unit 8 through a narrow-band amplifier 45-6 with a gain band from 400 kHz to 800 kHz; the input of the filter unit 8 through the input of the seventh filter 44-7 with a passband from 800 kHz to 1000 kHz is connected to the seventh output of the filter unit 8 through a narrow-band amplifier 45-7 with a gain band from 800 kHz to 1000 kHz; the input of the filter unit 8 through the input of the eighth filter 44-8 with a passband from 1.0 to 10 MHz is connected to the eighth output of the filter unit 8 through a narrow-band amplifier 45-8 with a gain band from 1.0 to 10 MHz; the input of the filter unit 8 through the input of the ninth filter 44-9 with a passband from 10 to 20 MHz is connected to the ninth output of the filter unit 8 through a narrow-band amplifier 45-9 with a gain band from 10 to 20 MHz; the input of the filter unit 8 through the input of the tenth filter 44-10 with a passband from 20 to 40 MHz is connected to the tenth output of the filter unit 8 through a narrow-band amplifier 45-10 with a gain band from 20 to 40 MHz.

The spectrum analyzer of the secondary radiation into ten channels 9 (Fig. 14), containing ten oscillatory systems from 46-1 to 46-10, and ten groups of five indicators in each group, or fifty indicators (LEDs) from I.1-1 to I.10-5, five indicators for each oscillatory system; the first input of the analyzer 9 is connected to the input of the first oscillatory system 46-1 at a frequency of 1-10 kHz, the first output of the first oscillatory system 46-1 is connected to the first inputs of the first group of five indicators I.1-1 through I.1- 5, and the second output of the first oscillating system 46-1 is connected to the second inputs of the first group of five indicators I.1-1 to I.1-5, the third output of the first oscillating system 46-1 is connected to the first output of the secondary radiation spectrum analyzer 9 ; the second input of the analyzer 9 is connected to the input of the second oscillatory system 46-2 at a frequency of 10-50 kHz, the first output of the second oscillatory system 46-2 is connected to the first inputs of the second group of five indicators I.2-1 to I.2-5, and the second output of the second oscillating system 46-2 is connected to the second inputs of the second group of five indicators I.2-1 to I.2-5, the third output of the second oscillating system 46-2 is connected to the second output of the secondary radiation spectrum analyzer 9; the third input of the analyzer 9 is connected to the input of the third oscillatory system 46-3 at a frequency of 50-100 kHz, the first output of the third oscillatory system 46-3 is connected to the first inputs of the third group of five indicators I.3-1 to I.3-5, and the second output of the third oscillatory system 46-3 is connected to the second inputs of the third group of five indicators I.3-1 to I.3-5, the third output of the third oscillatory system 46-3 is connected to the third output of the secondary radiation spectrum analyzer 9; the fourth input of the analyzer 9 is connected to the input of the fourth oscillatory system 46-4 at a frequency of 100-200 kHz, the first output of the fourth oscillatory system 46-4 is connected to the first inputs of the fourth group of five indicators I.4-1 through I.4-5, and the second output of the fourth oscillatory system 46-4 is connected to the second inputs of the fourth group of five indicators I.4-1 to I.4-5, the third output of the fourth oscillatory system 46-4 is connected to the fourth output of the secondary radiation spectrum analyzer 9; the fifth input of the analyzer 9 is connected to the input of the fifth oscillating system 46-5 at a frequency of 200-400 kHz, the first output of the fifth oscillating system 46-5 is connected to the first inputs of the fifth group of five indicators I.5-1 through I.5-5, and the second output of the fifth oscillatory system 46-5 is connected to the second inputs of the fifth group of five indicators I.5-1 to I.5-5, the third output of the fifth oscillatory system 46-5 is connected to the fifth output of the secondary radiation spectrum analyzer 9; the sixth input of the analyzer 9 is connected to the input of the sixth oscillation system 46-6 at a frequency of 400-800 kHz, the first output of the sixth oscillation system 46-6 is connected to the first inputs of the sixth group of five indicators I.6-1 to I.6-5, and the second output of the sixth vibrational system 46-6 is connected to the second inputs of the sixth group of five indicators I.6-1 to I.6-5, the third output of the sixth vibrational system 46-6 is connected to the sixth output of the secondary radiation spectrum analyzer 9; the seventh input of the analyzer 9 is connected to the input of the seventh oscillatory system 46-7 at frequencies of 800-1000 kHz, the first output of the seventh oscillatory system 46-7 is connected to the first inputs of the seventh group of five indicators I.7-1 to I.7-5, and the second output of the seventh oscillatory system 46-7 is connected to the second inputs of the seventh group of five indicators I.7-1 to I.7-5, the third output of the seventh oscillatory system 46-7 is connected to the seventh output of the secondary radiation spectrum analyzer 9; the eighth input of the analyzer 9 is connected to the input of the eighth oscillatory system 46-8 at a frequency of 1-10 MHz, the first output of the eighth oscillatory system 46-8 is connected to the first inputs of the eighth group of five indicators I.8-1 to I.8-5, and the second output of the eighth oscillatory system 46-8 is connected to the second inputs of the eighth group of five indicators I.8-1 to I.8-5, the third output of the eighth oscillatory system 46-8 is connected to the eighth output of the secondary radiation spectrum analyzer 9; the ninth input of the analyzer 9 is connected to the input of the ninth oscillatory system 46-9 at a frequency of 10-20 MHz, the first output of the ninth oscillatory system 46-9 is connected to the first inputs of the ninth group of five indicators I.9-1 through I.9-5, and the second output of the ninth vibrational system 46-9 is connected to the second inputs of the ninth group of five indicators I.9-1 to I.9-5, the third output of the ninth vibrational system 46-9 is connected to the ninth output of the secondary radiation spectrum analyzer 9; the tenth input of the analyzer 9 is connected to the input of the tenth oscillatory system 46-10 at a frequency of 20-40 MHz, the first output of the tenth oscillatory system 46-10 is connected to the first inputs of the tenth group of five indicators I.10-1 through I.10-5, and the second output of the tenth oscillatory system 46-10 is connected to the second inputs of the tenth group of five indicators I.10-1 to I.10-5, the third output of the tenth oscillatory system 46-10 is connected to the tenth output of the secondary radiation spectrum analyzer 9.

The oscillation system 46 (any of 46-1, 46-2, 46-3, ..., 46-10) (Fig. 15) contains five oscillatory bridges: 1, 2, 3, 4 and 5; each bridge contains a high-resistance resistance R and four parallel oscillatory circuits: two with parameters L ₁ and C ₁ and two with parameters L ₂ and C ₂ , while the input of the oscillating system 46 is connected in parallel with the five inputs of five bridges and with the third output of the oscillating system 46 , the first exits of the five bridges (1, 2, 3, 4, and 5) form the first exit, the second exits of the five bridges (1, 2, 3, 4, and 5) form the second exit; the input of each bridge is connected through terminal “c” through the second parallel oscillating circuit L ₂ and C ₂ , through terminal “a” with the first output of the bridge, and in parallel the point “c” is connected through the first parallel oscillating circuit L ₁ and C ₁ , through the terminal "B" with the second exit of the bridge; terminal “a” is connected via a high-resistance resistance R to terminal “b” and in parallel terminal “a” is connected through a first oscillating circuit L ₁ and C ₁ to terminal “d”, terminal “b” is connected through a parallel second oscillating circuit L ₂ and C ₂ connected to terminal “d”, terminal “d” is grounded; the first oscillation system 46-1 contains five bridges: the first bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 1.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 2.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 3.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 4.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 5.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 6.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 7.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 8.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 9.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 9.9 kHz. The second oscillatory system 46-2 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 11.9 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 15.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 20.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 25.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 30.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 35.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 40.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 44.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 47.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 49.9 kHz. The third oscillation system 46-3 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 52.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 58.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 62.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 68.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 72.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 78.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 82.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 88.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 92.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 98.1 kHz. The fourth oscillation system 46-4 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 110.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 120.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 130.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 140.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 150.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 160.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 170.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 178.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 185.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 198.1 kHz. The fifth oscillation system 46-5 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 210.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 230.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 250.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 270.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 290.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 310.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 330.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 350.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 370.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 390.1 kHz. The sixth oscillation system 46-6 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 410.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 450.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 490.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 530.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 570.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 610.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 650.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 690.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 730.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 790.1 kHz. The seventh oscillation system 46-7 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 810.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 830.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 850.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 870.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 890.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 910.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 930.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 950.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 970.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 990.1 kHz. The eighth oscillation system 46-8 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 1100.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 1900.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 2900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 3900.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 4900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 5900.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 6900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 7900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 8900.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 9900.1 kHz. The ninth oscillation system 46-9 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 10100.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 10900.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 12900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 13900.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 14900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 15900.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 16,900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 17,900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 18900.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 19900.1 kHz. The tenth oscillation system 46-10 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 21100.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 23100.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 25100.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 27900.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 30,100.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 32,900.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 35100.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 37900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 38,900.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 39900.1 kHz.

The unit for studying the spectrum of the secondary radiation 10 (Fig. 16) contains a frequency spectrum analyzer 47 and a switch Bk.1 for ten switching positions, while the ten inputs of the unit for studying the spectrum of the secondary radiation 10 are connected in parallel to ten terminals “a” of the switch Bk.1, and ten terminals “b” Vk.1 are connected in parallel to the input of the frequency spectrum analyzer 47.

The upper part of the high-voltage irradiating system 11-1 (Fig. 17), containing N lines of emitters, from the first line - L1 to N line - Ln, each line of emitters contains twenty-eight separation tanks C ₁ , twenty-eight flat radiating metal plates in each line and twenty-eight valves B1, while the first input of the upper high-voltage irradiator 11-1 is connected in parallel with the first inputs of each of the N lines, from the first line - L1 to N line - Ln; the second input of the upper high-voltage irradiator 11-1 is connected in parallel with the second inputs of each of the N lines, from the first line - L1 to N line - Ln; the third input of the upper high-voltage feed 11-1 is connected in parallel with the third inputs of each of the N lines, from the first line - L1 to N line - Ln; the fourth input of the upper high-voltage feed 11-1 is connected in parallel with the fourth inputs of each of the N lines, from the first line - L1 to N line - Ln; the fifth input of the upper high-voltage irradiator 11-1 is connected in parallel with the fifth inputs of each of the N lines, from the first line - L1 to N line - Ln; the sixth input of the upper high-voltage irradiator 11-1 is connected in parallel with the sixth inputs of each of the N lines, from the first line - L1 to N line - Ln; the seventh input of the upper high-voltage irradiator 11-1 is connected in parallel with the seventh inputs of each of the N lines, from the first line - L1 to N line - Ln; the eighth input of the upper high-voltage irradiator 11-1 is connected in parallel with the eighth inputs of each of the N lines, from the first line - L1 to N line - Ln; the ninth input of the upper high-voltage feed 11-1 is connected in parallel with the ninth inputs of each of the N lines, from the first line - L1 to N line - Ln; the tenth input of the upper high-voltage irradiator 11-1 is connected in parallel with the tenth inputs of each of the N lines, from the first line - L1 to N line - Ln; the twenty-ninth input of the upper high-voltage feed 11-1 is connected in parallel with the twenty-ninth inputs from the first line - L1 to N line - Ln; the first line of emitters L1 consists of twenty eight flat emitting metal plates, from the first plate 1-1 to the eighth of 1-28, twenty-eight valves B1 and twenty-eight isolation tanks C ₁ , with each of the twenty-eight inputs, from the first 1 to the twenty-eighth 28 inputs, of the first L1 line are connected in parallel with the twenty-eight outputs of the first line of L1 emitters, and through terminal “b” each of the twenty-eight inputs is connected to its own flat radiating metal plate, from the first 1-1 to twenty muyu 1-28, through the capacitance C _1, Twenty-ninth input line connected to the emitters of the first parallel terminal "a" through valve V1 self planar radiating metal plate 1-1 to the first through twenty-eighth 1-28; the second and subsequent lines of emitters, from the second line L2 to line N, are structurally executed like the first line of emitters L1.

The lower part of the high-voltage irradiating system 11-2 (Fig. 18), containing a grounded metal plate "A" connected to the input of the lower part of the high-voltage irradiating system 11-2, the dimensions of the grounded metal plate "A" are not less than the dimensions of the upper part of the high-voltage irradiating system 11- one.

A high voltage source 12 (Fig. 19), containing six step-up transformers, from the first Tr.1 to the sixth Tr.6, five high-voltage rectifiers consisting of a high-voltage BBB valve, filter inductance L _Ф and filter capacitance C _Ф , two switches Vk.1 and Vk.2, while the primary winding 1 of the first transformer Tr. 1 is connected to a 220-volt supply source, and the secondary winding 11 of the first transformer Tr. 1 is grounded with terminal “d” and connected to terminal “c” in parallel with five terminals “b” »The second switch Vk.2; terminal “a” of the first position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the second step-up transformer Tr.2, through terminal “d” the primary sheath 1 of the second step-up transformer Tr.2 is grounded, the secondary winding 11 of the second step-up transformer Tr.2 terminal "c" is connected to the terminal "b" of the first position of the first switch BK.1 through a high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal "d" of the secondary winding 11 of the second step-up transformer Tr.2 ; terminal “a” of the second position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the third step-up transformer Tr.3, through terminal “d” the primary sheath 1 of the third step-up transformer Tr.3 is grounded, the secondary winding 11 of the third step-up transformer Tr.3 terminal “c” is connected to terminal “b” of the second position of the first switch Vk.1 through the high-voltage valve BBB, through the filter inductance L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the third step-up transformer Tr.3 ; terminal “a” of the third position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the fourth step-up transformer Tr.4, through terminal “d” the primary sheath 1 of the fourth step-up transformer Tr.4 is grounded, the secondary winding 11 of the fourth step-up transformer Tr.4 terminal "c" is connected to a terminal "b" of the third position of the first switch valve via a high Vk.1 BBB through the filter inductance L _P and c _P filter capacitance terminal "d" of the secondary winding 11 of the fourth up transformer Tr.4 grounded; terminal “a” of the fourth position of the second switch Bk.2 is connected through terminal “c” to the primary winding of the fifth step-up transformer Tr.5, through terminal “e” the primary shell 1 of the fifth step-up transformer Tr.5 is grounded, the secondary winding 11 of the fifth step-up transformer Tr.5 terminal “c” is connected to terminal “b” of the fourth position of the first switch Vk.1 through a high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the fifth step-up transformer Tr.5 ; terminal “a” of the fifth position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the sixth step-up transformer Tr.6, through terminal “d” the primary sheath 1 of the sixth step-up transformer Tr.6 is grounded, the secondary winding 11 of the sixth step-up transformer Tr.6 terminal “c” is connected to terminal “b” of the fifth position of the first switch Vk.1 through the high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the sixth step-up transformer Tr.5 ; the terminals "a" of the first switch BK.1 are connected in parallel with the first output of the high voltage source 12; the second output of the high voltage source 12 is connected to the earth wire of the high voltage source 12.

, где два импульса длительностью 0,01 мкс и с разносом на 0,01 мкс или

; второй генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 0,02 мкс каждый с разносом в 0,02 мкс или

; третий генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 0,05 мкс каждый с разносом в 0,05 мкс или

; четвертый генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 0,1 мкс каждый с разносом в 0,1 мкс или

; пятый генератор создает два импульса с расстановкой -

, где

- два импульса длительностью по 1 мкс каждый с разносом в 1 мкс или

; таким образом полоса частот создаваемая генераторами находится в пределах от 1 МГц до 100 МГц.Temporary arrangement (Fig. 20) in the pulse packet, formed for the irradiation of the studied media; the first generator creates two pulses with an alignment -

where two pulses with a duration of 0.01 μs and a spacing of 0.01 μs or

; the second generator creates two pulses with an alignment -

where

- two pulses with a duration of 0.02 μs each with a spacing of 0.02 μs or

; the third generator creates two pulses with an arrangement -

where

- two pulses with a duration of 0.05 μs each with a spacing of 0.05 μs or

; the fourth generator creates two pulses with an alignment -

where

- two pulses with a duration of 0.1 μs each with a spacing of 0.1 μs or

; the fifth generator creates two pulses with an alignment -

where

- two pulses of 1 μs duration each with a separation of 1 μs or

; thus, the frequency band created by the generators is in the range from 1 MHz to 100 MHz.

The temporary structure (Fig. 21) of the voltage distribution excited on the emitting plates of the rulers: from the first ruler - L1 to N line - Ln, twenty-eight radiating plates in each ruler, on each radiating plate the total voltage U is equal to the static voltage U _STAT and voltage of the pulse generator U _IMP or U = U _STAT + U _IMP .

The temporal distribution of the pulse packet (Fig. 22) of medium exposure along twenty-eight channels, where the time offset in each subsequent channel is a shift of 1 ms compared to the previous channel.

The placement of the irradiating and receiving antenna systems (Fig. 23) for studying the radiation of electromagnetic fields of secondary emitters, where 4 is the receiving antenna system, 11 is the high-voltage irradiated system (the upper part is 11-1 and the lower part is 11-2).

The principle of operation of the device.

Based on the block diagram of FIG. 1, the control device of the electromagnetic field of the secondary emitters works as follows: a clock pulse generator (GTI) at the output excites a sequence of pulses with a duration of 0.01 μs, these pulses are fed to the input of the radiation spectrum shaper 2, and only one pulse arrives into the shaper 2, which synchronizes five generators (A1, A2, A3, A4 and A5) in the shaper 2 (Fig. 2). The generators A1, A2, A3, A4 and A5, each output two pulses of different durations (Fig. 15), thus forming a burst of pulses. This packet by the pulse switch in the shaper 2 distributes twenty-eight channels at the output of the shaper. Packets using the antenna switch 3 are supplied to the twenty-eight outputs of the switch 3, from the first to the twenty-eighth output, and provide the imposition of high-frequency currents on the irradiating plates in the irradiator 11-1, which are under high voltage from 10 kV to 50 kV. At the same time, the switch 3 connects four receiving antenna systems 4 (Fig. 23). Each of the four antenna systems 4 can be placed arbitrarily depending on the size and shape of the investigated object. The excited electromagnetic field by the antenna systems 11 (11-1 and 11-2) brings the media under investigation into an excited state: electrical boards, electrical circuits, block designs, dielectric and weakly conductive materials, etc. These studied media can emit a secondary field, and its level depends on the block or design features, on the material and the advantages and disadvantages. The radiated secondary electromagnetic field is fixed by the antenna system 4 and in the form of induced emf enters through twenty eight lines to twenty eight inputs of the antenna switch 3 and through switch 3 to its twenty eight outputs from the twenty-ninth to fifty-sixth. This EMF, arriving at the twenty-eight inputs of the secondary radiation emitter 5, is added to the frequency spectrum converter 6, where the secondary radiation frequencies are separated by multiplying the emitted secondary field frequencies by 10 kHz. At the output of the converter 6, a filter unit 7 is installed, which ensures the separation of the secondary radiation frequencies and their arrival through ten channels to the secondary radiation spectrum analyzer into ten channels 8, followed by their indication in the frequency band using LEDs, and the frequency research in the secondary radiation spectrum research unit 9. Consider in detail the work of all blocks.

The clock pulse generator 1 (GTI) excites at the output a continuous sequence of pulses with a duration of τ _GTI = 0.01 μs, which are fed to the first input of the radiation spectrum shaper 2 (Fig. 1) and through it to the second input of the And 14 element (Fig. 2 ) From this sequence of pulses of the GTI 1, only one pulse passes through the And 14 element, which is synchronized in time with the pulse of the first trigger 13 along the first input of the And 14. The trigger 13 is triggered by the first switch Vk.1, when you press the "Start" button, the terminals " a ”and“ b ”and the GTI pulse 1 is fed to the input of trigger 13. Moreover, the start is made once by the“ Start ”element, subsequent launches of the trigger 13 are carried out by pulses arriving at the output of gate B.38 of the pulse distributor via twenty eight channels and consisting of twenty-eight gates B.11 through B.38 connected in series and twenty-eight discrete delay lines 29 for 1 ms each. Trigger 13 works with a delay to restore to its initial state of 0.01 ms, therefore, it starts only from the first pulse of ten incoming (Fig. 20). A GTI pulse synchronized by trigger 13 with a duration of 0.01 μs enters the output of element And 14 and enters the input of the first generator of two pulses A1, while the GTI pulse enters the output of the first generator in two circuits: the first directly through the second valve B.2, and the second - through the first gate B.1 and the first discrete delay line 15 by 0.01 μs. At the output of the first generator A1, the first two pulses appear (Fig. 20) with a duration of 0.01 μs each and spaced in time by 0.01 μs. These pulses are fed in parallel to the collecting line to the first “1” point and to the input of the second A2 generator, where the pulses are fed through the second discrete delay line 17 by 0.01 μs to the input of the second trigger 18. The trigger 18, which is in standby mode, is started and trigger output 18 creates a pulse with a duration of 0.02 μs. Trigger 18 works with a delay to restore to its original state after 1 ms, therefore it is launched only from the first pulse, of the two incoming, to the input of the A2 generator. In this case, the pulse of the second trigger 18 is supplied to the output of the second generator A2 through two circuits: the first directly through the fourth gate B.4, and the second through the third gate B.3 and the third discrete delay line 16 by 0.02 μs. At the output of the second generator A2, the second two pulses appear (Fig. 15) with a duration of 0.02 μs each and spaced in time by 0.02 μs. These pulses are fed in parallel to the collector line at point two “2” and to the input of the third generator A3, where the pulses are fed through the fourth line of discrete delay 19 by 0.02 µs to the input of the third trigger 21. The trigger 21, which is in standby mode, starts and trigger output creates a pulse with a duration of 0.05 μs. Trigger 21 works with a delay to restore to its original state after 1 ms, therefore it is launched only from the first pulse, of the two incoming, to the input of generator A3. In this case, the pulse of the third trigger 21 enters the output of the third generator A3 in two circuits: the first directly through the sixth gate B.6, and the second through the fifth gate B.5 and the fifth discrete delay line 20 by 0.05 μs. At the output of the third generator A3, a third pair of pulses (Fig. 20) with a duration of 0.05 μs each and spaced 0.05 μs apart relative to each other in time will appear. These pulses are fed in parallel to the collector line at point three “3” and to the input of the fourth generator A4, where the pulses are fed through the sixth discrete delay line 22 by 0.05 μs to the input of the fourth trigger 24. Trigger 24, which is in standby mode, starts and trigger output creates a pulse with a duration of 0.1 μs. Trigger 24 works with a delay to restore to its original state after 1 ms, therefore it is triggered only by the first pulse, from two of the generator A4 entering the input. The pulse of the fourth trigger 24 is supplied to the output of the fourth generator A4 through two circuits: the first directly through the eighth valve B.8, and the second through the seventh valve B.7 and the seventh discrete delay line 23 by 0.1 μs. At the output of the fourth generator A4, a fourth pair of pulses (Fig. 20) with a duration of 0.1 μs each and separated by 0.1 μs relative to each other in time will appear. These pulses are fed in parallel to the collector line at point four “4” and to the input of the fifth generator A5, where the pulses are fed through the eighth discrete delay line 25 by 0.1 μs to the input of the fifth trigger 27. The trigger 27, which works in standby mode, starts and the output of the trigger 27 creates a pulse with a duration of 1 μs. Trigger 27 works with a delay to restore to its original state after 1 ms, therefore it is launched only from the first pulse, from two incoming to the input of the fifth generator A5. In this case, the pulse of the fifth trigger 27 enters the output of the fifth generator A5 in two circuits: the first directly through the tenth valve B.10, and the second through the ninth valve B.9 and the ninth discrete delay line 26 by 1 μs. At the output of the fifth generator A5, a fifth pair of pulses (Fig. 20) with a duration of 1 μs each and 1 μs apart relative to each other in time will appear. The pulses of the fifth generator A5 arrive at the collective line at point five "5". All five points 1, 2, 3, 4 and 5 of the collective line are connected to the input of the amplifier 28. Therefore, the pulse packets of ten pulses (Fig. 20) are fed to the input of the voltage amplifier 28. At the output of the amplifier 28, the amplified pulses are sent in parallel to the first the output of the radiation spectrum shaper 2 and to the pulse switch, consisting of twenty-eight valves B.11 to B.38 connected in series and twenty-eight discrete delay lines 29 for 1 ms. So the output of the voltage amplifier 28 is connected to the first output of the radiation spectrum shaper 2, and in parallel through the tenth discrete delay line 29 by 1 ms and through the eleventh gate B.11 to the second output of the radiation spectrum shaper 2 and parallel to the input of the eleventh discrete delay 29 by 1 ms; the output of the eleventh line 29 for 1 ms is connected through the twelfth gate B.12 to the third output of the radiation spectrum shaper 2 and in parallel to the input of the twelfth discrete delay line 29 for 1 ms; the output of the twelfth line 29 for 1 ms is connected through the thirteenth valve B.13 to the fourth output of the radiation spectrum shaper 2 and in parallel to the input of the thirteenth line of discrete delay 29 for 1 ms; the output of the thirteenth line 29 for 1 ms is connected through the fourteenth gate B.14 to the fifth output of the radiation spectrum shaper 2 and in parallel to the input of the fourteenth line of discrete delay 29 for 1 ms; the output of the fourteenth line 29 for 1 ms is connected through the fifteenth gate B.15 to the sixth output of the radiation spectrum shaper 2 and in parallel to the input of the fifteenth discrete delay line 29 for 1 ms; the output of the fifteenth line 29 for 1 ms is connected via the sixteenth gate B.16 to the seventh output of the radiation spectrum shaper 2 and in parallel to the input of the sixteenth discrete delay line 29 for 1 ms; the output of the sixteenth line 29 for 1 ms is connected through the seventeenth valve B.17 to the eighth output of the radiation spectrum shaper 2 and in parallel to the input of the seventeenth discrete delay line 29 for 1 ms; the output of the seventeenth line 29 for 1 ms is connected through the eighteenth gate B.18 to the ninth output of the shaper of the radiation spectrum 2 and in parallel to the input of the eighteenth line of discrete delay 29 for 1 ms; the output of the eighteenth line 29 for 1 ms is connected through the nineteenth gate B.19 to the tenth output of the radiation spectrum shaper 2 and in parallel to the input of the nineteenth line of the discrete delay 29 for 1 ms; the output of the nineteenth line 29 for 1 ms is connected through the twentieth valve B.20 to the eleventh output of the radiation spectrum shaper 2 and in parallel to the input of the twentieth discrete delay line 29 for 1 ms; the output of the twentieth line 29 for 1 ms is connected through the twenty-first valve B.21 to the twelfth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-first discrete delay line 29 for 1 ms; the output of the twenty-first line 29 for 1 ms is connected through the twenty-second gate B.22 to the thirteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-second discrete delay line 29 for 1 ms; the output of the twenty-second line 29 for 1 ms is connected through the twenty-third gate B.23 to the fourteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-third discrete delay line 29 for 1 ms; the output of the twenty-third line 29 for 1 ms is connected through the twenty-fourth gate B.24 to the fifteenth output of the radiation spectrum shaper 2 and in parallel to the input of the twenty-fourth discrete delay line 29 for 1 ms; the output of the twenty-fourth line 29 for 1 ms is connected through the twenty-fifth gate B.25 to the sixteenth output of the radiation spectrum shaper 2 and in parallel to the input of the twenty-fifth discrete delay line 29 for 1 ms; the output of the twenty-fifth line 29 for 1 ms is connected through the twenty-sixth valve B.26 to the seventeenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-sixth line of discrete delay 29 for 1 ms; the output of the twenty-sixth line 29 for 1 ms is connected through the twenty-seventh gate В.27 to the eighteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-seventh line of discrete delay 29 for 1 ms; the output of the twenty-seventh line 29 for 1 ms is connected through the twenty-eighth gate B.28 to the nineteenth output of the shaper of the radiation spectrum 2 and in parallel to the input of the twenty-eighth line of discrete delay 29 for 1 ms; the output of the twenty-eighth line 29 for 1 ms is connected via the twenty-ninth valve В.29 to the twentieth output of the radiation spectrum shaper 2 and in parallel to the input of the twenty-ninth discrete delay line 29 for 1 ms; the output of the twenty-ninth line 29 for 1 ms is connected through the thirtieth gate B.30 to the twenty-first output of the radiation spectrum shaper 2 and in parallel to the input of the thirtieth discrete delay line 29 for 1 ms; the output of the thirtieth line 29 for 1 ms is connected through the thirty-first gate B.31 to the twenty-second output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-first discrete delay line 29 for 1 ms; the output of the thirty-first line 29 for 1 ms is connected through the thirty-second gate B.32 to the twenty-third output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-second discrete delay line 29 for 1 ms; the output of the thirty-second line 29 for 1 ms is connected through the thirty-third B.33 gate to the twenty-fourth output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-third discrete delay line 29 for 1 ms; the output of the thirty-third line 29 for 1 ms is connected through the thirty-fourth gate B.34 to the twenty-fifth output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-fourth discrete delay line 29 for 1 ms; the output of the thirty-fourth line 29 for 1 ms is connected through the thirty-fifth gate B.35 to the twenty-sixth output of the radiation spectrum shaper 2 and in parallel to the input of the thirty-fifth discrete delay line 29 for 1 ms; the output of the thirty-fifth line 29 for 1 ms is connected through the thirty-sixth valve B.36 to the twenty-seventh output of the shaper of the radiation spectrum 2 and in parallel to the input of the thirty-sixth line of discrete delay 29 for 1 ms; the output of the thirty-sixth line 29 for 1 ms is connected through the thirty-seventh valve B.37 to the twenty-eighth output of the shaper of the radiation spectrum 2 and in parallel to the input of the thirty-seventh line of discrete delay 29 for 1 ms; the output of the thirty-seventh line 29 for 1 ms is connected through the thirty-eighth gate B.38 to the input of the first trigger 13. Thus, the pulse packets generated by the five generators A1, A2, A3, A4 and A5 after amplification arrive with a delay of one millisecond relative to the previous output, twenty-eight outputs of the shaper of the radiation spectrum 2 (Fig. 2 and Fig. 22). And from the output of the switch, the output pulses coming through the thirty-eighth valve B.38 trigger the first trigger 13, which with its pulse at the output ensures the passage of one GTI pulse 1 through the And 14 element to resume the operation of five generators A1, A2, A3, A4 and A5, the latter create bursts of ten pulses (Fig. 20). These ten pulses are amplified by amplifier 28 and then distributed by the switch over the twenty-eight outputs of spectrum shaper 2. Thus, GTI 1 and spectrum shaper 2 will work cycle after cycle.

Twenty-eight outputs of the radiation spectrum shaper 2 (Fig. 3) are connected to twenty-eight inputs of the antenna switch 3. Moreover, twenty-eight inputs in the antenna switch 3 are divided for convenience of description into two groups of fourteen inputs, although all twenty eight can be displayed together. The first group is formed from the first to fourteenth inputs from the inputs of the antenna switch 3 (Fig. 3). The second group is from the fifteenth to the twenty-eighth of the inputs of the antenna switch 3. In this case, five pulse packets arrive at each of the inputs of the antenna switch 3. The first group of fourteen inputs, from the first to the fourteenth, are connected in parallel with fourteen inputs of the first switch 31-1 and fourteen inputs of the first switching control unit 30-1. The second group of fourteen inputs, from the fifteenth to the twenty-eighth, are connected in parallel with the fourteen inputs of the second switch 31-2 and the fourteen inputs of the second switching control unit 30-2. Fourteen inputs of the first switch 31-1, from the fifteenth to twenty-eighth, are connected to fourteen inputs starting from the twenty-ninth to forty-second inputs of the antenna switch 3. Fourteen outputs, from the first to fourteenth, of the first switch 31-1 are connected to fourteen outputs of the antenna switch 3 forty-third through fifty-sixth exits. Fourteen outputs of the first switch 31-1 from the fifteenth to twenty-eighth are connected to fourteen outputs of the switch antenna 3 from the first to fourteenth output. Fourteen inputs of the second switch 31-2, from the fifteenth to twenty-eighth, are connected to fourteen inputs starting from the forty-third to fifty-sixth inputs of the antenna switch 3. Fourteen outputs, from the first to fourteenth, of the second switch 31-2 are connected to fourteen outputs of the antenna switch 3 from the twenty-ninth to the forty-second exits. Fourteen outputs of the second switch 31-2 from the fifteenth to the twenty-eighth are connected to fourteen outputs of the switch antenna 3 from the fifteenth to the twenty-eighth output. The output of the first 30-1 and second 30-2 switching control units of the transceiver antenna system is connected to terminal “a” through valves B.1 and B.2, terminal “a” is connected in parallel with the twenty-ninth inputs of the first 31-1 and second 31-2 switches. The switching units 31-1 and 31-2 provide separation of the transmission channels from the receiving channels, and the blocks 30-1 and 30-2 with voltage at their output provide closing reception for the period of radiation by the emitters.

The switching units 31-1 and 32-2 are identical; therefore, they are considered as one antenna switch 31 shown in FIG. 4. The fourteen inputs of the switching unit 31 receive pulse packets generated in the spectrum shaper 2. These pulses in each channel out of fourteen arrive at the second input of the fourteen transmitting diode-capacitive bridges 32. The transmitting diode-capacitive bridge 32, in each channel, provides a pass pulse packets of the shaper 2, on fourteen outputs of the transmission of the switching unit 31, from the fifteenth to the twenty-eighth. At the same time, the high voltage excited by the pulse packets in the receiving antenna system 4 is supplied to the second inputs of the fourteen receiving diode-capacitive bridges 33, which are currently closed for passing packets to the receiving part, that is, to the output of the switching unit 31 at its outputs from the first on the fourteenth and at the output of the antenna switch 3. The operation of locking and unlocking the bridges 32 and 33 is controlled by the control unit of the transceiver antenna system 30-1 and 30-2 at the twenty-ninth input of the switching unit 31. voltage was bridges 33 and 33 is synchronized pulse packets arriving at the inputs of control units 30-1 and 30-2. Moreover, when pulse packets arrive at the inputs from the first to the fourteenth, they must be transmitted to fourteen outputs, from the fifteenth to the twenty-eighth through the transmitting bridges 32. To do this, pulse packets arrive at the first input of the transmitting bridges 32, and the blocking voltage at the second input. If there is no voltage at the second input, then the pulse packets freely pass through the bridge 32 from the input from the first to the fourteenth switching unit 31 to its output, from the fifteenth to the twenty-eighth outputs. This blocking voltage is supplied to the twenty-ninth input of the switching unit 31 through the element NOT 34. Therefore, there is no voltage at the second input of the bridges 32 and the pulses freely pass through fourteen bridges 32 from the input of the switch 31 to its fourteen outputs. At the same time, the voltage at the twenty-ninth input goes directly to the first inputs of the fourteen receiving diode-capacitive bridges 33, which ensures the locking of the bridges 33 for transmitting the high voltage created by the shaper of spectrum 2. The control locking voltage is supplied out of phase for the transmitting bridges 32 through the element 34, and for receiving bridges 33 directly through the twenty-ninth input of the switch 31. In the absence of high voltage at the twenty-ninth input, a locking voltage appears for giving diode-capacitive bridges 32 at the output of the HE 34 element. During this period, the reaction of the experimentally exposed elements to secondary radiation (re-radiation) by the antenna system 4 is recorded and the reaction in the form of induced voltages (EMF) enters fourteen inputs, from the fifteenth to the twenty-eighth to the first the inputs of the fourteen receiving diode-capacitive bridges 33, which are open at this time, and then goes to the outputs of the switching unit 31 from the first to the fourteenth. Moreover, the secondary radiation is recorded on fourteen channels in each block 31, which ensures the study of the frequencies of the secondary emitters, the polarization properties of the radiation field and its levels.

The switching control units of the transceiver antenna system 30-1 and 30-2 are represented by the unit 30 in FIG. 5, since the blocks 30-1 and 30-2 are structurally identical and, therefore, their principle of operation is the same. Consider the operation of the switching control unit of the transceiver antenna system 30 (Fig. 5). Fourteen inputs from the first to fourteenth switching control unit of the transceiver antenna system 30 (Fig. 5) of the antenna switch 3 are connected to the fourteen primary windings 1 of the transformer Tr. 1. At the same time, for each input out of fourteen, five packets of pulses arrive, and the arrival of packets at each subsequent input in comparison with the previous one differs in time by 1 ms. The transformer Tr. 1 sums up every five pulse packets arriving separately on fourteen channels spaced in time and, on the secondary winding, an EMF corresponding to the action on each input of the pulse packets in the primary windings is excited. When pulse packets appear in any primary winding, an EMF is excited at the output of the secondary winding, and this EMF is transmitted to a voltage amplifier 35. At the output of amplifier 35, a high voltage in the form of a single pulse with a duration of five packets (about 3.72 μs) arriving at the first output of the control unit 30. The included valve B.1 allows you to generate a positive pulse at the output of the amplifier 35.

The diode-capacitive bridges transmitting 32 and receiving 33 are structurally identical, and perform the same functions (Fig. 6). The receiving bridges 33 provide protection of the receiving path when the antenna system 4 is high voltage, and the transmitting bridges 32 provide protection of the receiving path from accidental, unauthorized high voltage supply from the generators A1, A2, A3, A4 and A5 through a switching and distribution network. The diode-capacitive bridge 32 (or 33) contains two parallel circuits between the terminals “c” and “d”: the first circuit is a series connection of the first valve B.1 and the second capacity C ₂ ; the second circuit is a series connection of the second valve B.2 and the first tank C ₁ . The gates in the chains are turned on. Terminal “d” is connected to the second input of the bridge 32 (33), and terminal “c” is connected to the output of the bridge 32 (33). The connection points of the valve with the capacity in each circuit form the terminals “b” and “a”. High resistance impedances of the same magnitude are connected to terminals “b” and “a”, i.e. R ₁ = R ₂ . Resistance R ₁ and R _{2 are} connected in parallel to the first input of the bridge 32 (33). At the first input of the bridge, a control high voltage is supplied through the resistances R ₁ and R ₂ to the cathodes of valves B.1 and B.2, ensuring that they are locked to allow currents flowing through them to the bridge at the second input to the bridge output. The control voltage for the bridges 33 is supplied at the first output from the control unit 30, and for the bridges 32 at the first output of the control unit 30 through the element 34 (Fig. 4).

Five packets of pulses distributed over time along twenty eight channels in the form of high voltage levels are supplied to twenty eight inputs of the high voltage irradiating system 11 (11-1 and 11-2), containing N rulers. Each of N rulers consists of twenty eight flat metal plates. For example, the first line L1 consists of twenty-eight flat metal plates from the first 1-1 to the twenty-eighth 1-28. Twenty-eight inputs of the high-voltage irradiating system 11 are connected in parallel with twenty-eight flat metal plates through a capacitor C ₁ proper for each plate (Fig. 17). According to twenty-eight inputs, the voltage of the pulse packets U _IMP is supplied to the irradiators (metal plates). At the same time, a high-voltage constant voltage U _{STAT of} a direct current source or a high voltage source 12 is supplied to the metal plates. Thus, the total driving voltage on the radiating elements 11-1 and 11-2 will be presented as U = U _STAT + U _IMP (Fig. 21) . This excitation voltage has a variable component in the range from 1 MHz to 100 MHz, and the constant component creates a high level of field strength from 10 kV to 50 kV. The response to excitations in the form of secondary radiation of an electromagnetic field is recorded by the receiving antenna system 4. The relative position of the radiating antenna system 11 (consisting of 11-1 and 11-2) and the receiving antenna system 4 is shown in FIG. 23. As can be seen from FIG. 23, the receiving antenna system 4 is located on four sides and allows you to record the radiation of both linear and circular polarization. The receiving antenna system 4 consists of conductors arranged in a circle on a plane. Each conductor is an emitter or antenna. The structure of the design of the receiving antenna system 4 is shown in FIG. 7, where twenty-eight inputs are connected to twenty-eight antennas. Each antenna, from the first to the twenty-eighth, is a conductor with a load at the end 36 (Fig. 8). Twenty-eight antennas operate in strong elongation mode, therefore, to increase their effective length, each antenna is loaded through the inductance L _K on the capacitance - C (Fig. 8).

After irradiation of the studied objects in the antenna system 11-1 and 11-2, the latter excite the secondary electromagnetic field, which induces the EMF in the antenna system 4. This EMF enters through the receiving bridges 33 of the antenna switch 3 to fourteen outputs of two switches 31-1 and 31- 2 (Fig. 4) and then to the twenty-eight outputs of the antenna switch 3 (Fig. 1) from the twenty-ninth to fifty-sixth (Fig. 1 and Fig. 3).

These twenty-eight outputs of the switch transceiver antennas 3 are connected to twenty-eight inputs of the adaptive Converter 5.

Adaptive converter 5 (Fig. 9), containing a switch Vk.1 for twenty-eight boards, each board for two switching positions with a common control unit - “VK-Off.” 37 — generator of the studied frequency range, 38 — own current corrector on each of the 28 channels of the adaptive converter 5, while the twenty eight inputs of the adaptive converter 5 are connected to the zero terminal on the twenty-eight circuit boards of the switch Vk.1, their own board in each of the twenty eight channels. When the Bk.1 switch is turned on, the zero terminal in each channel, on each of the twenty-eight boards, must be connected to the first terminal, while the input of each of the twenty-eight channels of the adaptive converter 5 is connected to its output of the 5 each of the twenty-eight channels through the zero terminal, the first terminal, through the first input of the current corrector 38 in each of the twenty-eight channels of the adaptive converter 5. When the Bk.1 switch is turned on, “Off” is turned off, each input of twenty eight channels fishing adaptive converter 5 is connected with its output adaptive converter 5 via terminal zero and two terminal; the output of the generator of the studied frequency range 37 is connected in parallel with the second inputs of the current corrector 38 in each of the twenty-eight channels of the adaptive converter 5. The task of the adaptive converter 5 is to provide the same phase of the induced currents of the studied frequency of the secondary emitters, which is set by the phase of the frequency of the reference generator 37, which will be the studied frequency, and then all the EMFs of the induced studied frequency via twenty-eight channels are fed to the adder 6, which is the information generator and the secondary radiation emitters 6 (or twenty-eight inputs information generator secondary radiation emitters 6).

The current corrector 38 for each of the 28 channels (Fig. 10) contains a phase detector 39 and a phase corrector 40 (phase shifter), while the first input of the current corrector - 38 is connected in parallel with the second inputs of the phase detector 39 and phase corrector 40, and the second input of the corrector current 38 is connected to the first input of the phase detector 39, the output of the phase detector 39 is connected through the first input to the phase corrector 40 with the output of the current corrector 38.

These twenty-eight outputs of the adaptive converter 5 are connected to twenty-eight inputs of the radiation information generator of the secondary emitters 6 (Fig. 11) from the first to the twenty-eighth input. Twenty-eight inputs of the secondary radiation emitter 6 information generator are connected in each of the twenty-eight channels to terminal “a” of each primary winding of transformer Tr.1 through broadband amplifier 41. Terminal “b” of each of the twenty-eight primary windings of transformer Tr.1 is grounded. Secondary winding 2 of transformer Tr.1 with terminal “c” is connected to the output of the radiation driver of radiation of secondary emitters 6, and terminal “d” of secondary winding 2 of transformer Tr.1 is grounded. The incoming induced EMF via twenty-eight channels by transformer Tr. 1 in the radiation information generator of the secondary emitters 6 are summed. The need for summation allows you to create an overall picture of the radiation spectrum of secondary emitters with their subsequent separation during subsequent processing. Indeed, the object under study can radiate polarized waves different from the excitation fields, so the summation will add the fields to the overall picture of different polarization, but the same frequency spectrum. This is the purpose of the shaper information radiation secondary emitters 6.

The output of the radiation information generator of the secondary emitters 6 (Fig. 1) is connected to the input by the frequency spectrum converter 7, in which the input of the frequency spectrum converter 7 is connected to its output through the first input of the mixer 43 (Fig. 12), the second input of the mixer 43 is connected to the output of the generator sinusoidal voltage 42. The purpose of the frequency spectrum converter 7 is to separate the closely spaced frequency fields of the secondary emitters for their recognition. Indeed, the frequency of the generator 42 is 10 kHz, therefore, adjacent frequencies after their conversion will have frequencies 10 kHz higher, so the frequency can be detected in the secondary radiation mixture. In the case of a direct study of the radiation frequencies by secondary emitters, the spectrum analyzer in the indicator block 9 (Fig. 1) has the opportunity to turn off the frequency conversion through a workaround using switch Bk.1 into two switching positions: spectrum analysis using and without a frequency converter. To turn off the converter, the Bk.1 switch is put into the second position, while the input of the frequency spectrum converter 7 through the second terminals of the Bk.1 switch will be connected to the output of the frequency spectrum converter 7 and the frequencies of the secondary radiation at the output will not undergo frequency conversion.

The output of the frequency spectrum converter 7 is connected to the input of the filter unit 8 (Fig. 1 and Fig. 13), the input of which is connected in parallel to ten frequency filters 44-1 to 44-10, the outputs of ten frequency filters through ten narrow-band amplifiers 45-1 45-10, in each of ten channels, connected to ten outputs of the filter unit 8. Thus, the voltage of the mixture of frequencies of the radiation of the secondary emitters from the output of the converter 7 is supplied to a system of ten filters that divide the frequency spectrum into ten channels. The first filter 44-1 passes frequencies from 1 to 10 kHz, and the amplifier 45-1 amplifies this frequency band; the second filter 44-2 passes the frequencies from 10 to 50 kHz, and the amplifier 45-2 amplifies this frequency band; the third filter 44-3 passes frequencies from 50 to 100 kHz, and the amplifier 45-3 amplifies this frequency band; the fourth filter 44-4 allows the passage of frequencies from 100 to 200 kHz, and the amplifier 45-4 amplifies this frequency band; the fifth filter 44-5 allows the passage of frequencies from 200 to 400 kHz, and the amplifier 45-5 amplifies this frequency band; the sixth filter 44-6 allows the passage of frequencies from 400 to 800 kHz, and the amplifier 45-6 amplifies this frequency band; the seventh filter 44-7 passes frequencies from 800 to 1000 kHz, and the amplifier 45-7 amplifies this frequency band; the eighth filter 44-8 allows the passage of frequencies from 1 to 10 MHz, and the amplifier 45-8 amplifies this frequency band; the ninth filter 44-9 passes frequencies from 10 to 20 MHz, and the amplifier 45-9 amplifies this frequency band; the tenth filter 44-10 passes frequencies from 20 to 40 MHz, and the amplifier 45-10 amplifies this frequency band. Amplified by narrow-band amplifiers 45 in each frequency channel at the output of the filters are fed to the output of the filter unit 8 (Fig. 14).

Ten outputs of the filter unit 8 (Fig. 1 and Fig. 14) are connected to ten inputs of the analysis unit of the spectrum of the secondary radiation 9 (Fig. 14). Ten inputs of the analysis unit of the spectrum of the secondary radiation 9 are connected to the inputs of ten oscillatory systems from 46-1 to 46-10. Each oscillating system 46 forms three outputs: the first second and third. The first and second outputs of each oscillatory system 46 form a system of five conductors (Fig. 15) connected to five resonance indicators in the oscillatory system. The third output of each oscillating system 46 is connected to the output of the analysis unit of the spectrum of the secondary radiation 9, so ten third outputs from ten vibrational systems 46 form ten outputs of the analysis unit of the spectrum of the secondary radiation 9. The first input of the analyzer 9 is connected to the input of the first oscillating system 46 -1 at a frequency of 1-10 kHz, the first output of the first oscillating system 46-1 is connected to the first inputs of the first group of five indicators I.1-1 to I.1-5, and the second output of the first oscillating system 46-1 is connected to second in by the first group of five indicators I.1-1 through I.1-5, the third output of the first oscillating system 46-1 is connected to the first output of the secondary radiation spectrum analyzer 9; the second input of the analyzer 9 is connected to the input of the second oscillatory system 46-2 at a frequency of 10-50 kHz, the first output of the second oscillatory system 46-2 is connected to the first inputs of the second group of five indicators I.2-1 to I.2-5, and the second output of the second oscillating system 46-2 is connected to the second inputs of the second group of five indicators I.2-1 to I.2-5, the third output of the second oscillating system 46-2 is connected to the second output of the secondary radiation spectrum analyzer 9; the third input of the analyzer 9 is connected to the input of the third oscillatory system 46-3 at a frequency of 50-100 kHz, the first output of the third oscillatory system 46-3 is connected to the first inputs of the third group of five indicators I.3-1 to I.3-5, and the second output of the third oscillatory system 46-3 is connected to the second inputs of the third group of five indicators I.3-1 to I.3-5, the third output of the third oscillatory system 46-3 is connected to the third output of the secondary radiation spectrum analyzer 9; the fourth input of the analyzer 9 is connected to the input of the fourth oscillatory system 46-4 at a frequency of 100-200 kHz, the first output of the fourth oscillatory system 46-4 is connected to the first inputs of the fourth group of five indicators I.4-1 through I.4-5, and the second output of the fourth oscillatory system 46-4 is connected to the second inputs of the fourth group of five indicators I.4-1 to I.4-5, the third output of the fourth oscillatory system 46-4 is connected to the fourth output of the secondary radiation spectrum analyzer 9; the fifth input of the analyzer 9 is connected to the input of the fifth oscillating system 46-5 at a frequency of 200-400 kHz, the first output of the fifth oscillating system 46-5 is connected to the first inputs of the fifth group of five indicators I.5-1 through I.5-5, and the second output of the fifth oscillatory system 46-5 is connected to the second inputs of the fifth group of five indicators I.5-1 to I.5-5, the third output of the fifth oscillatory system 46-5 is connected to the fifth output of the secondary radiation spectrum analyzer 9; the sixth input of the analyzer 9 is connected to the input of the sixth oscillation system 46-6 at a frequency of 400-800 kHz, the first output of the sixth oscillation system 46-6 is connected to the first inputs of the sixth group of five indicators I.6-1 to I.6-5, and the second output of the sixth vibrational system 46-6 is connected to the second inputs of the sixth group of five indicators I.6-1 to I.6-5, the third output of the sixth vibrational system 46-6 is connected to the sixth output of the secondary radiation spectrum analyzer 9; the seventh input of the analyzer 9 is connected to the input of the seventh oscillatory system 46-7 at frequencies of 800-1000 kHz, the first output of the seventh oscillatory system 46-7 is connected to the first inputs of the seventh group of five indicators I.7-1 to I.7-5, and the second output of the seventh oscillatory system 46-7 is connected to the second inputs of the seventh group of five indicators I.7-1 to I.7-5, the third output of the seventh oscillatory system 46-7 is connected to the seventh output of the secondary radiation spectrum analyzer 9; the eighth input of the analyzer 9 is connected to the input of the eighth oscillatory system 46-8 at a frequency of 1-10 MHz, the first output of the eighth oscillatory system 46-8 is connected to the first inputs of the eighth group of five indicators I.8-1 to I.8-5, and the second output of the eighth oscillatory system 46-8 is connected to the second inputs of the eighth group of five indicators I.8-1 to I.8-5, the third output of the eighth oscillatory system 46-8 is connected to the eighth output of the secondary radiation spectrum analyzer 9; the ninth input of the analyzer 9 is connected to the input of the ninth oscillatory system 46-9 at a frequency of 10-20 MHz, the first output of the ninth oscillatory system 46-9 is connected to the first inputs of the ninth group of five indicators I.9-1 through I.9-5, and the second output of the ninth vibrational system 46-9 is connected to the second inputs of the ninth group of five indicators I.9-1 to I.9-5, the third output of the ninth vibrational system 46-9 is connected to the ninth output of the secondary radiation spectrum analyzer 9; the tenth input of the analyzer 9 is connected to the input of the tenth oscillatory system 46-10 at a frequency of 20-40 MHz, the first output of the tenth oscillatory system 46-10 is connected to the first inputs of the tenth group of five indicators I.10-1 through I.10-5, and the second output of the tenth oscillatory system 46-10 is connected to the second inputs of the tenth group of five indicators I.10-1 to I.10-5, the third output of the tenth oscillatory system 46-10 is connected to the tenth output of the secondary radiation spectrum analyzer 9.

The oscillation system 46 (any of 46-1, 46-2, 46-3, ..., 46-10 the block diagram is identical) contains five oscillatory bridges: 1, 2, 3, 4 and 5 (Fig. 15); each bridge contains a high-resistance resistance R and four parallel oscillatory circuits: two with parameters L ₁ and C ₁ and two with parameters L ₂ and C ₂ , while the input of the oscillating system 46 is connected in parallel with the five inputs of five bridges and with the third output of the oscillating system 46 , the first exits of the five bridges (1, 2, 3, 4, and 5) form the first exit, the second exits of the five bridges (1, 2, 3, 4, and 5) form the second exit; the input of each bridge is connected through terminal “c” through the second parallel oscillating circuit L ₂ and C ₂ , through terminal “a” with the first output of the bridge, and in parallel the point “c” is connected through the first parallel oscillating circuit L ₁ and C ₁ , through the terminal "B" with the second exit of the bridge; terminal “a” is connected via a high-resistance resistance R to terminal “b” and in parallel terminal “a” is connected through a first oscillating circuit L ₁ and C ₁ to terminal “d”, terminal “b” is connected through a parallel second oscillating circuit L ₂ and C ₂ connected to terminal “d”, terminal “d” is grounded; the first oscillation system 46-1 contains five bridges: the first bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 1.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 2.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 3.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 4.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 5.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 6.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 7.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 8.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 9.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 9.9 kHz. The second oscillatory system 46-2 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 11.9 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 15.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 20.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 25.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 30.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 35.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 40.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 44.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 47.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 49.9 kHz. The third oscillation system 46-3 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 52.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 58.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 62.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 68.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 72.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 78.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 82.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 88.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 92.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 98.1 kHz. The fourth oscillation system 46-4 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 110.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 120.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 130.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 140.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 150.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 160.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 170.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 178.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 185.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 198.1 kHz. The fifth oscillation system 46-5 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 210.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 230.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 250.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 270.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 290.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 310.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 330.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 350.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 370.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 390.1 kHz. The sixth oscillation system 46-6 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 410.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 450.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 490.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 530.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 570.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 610.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 650.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 690.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 730.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 790.1 kHz. The seventh oscillation system 46-7 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 810.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 830.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 850.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 870.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 890.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 910.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 930.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 950.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 970.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 990.1 kHz. The eighth oscillation system 46-8 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 1100.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 1900.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 2900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 3900.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 4900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 5900.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 6900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 7900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 8900.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 9900.1 kHz. The ninth oscillation system 46-9 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 10100.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 10900.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 12900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 13900.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 14900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 15900.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 16,900.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 17,900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 18900.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 19900.1 kHz. The tenth oscillation system 46-10 contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 21100.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 23100.1 kHz; a second bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 25100.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 27900.1 kHz; a third bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 30,100.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 32,900.1 kHz; a fourth bridge with a first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 35100.1 kHz, and a second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 37900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 with a} frequency of 38,900.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 with a} frequency of 39900.1 kHz.

The work of bridges is as follows. If a secondary radiation field appears at a frequency f _N, one of the bridge loops, for example, L ₂ and C _2, will be tuned to a given frequency. At resonance circuit resistance will increase and, consequently, a high voltage occurs at the terminal "b" of the bridge, at the same time on a parallel oscillatory circuit elements L ₁ and C ₁ remain not excited and its resistance is small. Through this circuit L ₁ and C ₁ at terminal “a”, the potential will be close to the potential of the earth wire or the grounded terminal “d”. At the high-resistance resistance R or between the terminals “a” and “b”, a potential difference will arise, which will be applied to the outputs of the first and second oscillatory systems. This potential difference applied to one of the LEDs (indicator) will light it, which will indicate the presence of an electromagnetic field emitted by a secondary emitter. Thus established by the indicator, the output number of the oscillatory system can be investigated by connecting to this output the analysis of the spectrum 47, located in the unit for studying the spectrum of secondary radiation 10 (Fig. 16). The unit for studying the spectrum of the secondary radiation 10 (Fig. 16) contains a frequency spectrum analyzer 47 and switch Bk.1 for ten switching positions, while the ten inputs of the unit for studying the spectrum of secondary radiation 9 are connected in parallel to the ten terminals “a” of the switch Bk.1, and ten terminals “b” Vk.1 are connected in parallel to the input of the frequency spectrum analyzer 47. Thus, by signaling, for example, a lit LED, the channel number in which the secondary radiation frequency is present is set. Using the switch Vk.1 at ten positions, connect one of the inputs for the installed channel to the spectrum analyzer 47 and perform studies of the frequency spectrum in a given frequency band. If several emission bands are detected, then all the bands detected by the LEDs are subject to investigation by the spectrum analyzer.

The upper part of the high-voltage irradiating system 11-1, containing N lines of emitters, from the first line - L1 to N line - Ln, each line of emitters contains twenty-eight separation tanks C ₁ , twenty-eight flat radiating metal plates in each line and twenty-eight valves B1 wherein the first input of the upper high-voltage irradiator 11-1 is connected in parallel with the first inputs of each of the N lines, from the first line - L1 to N line - Ln; the second input of the upper high-voltage irradiator 11-1 is connected in parallel with the second inputs of each of the N lines, from the first line - L1 to N line - Ln; the third input of the upper high-voltage feed 11-1 is connected in parallel with the third inputs of each of the N lines, from the first line - L1 to N line - Ln; the fourth input of the upper high-voltage feed 11-1 is connected in parallel with the fourth inputs of each of the N lines, from the first line - L1 to N line - Ln; the fifth input of the upper high-voltage irradiator 11-1 is connected in parallel with the fifth inputs of each of the N lines, from the first line - L1 to N line - Ln; the sixth input of the upper high-voltage irradiator 11-1 is connected in parallel with the sixth inputs of each of the N lines, from the first line - L1 to N line - Ln; the seventh input of the upper high-voltage irradiator 11-1 is connected in parallel with the seventh inputs of each of the N lines, from the first line - L1 to N line - Ln; the eighth input of the upper high-voltage irradiator 11-1 is connected in parallel with the eighth inputs of each of the N lines, from the first line - L1 to N line - Ln; the ninth input of the upper high-voltage feed 11-1 is connected in parallel with the ninth inputs of each of the N lines, from the first line - L1 to N line - Ln; the tenth input of the upper high-voltage irradiator 11-1 is connected in parallel with the tenth inputs of each of the N lines, from the first line - L1 to N line - Ln; the twenty-ninth input of the upper high-voltage feed 11-1 is connected in parallel with the twenty-ninth inputs from the first line - L1 to N line - Ln; the first line of emitters L1 consists of twenty eight flat emitting metal plates, from the first plate 1-1 to the eighth of 1-28, twenty-eight valves B1 and twenty-eight isolation tanks C ₁ , with each of the twenty-eight inputs, from the first 1 to the twenty-eighth 28 inputs, of the first L1 line are connected in parallel with the twenty-eight outputs of the first line of L1 emitters, and through terminal “b” each of the twenty-eight inputs is connected to its own flat radiating metal plate, from the first 1-1 to twenty muyu 1-28, through the capacitance C _1, Twenty-ninth input line connected to the emitters of the first parallel terminal "a" through valve V1 self planar radiating metal plate 1-1 to the first through twenty-eighth 1-28; the second and subsequent lines of emitters, from the second line L2 to line N, are structurally executed like the first line of emitters L1.

According to the twenty-eight inputs of block 11-1, the voltage of the pulse packets U _IMP is supplied to irradiators (metal plates). At the same time, a high-voltage constant voltage U _{STAT of} a direct current source or a high voltage source 12 is supplied to the metal plates. Thus, the total driving voltage on the radiating elements 11-1 and 11-2 will be presented as U = U _STAT + U _IMP (Fig. 21) . This excitation voltage has a variable component in the range from 1 MHz to 100 MHz, and the constant component creates a high level of field strength from 10 kV to 50 kV.

The lower part of the high-voltage irradiating system 11-2 (Fig. 18), containing a grounded metal plate "A" connected to the input of the lower part of the high-voltage irradiating system 11-2, the dimensions of the grounded metal plate "A" are not less than the dimensions of the upper part of the high-voltage irradiating system 11- one.

The high voltage source 12 (Fig. 19) contains six step-up transformers, from the first Tr.1 to the sixth Tr.6, five high-voltage rectifiers consisting of a high-voltage BBB valve, filter inductance L _Ф and filter capacitance C _Ф , two switches Vk.1 and Vk.2, while the primary winding 1 of the first transformer Tr. 1 is connected to a 220-volt supply source, and the secondary winding 11 of the first transformer Tr. 1 is grounded with terminal “d” and connected to terminal “c” in parallel with five terminals “b” »The second switch Vk.2; terminal “a” of the first position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the second step-up transformer Tr.2, through terminal “d” the primary sheath 1 of the second step-up transformer Tr.2 is grounded, the secondary winding 11 of the second step-up transformer Tr.2 terminal "c" is connected to the terminal "b" of the first position of the first switch BK.1 through a high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal "d" of the secondary winding 11 of the second step-up transformer Tr.2 ; terminal “a” of the second position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the third step-up transformer Tr.3, through terminal “d” the primary sheath 1 of the third step-up transformer Tr.3 is grounded, the secondary winding 11 of the third step-up transformer Tr.3 terminal “c” is connected to terminal “b” of the second position of the first switch Vk.1 through the high-voltage valve BBB, through the filter inductance L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the third step-up transformer Tr.3 ; terminal “a” of the third position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the fourth step-up transformer Tr.4, through terminal “d” the primary sheath 1 of the fourth step-up transformer Tr.4 is grounded, the secondary winding 11 of the fourth step-up transformer Tr.4 terminal "c" is connected to a terminal "b" of the third position of the first switch valve via a high Vk.1 BBB through the filter inductance L _P and c _P filter capacitance terminal "d" of the secondary winding 11 of the fourth up transformer Tr.4 grounded; terminal “a” of the fourth position of the second switch Bk.2 is connected through terminal “c” to the primary winding of the fifth step-up transformer Tr.5, through terminal “e” the primary shell 1 of the fifth step-up transformer Tr.5 is grounded, the secondary winding 11 of the fifth step-up transformer Tr.5 terminal “c” is connected to terminal “b” of the fourth position of the first switch Vk.1 through a high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the fifth step-up transformer Tr.5 ; terminal “a” of the fifth position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the sixth step-up transformer Tr.6, through terminal “d” the primary sheath 1 of the sixth step-up transformer Tr.6 is grounded, the secondary winding 11 of the sixth step-up transformer Tr.6 terminal “c” is connected to terminal “b” of the fifth position of the first switch Vk.1 through the high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the sixth step-up transformer Tr.5 ; the terminals "a" of the first switch BK.1 are connected in parallel with the first output of the high voltage source 12; the second output of the high voltage source 12 is connected to the earth wire of the high voltage source 12. Thus, the second transformer Tr.2 generates an output voltage of 10 kV AC, using a high-voltage rectifier BBB and L _Ф C _Ф creates a constant voltage supplied to the first output through the first position of the switch Vk.1 and further on the plate of the emitter 11-1. The third transformer Tr.3 generates an output voltage of 20 kV AC, using a high-voltage rectifier BBB and L _Ф C _Ф a constant voltage is generated that is supplied to the first output through the second position of the switch Vk.1 and then to the emitter plates 11-1.

The fourth transformer Tr.4 creates an output voltage of 30 kV AC, using a high-voltage rectifier BBB and L _Ф C _Ф a constant voltage is generated which is supplied to the first output through the third position of the switch Vk.1 and then to the emitter plates 11-1. The fifth transformer Tr.5 creates an output voltage of 40 kV AC, using a high-voltage rectifier BBB and L _Ф C _Ф , a constant voltage is generated which is supplied to the first output through the fourth position of the switch Vk.1 and then to the emitter plates 11-1. The sixth transformer Tr.6 creates an output voltage of 50 kV AC, using a high-voltage rectifier BBB and L _Ф C _Ф a constant voltage is generated that is supplied to the first output through the fifth position of the switch Vk.1 and further to the emitter plates 11-1.

The earth wire of all transformers is permanently connected to the secondary windings of all high-voltage transformers and is connected to the lower part of the high-voltage irradiating system 11-2. A high constant voltage or potential difference is applied to the plates 11-1 and 11-2, this applied voltage creates a given tension in a confined space for research of secondary radiation.

The authors are not aware of technical solutions from the field of radio communications containing features equivalent to the distinguishing features of the claimed device. The authors are not aware of technical solutions from other technical fields having the properties of the claimed technical object of the invention. Thus, the claimed technical solution, according to the authors, has the criterion of essential features.

Claims (18)

1. A device for studying the electromagnetic field of secondary emitters, containing a clock pulse generator and a radiation spectrum shaper, characterized in that a commutator of transceiver antennas, a receiving antenna system, upper and lower parts of a high-voltage irradiating system, a high voltage source, an adaptive converter, a shaper are introduced radiation information of secondary emitters, frequency spectrum converter, filter unit, radiation spectrum analysis unit, special research unit tra secondary radiation, wherein the clock pulse generator output is connected with the input of the emission spectrum; twenty eight outputs of the radiation spectrum shaper are connected to twenty eight inputs of the switch of the transceiver antennas; twenty-eight outputs of the switch of the transceiver antennas, from the first to the twenty-eighth, are connected in parallel with the twenty-eight inputs of the upper part of the high-voltage irradiating system; twenty-eight inputs of the switch of the transceiver antennas, from the twenty-ninth to the fifty-sixth inputs, are connected in parallel with four receiving antenna systems; twenty-eight outputs of the switch of the transceiver antennas, from the twenty-ninth to the fifty-sixth outputs, are connected through an adaptive converter with twenty-eight inputs of the radiation information generator of the secondary emitters; the output of the information generator is connected through the frequency spectrum converter, through ten outputs of the filter block with ten inputs of the secondary radiation spectrum analysis block; ten outputs of the secondary spectrum spectrum analysis unit are connected to ten inputs of the radiation spectrum research unit; the first output of the high voltage source is connected to the twenty-ninth input of the upper part of the high voltage irradiating system, and the second output of the high voltage source is connected to the input of the lower part of the high voltage irradiating system. 2. A device for studying the electromagnetic field of secondary emitters according to claim 1, characterized in that the radiation spectrum shaper comprises an And element, a first trigger for 0.01 μs, twenty eight discrete delay lines for 1 ms, thirty eight gates, and a switch Vk. 1 s terminals “a” and “b”, a discrete delay line at 0.01 µs, a second trigger at 0.02 µs, two discrete delay lines at 0.02 µs, a third trigger at 0.05 µs, two discrete delay lines at 0 , 05 μs, fourth trigger at 0.1 μs, two discrete delay lines at 0.1 μs, fifth trigger at 1 μs, 1 μs discrete delay line, voltage amplifier, collective line with five terminals: 1, 2, 3, 4, and 5; the first packet generator of two pulses of 0.01 μs each contains: two gates and a discrete delay line of 0.01 μs; the second generator of a packet of two pulses of 0.02 μs each contains: two gates, a discrete delay line of 0.02 μs, a discrete delay line of 0.01 μs and a second trigger of 0.02 μs; the third generator of a packet of two pulses of 0.05 μs each contains: two gates, a discrete delay line of 0.02 μs, a discrete delay line of 0.05 μs and a third trigger of 0.05 μs; the fourth packet generator of two pulses of 0.1 μs each contains: two gates, a discrete delay line of 0.05 μs, a discrete delay line of 0.1 μs and a fourth trigger of 0.1 μs; the fifth packet generator of two pulses of 1 μs each contains: two gates, a discrete delay line of 0.1 μs, a discrete delay line of 1 μs and a fifth trigger of 1 μs; the pulse switch contains twenty eight gates and twenty eight discrete delay lines for 1 ms, while the first input of the radiation spectrum shaper is connected in parallel with the second input of the And element directly, and with the first input of the And element through the first switch and through the first trigger for 0.01 μs ; the output of the element And is connected to the input of the first pulse packet generator; the input of the first packet generator of two pulses of 0.01 μs is connected to the output in parallel through the first valve and through the first delay line by 0.01 μs, and also through the second valve, the output of the first generator is connected to the first terminal of the collective line; the input of the second packet generator of two pulses of 0.02 μs is connected to the output of the first generator, the input of the second generator is connected to the second trigger through the second discrete delay line of 0.01 μs, the output of the second trigger is connected to the output of the second generator of packets of two pulses of 0 , 02 μs through the third valve, through the third discrete delay line by 0.02 μs and in parallel through the fourth valve, the output of the second packet generator of two pulses of 0.02 μs is connected to the second terminal of the collective line and in parallel with the input tego packet generator from two pulses of 0.05 ms; the input of the third packet generator of two pulses of 0.05 μs is connected to the third trigger by 0.05 μs through the fourth discrete delay line of 0.02 μs, the output of the third trigger is connected to the output of the third packet generator of two pulses of 0.05 μs through the fifth gate, through the fifth discrete delay line by 0.05 μs and in parallel through the sixth valve, the output of the third packet generator of two pulses of 0.05 μs is connected to the third terminal of the collective line and in parallel with the input of the fourth packet generator of two pulses of 0, 1m cop; the input of the fourth packet generator of two pulses of 0.1 μs is connected to the fourth trigger by 0.1 μs through the sixth discrete delay line of 0.05 μs, the output of the fourth trigger is connected to the output of the fourth packet generator of two pulses of 0.1 μs through the seventh valve, through the seventh discrete delay line of 0.1 μs and in parallel through the eighth valve, the output of the fourth packet generator of two pulses of 0.1 μs is connected to the fourth terminal of the collective line and in parallel with the input of the fifth packet generator of two pulses in 1 ms; the input of the fifth packet generator of two pulses of 1 μs is connected to the fifth trigger by 1 μs through the eighth discrete delay line of 0.1 μs, the output of the fifth trigger is connected to the output of the fifth generator of packets of two pulses of 1 μs through the ninth valve, through the ninth line a discrete delay of 1 μs and in parallel through the tenth valve, the output of the fifth packet generator from two pulses of 1 μs is connected to the fifth terminal of the collective line; the input of the voltage amplifier is connected to a collective line; the output of the voltage amplifier is connected to the first output of the radiation spectrum shaper and in parallel with the input of the pulse switch consisting of twenty-eight gates and twenty-eight delay lines for 1 ms connected in series; the amplifier output is connected through the tenth discrete delay line for 1 ms and through the eleventh gate to the second output of the radiation spectrum shaper and in parallel to the input of the eleventh discrete delay line for 1 ms; the output of the eleventh discrete delay line for 1 ms is connected through the twelfth gate to the third output of the radiation spectrum shaper and in parallel to the input of the twelfth discrete delay line for 1 ms; the output of the twelfth delay line for 1 ms is connected through the thirteenth gate to the fourth output of the radiation spectrum shaper and in parallel to the input of the thirteenth discrete delay line for 1 ms; the output of the thirteenth delay line for 1 ms is connected through the fourteenth gate to the fifth output of the radiation spectrum shaper and in parallel to the input of the fourteenth discrete delay line for 1 ms; the output of the fourteenth line for 1 ms is connected through the fifteenth gate to the sixth output of the radiation spectrum shaper and in parallel to the input of the fifteenth discrete delay line for 1 ms; the output of the fifteenth delay line for 1 ms is connected via the sixteenth gate to the seventh output of the radiation spectrum shaper and in parallel to the input of the sixteenth discrete delay line for 1 ms; the output of the sixteenth 1 ms delay line is connected through the seventeenth gate to the eighth output of the radiation spectrum shaper and in parallel to the input of the seventeenth discrete delay 1 ms; the output of the seventeenth 1 ms delay line is connected through the eighteenth gate to the ninth output of the radiation spectrum shaper and in parallel to the input of the eighteenth discrete delay line for 1 ms; the output of the eighteenth 1 ms delay line is connected through the nineteenth gate to the tenth output of the radiation spectrum shaper and in parallel to the input of the nineteenth 1 ms discrete delay line; the output of the nineteenth delay line for 1 ms is connected through the twentieth gate to the eleventh output of the radiation spectrum shaper and in parallel to the input of the twentieth discrete delay line for 1 ms; the output of the twentieth delay line for 1 ms is connected through the twenty-first valve to the twelfth output of the radiation spectrum shaper and in parallel to the input of the twenty-first discrete delay line for 1 ms; the output of the twenty-first 1 ms delay line is connected through the twenty-second gate to the thirteenth output of the radiation spectrum shaper and in parallel to the input of the twenty-second discrete delay line for 1 ms; the output of the twenty-second delay line for 1 ms is connected through the twenty-third gate to the fourteenth output of the shaper of the radiation spectrum and in parallel to the input of the twenty-third discrete delay line for 1 ms; the output of the twenty-third 1 ms delay line is connected through the twenty-fourth gate to the fifteenth output of the radiation spectrum shaper and in parallel to the input of the twenty-fourth discrete delay line for 1 ms; the output of the twenty-fourth delay line for 1 ms is connected via the twenty-fifth gate to the sixteenth output of the radiation spectrum shaper and in parallel to the input of the twenty-fifth discrete delay line for 1 ms; the output of the twenty-fifth delay line for 1 ms is connected through the twenty-sixth gate to the seventeenth output of the radiation spectrum shaper and in parallel to the input of the twenty-sixth discrete delay line for 1 ms; the output of the twenty-sixth 1 ms delay line is connected through the twenty-seventh gate to the eighteenth output of the radiation spectrum shaper and in parallel to the input of the twenty-seventh discrete delay line for 1 ms; the output of the twenty-seventh 1 ms delay line is connected through the twenty-eighth gate to the nineteenth output of the radiation spectrum shaper and in parallel to the input of the twenty-eighth discrete delay line for 1 ms; the output of the twenty-eighth delay line for 1 ms is connected through the twenty-ninth gate to the twentieth output of the radiation spectrum shaper and in parallel to the input of the twenty-ninth discrete delay line for 1 ms; the output of the twenty-ninth line for 1 ms is connected through the thirtieth gate to the twenty-first output of the radiation spectrum shaper and in parallel to the input of the thirtieth discrete delay line for 1 ms; the output of the thirtieth delay line for 1 ms is connected through the thirty-first valve to the twenty-second output of the radiation spectrum shaper and in parallel to the input of the thirty-first discrete delay line for 1 ms; the output of the thirty-first 1 ms delay line is connected through the thirty-second valve to the twenty-third output of the radiation spectrum shaper and parallel to the input of the thirty-second discrete delay line for 1 ms; the output of the thirty-second 1 ms delay line is connected through the thirty-third valve to the twenty-fourth output of the radiation spectrum shaper and in parallel to the input of the thirty-third discrete delay line for 1 ms; the output of the thirty-third 1 ms delay line is connected through the thirty-fourth gate to the twenty-fifth output of the radiation spectrum shaper and parallel to the input of the thirty-fourth discrete delay line for 1 ms; the output of the thirty-fourth delay line for 1 ms is connected through the thirty-fifth gate to the twenty-sixth output of the radiation spectrum shaper and in parallel to the input of the thirty-fifth discrete delay line for 1 ms; the output of the thirty-fifth delay line for 1 ms is connected through the thirty-sixth gate to the twenty-seventh output of the radiation spectrum shaper and in parallel to the input of the thirty-sixth discrete delay line for 1 ms; the output of the thirty-sixth 1 ms delay line is connected through the thirty-seventh gate to the twenty-eighth output of the radiation spectrum shaper and in parallel to the input of the thirty-seventh discrete delay line for 1 ms; the output of the thirty-seventh delay line for 1 ms is connected through the thirty-eighth gate to the input of the first trigger through terminal “a” of the first switch. 3. A device for studying the electromagnetic field of secondary emitters according to claim 2, characterized in that the switchboard of the transceiver antennas comprises: a first and a second, two identical switches with fourteen inputs each; the first and second, two identical switching control units of the transceiver antenna system with fourteen inputs each and two gates; while the fourteen inputs of the switch of the transceiver antennas, from the first to the fourteenth, are connected in parallel with fourteen inputs of the first switch and with fourteen inputs of the first switching control unit of the transceiver antenna system; fourteen inputs of the switch of the transceiver antennas, from the fifteenth to the twenty-eighth, are connected in parallel with fourteen inputs of the second switch and fourteen inputs of the second switching control unit of the transceiver antenna system; fourteen inputs, from the fifteenth to twenty-eighth inputs, of the first switch are connected to fourteen inputs, from the twenty-ninth to forty-second, of the transmitter-receiver antenna switch; fourteen entrances, from the fifteenth to twenty-eighth, of the second switch are connected to fourteen inputs, from the forty-third to fifty-sixth, of the transmitter-receiver antenna switch; fourteen outputs, from the first to fourteenth, of the first switch are connected to fourteen outputs, from the forty-third to fifty-sixth, of the transmitter-receiver antenna switch; fourteen outputs, from the first to the fourteenth, of the second switch are connected to fourteen outputs, from the twenty-ninth to forty-second, of the transmitter-receiver antenna switch; fourteen outputs, from the fifteenth to twenty-eighth, of the first switch are connected to fourteen outputs, from the first to the fifteenth, of the transmitter-receiver antenna switch; fourteen outputs, from the fifteenth to twenty-eighth, of the second switch connected to fourteen outputs, from the fifteenth to twenty-eighth, of the switch of the transceiver antennas; the output of the first and second switching control units of the transceiver antenna system is connected to terminal “a” through the valves, terminal “a” is connected in parallel with the twenty-ninth inputs of the first and second switches. 4. A device for studying the electromagnetic field of secondary emitters according to claim 3, characterized in that the switchboard comprises: fourteen receiving diode-capacitive bridges (on the receiving side of the antennas) and fourteen transmitting diode-capacitive bridges (on the transmitting side of the antennas) and an element NOT this fourteen inputs, from the first to fourteenth, of the switch are connected in parallel with the first inputs of the fourteen transmitting diode-capacitive bridges, and the second inputs of the fourteen transmitting diode-capacitive bridges are connected in parallel with the output of the element is NOT; the outputs of fourteen transmitting diode-capacitive bridges are connected to fourteen outputs of the switch, from the fifteenth to the twenty-eighth; fourteen inputs of the switch, starting from the fifteenth to the twenty-eighth, are connected to the second inputs of the fourteen receiving diode-capacitive bridges; the first inputs of fourteen receiving diode-capacitive bridges are connected in parallel with the twenty-ninth input of the switch; the outputs of fourteen receiving diode-capacitive bridges are connected in parallel with fourteen outputs, starting from the first to fourteenth output of the switch; for example, the first transmission channel is formed - the first input of the switch is connected to the first input of the first transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, and the input of the element is NOT connected to the twenty-ninth input of the switch, the output of this bridge is connected to the fifteenth switch output; the second transmission channel is formed - the second input of the switch is connected to the first input of the second transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the sixteenth output of the switch; the third transmission channel is formed - the third input of the switch is connected to the first input of the third transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the seventeenth output of the switch; the fourth transmission channel is formed - the fourth input of the switch is connected to the first input of the fourth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the eighteenth output of the switch; the fifth transmission channel is formed - the fifth input of the switch is connected to the first input of the fifth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the nineteenth output of the switch; the sixth transmission channel is formed - the sixth input of the switch is connected to the first input of the sixth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twentieth output of the switch; the seventh transmission channel is formed - the seventh input of the switch is connected to the first input of the seventh transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-first output of the switch; the eighth transmission channel is formed - the eighth input of the switch is connected to the first input of the eighth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-second output of the switch; the ninth transmission channel is formed — the ninth input of the switch is connected to the first input of the ninth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-third output of the switch; the tenth transmission channel is formed - the tenth input of the switch is connected to the first input of the tenth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-fourth output of the switch; the eleventh transmission channel is formed - the eleventh input of the switch is connected to the first input of the eleventh transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-fifth output of the switch; the twelfth transmission channel is formed - the twelfth input of the switch is connected to the first input of the twelfth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-sixth output of the switch; the thirteenth transmission channel is formed - the thirteenth input of the switch is connected to the first input of the thirteenth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-seventh output of the switch; the fourteenth transmission channel is formed - the fourteenth input of the switch is connected to the first input of the fourteenth transmitting diode-capacitive bridge, and the second input of this transmitting bridge is connected to the output of the element NOT, the output of this bridge is connected to the twenty-eighth output of the switch; the first reception channel is formed - the fifteenth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the first output of the switch; the second reception channel is formed - the sixteenth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the second output of the switch; the third reception channel is formed - the seventeenth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the third output of the switch; the fourth reception channel is formed - the eighteenth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the fourth output of the switch; the fifth reception channel is formed - the nineteenth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the fifth output of the switch; the sixth reception channel is formed - the twentieth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the sixth output of the switch; the seventh reception channel is formed - the twenty-first input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the seventh output of the switch; the eighth reception channel is formed - the twenty-second input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the eighth output of the switch; the ninth reception channel is formed - the twenty-third input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the ninth output of the switch; the tenth reception channel is formed - the twenty-fourth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the tenth output of the switch; the eleventh reception channel is formed - the twenty-fifth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the eleventh output of the switch; the twelfth receiving channel is formed - the twenty-sixth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the twelfth output of the switch; the thirteenth reception channel is formed - the twenty-seventh input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the thirteenth output of the switch; the fourteenth reception channel is formed - the twenty-eighth input of the switch is connected to the second input of the receiving diode-capacitive bridge, the first input of which is connected to the twenty-ninth input of the switch, the output of this receiving diode-capacitive bridge is connected to the fourteenth output of the switch. 5. A device for studying the electromagnetic field of secondary emitters according to claim 4, characterized in that the switching control unit of the transceiver antenna system comprises a Tr-1 transformer with fifteen primary and one secondary winding, a voltage amplifier, a valve; while the fifteen inputs of the switching control unit of the transceiver antenna system are connected in parallel with the terminal “a” of the fifteen primary windings of the transformer Tr.1, and the terminal “b” of the fifteen primary windings of the transformer Tr.1 is grounded; the secondary winding with terminal “0” is grounded, and terminal “c” is connected to the output of the switching control unit via a valve and a voltage amplifier. 6. A device for studying the electromagnetic field of secondary emitters according to claim 5, characterized in that the receiving diode-capacitive bridge and the transmitting diode-capacitive bridge contain the same elements each: two resistors (R ₁ and R ₂ are high-resistance active, with a resistance of at least one hundred megohm), two valves, two tanks (C1 and C2), while the first input of the diode-capacitive bridge is connected in parallel to the diagonal of the bridge, to points “a” and “b”, so the first bridge input is connected through the first active resistance R ₁ to point "a", and through the second active resistance Leniye R ₂ to the point "b"; the second input of the diode-capacitive bridge is connected to point “d”, point “d” is connected to point “c” in parallel in two circuits: the first through the second capacitance C ₂ and the first valve, and the second circuit through the second valve and the first capacitance C ₁ ; point "c" is connected to the output of the diode-capacitive bridge. 7. A device for studying the electromagnetic field of secondary emitters according to claim 6, characterized in that each of the four receiving antenna systems contains twenty-eight receiving antennas (vibrators), on the one hand, each of the twenty-eight vibrators is connected to one of the twenty-eight inputs of the receiving antenna system and, on the other hand, each of the twenty-eight antennas is connected to a grounded load inductance L _K connected in series and a capacitance C providing an increase in the electric length of the vibrator. 8. The device for studying the electromagnetic field of the secondary emitters according to claim 7, characterized in that the adaptive converter comprises a switch BK.1 for twenty-eight boards, each board for two switching positions with a common control unit - “VK. “Off.”, The generator of the range of the studied frequencies, the current corrector, own on each of the twenty-eight channels of the adaptive converter, while the twenty-eight inputs of the adaptive converter are connected to the zero terminal of each on the twenty-eight circuit boards of switch Vk.1, their own board in each of the twenty eight channels, in the switch position of the first “Vk.” the zero terminal in each channel, on each of the twenty-eight boards, is connected to the first terminal, while the input of each of the twenty-eight adaptive conversion channels The cable is connected to its converter output in each channel through the zero terminal, the first terminal with the first input of the current corrector; when the switch of the first Vk.1 is turned on to the “Off” position, each input of twenty-eight channels of the adaptive converter is connected to its output of the adaptive converter through terminal zero and terminal two; the output of the generator of the range of the studied frequencies is connected in parallel with the second inputs of the current corrector in each of the channels of the adaptive converter, the output of the current corrector is connected to the output of the adaptive converter. 9. The device for studying the electromagnetic field of the secondary emitters according to claim 8, characterized in that the current corrector in each of the twenty-eight channels of the adaptive converter comprises a phase detector and a phase corrector, while the first input of the current corrector is connected in parallel with the second inputs of the phase detector and phase corrector and the second input of the current corrector is connected to the first input of the phase detector, the output of the phase detector is connected through the first input of the phase corrector to the output of the current corrector. 10. A device for studying the electromagnetic field of secondary emitters according to claim 9, characterized in that the shaper of radiation information of secondary emitters comprises: a transformer with twenty eight primary windings and one secondary winding, twenty eight broadband amplifiers, while twenty eight inputs of the shaper of radiation information of secondary emitters twenty eight parallel independent channels form, in each of twenty eight channels the input of the secondary radiation radiation information generator STUDIO connected via its own channel in each broadband amplifier to terminal "a" of the transformer primary winding and the terminal "b" in each channel of the primary winding of the transformer is grounded; the output of the radiation information generator of the secondary emitters is connected to the terminal “c” of the secondary winding of the transformer, and the terminal “d” of the secondary winding of the transformer is grounded. 11. A device for studying the electromagnetic field of secondary emitters according to claim 10, characterized in that the frequency spectrum converter comprises: a 10 kHz generator, a mixer, a two-position switch, wherein the input of the frequency spectrum converter is connected to the output of the frequency spectrum converter in parallel through the first terminal switch and the first input of the mixer, and also through the second terminal of the switch directly, the second input of the mixer is connected to the output of the generator. 12. The device for studying the electromagnetic field of secondary emitters according to claim 11, characterized in that the filter unit contains ten channels, in each channel: a narrow-band filter and narrow-band amplifiers, while the input of the filter unit to ten channels is connected in parallel with ten inputs of ten filters; the output of the first filter with a bandwidth of 1 kHz to 10 kHz is connected to the first output of the filter unit through a narrow-band amplifier; the output of the second filter with a bandwidth of 10 kHz to 50 kHz is connected to the second output of the filter unit through a narrow-band amplifier; the output of the third filter with a passband from 50 kHz to 100 kHz is connected to the third output of the filter unit through a narrow-band amplifier; the output of the fourth filter with a passband from 100 kHz to 200 kHz is connected to the fourth output of the filter unit through a narrow-band amplifier; the output of the fifth filter with a bandwidth of 200 kHz to 400 kHz is connected to the fifth output of the filter unit through a narrow-band amplifier; the output of the sixth filter with a passband from 400 kHz to 800 kHz is connected to the sixth output of the filter unit through a narrow-band amplifier; the output of the seventh filter with a bandwidth of 800 kHz to 1000 kHz is connected to the seventh output of the filter unit through a narrow-band amplifier; the output of the eighth filter with a bandwidth of 1.0 to 10 MHz is connected to the eighth output of the filter unit through a narrow-band amplifier; the output of the ninth filter with a bandwidth of 10 to 20 MHz is connected to the ninth output of the filter unit through a narrow-band amplifier; the output of the tenth filter with a bandwidth of 20 to 40 MHz is connected to the tenth output of the filter unit through a narrow-band amplifier. 13. The device for studying the electromagnetic field of secondary emitters according to claim 12, characterized in that the analyzer of the spectrum of secondary radiation into ten channels, containing ten oscillatory systems from the first to the tenth and ten groups of five indicators in each group, or fifty indicators (LEDs) from I.1-1 to I.10-5, five indicators for each oscillatory system; the first input of the spectrum analyzer of the secondary radiation is connected to the input of the first oscillatory system at frequencies of 1-10 kHz, the first output of the first oscillatory system is connected to the first inputs of the first group of five indicators I.1-1 through I.1-5, and the second the output of the first oscillatory system is connected to the second inputs of the first group of five indicators I.1-1 to I.1-5, the third output of the first oscillatory system is connected to the first output of the secondary radiation spectrum analyzer; the second input of the analyzer is connected to the input of the second oscillatory system at frequencies of 10-50 kHz, the first output of the second oscillatory system is connected to the first inputs of the second group of five indicators I.2-1 to I.2-5, and the second output of the second oscillatory system is connected with the second inputs of the second group of five indicators I.2-1 through I.2-5, the third output of the second oscillatory system is connected to the second output of the secondary radiation spectrum analyzer; the third input of the analyzer is connected to the input of the third oscillatory system at frequencies of 50-100 kHz, the first output of the third oscillatory system is connected to the first inputs of the third group of five indicators I.3-1 to I.3-5, and the second output of the third oscillatory system is connected with the second inputs of the third group of five indicators I.3-1 to I.3-5, the third output of the third oscillatory system is connected to the third output of the secondary radiation spectrum analyzer; the fourth input of the analyzer is connected to the input of the fourth oscillatory system at frequencies of 100-200 kHz, the first output of the fourth oscillatory system is connected to the first inputs of the fourth group of five indicators I.4-1 to I.4-5, and the second output of the fourth oscillatory system is connected with the second inputs of the fourth group of five indicators I.4-1 to I.4-5, the third output of the fourth oscillatory system is connected to the fourth output of the secondary radiation spectrum analyzer; the fifth input of the analyzer is connected to the input of the fifth oscillatory system at frequencies of 200-400 kHz, the first output of the fifth oscillatory system is connected to the first inputs of the fifth group of five indicators I.5-1 to I.5-5, and the second output of the fifth oscillatory system is connected with the second inputs of the fifth group of five indicators I.5-1 to I.5-5, the third output of the fifth oscillatory system is connected to the fifth output of the secondary radiation spectrum analyzer; the sixth input of the analyzer is connected to the input of the sixth oscillatory system at frequencies of 400-800 kHz, the first output of the sixth oscillatory system is connected to the first inputs of the sixth group of five indicators I.6-1 to I.6-5, and the second output of the sixth oscillatory system is connected with the second inputs of the sixth group of five indicators I.6-1 to I.6-5, the third output of the sixth oscillatory system is connected to the sixth output of the secondary radiation spectrum analyzer; the seventh input of the analyzer is connected to the input of the seventh oscillatory system at frequencies of 800-1000 kHz, the first output of the seventh oscillatory system is connected to the first inputs of the seventh group of five indicators I.7-1 to I.7-5, and the second output of the seventh oscillatory system is connected with the second inputs of the seventh group of five indicators I.7-1 to I.7-5, the third output of the seventh oscillatory system is connected to the seventh output of the secondary radiation spectrum analyzer; the eighth input of the analyzer is connected to the input of the eighth oscillatory system at frequencies of 1-10 MHz, the first output of the eighth oscillatory system is connected to the first inputs of the eighth group of five indicators I.8-1 to I.8-5, and the second output of the eighth oscillatory system is connected with the second inputs of the eighth group of five indicators I.8-1 to I.8-5, the third output of the eighth oscillatory system is connected to the eighth output of the secondary radiation spectrum analyzer; the ninth input of the analyzer is connected to the input of the ninth oscillatory system at frequencies of 10-20 MHz, the first output of the ninth oscillatory system is connected to the first inputs of the ninth group of five indicators I.9-1 to I.9-5, and the second output of the ninth oscillatory system is connected with the second inputs of the ninth group of five indicators I.9-1 through I.9-5, the third output of the ninth oscillatory system is connected to the ninth output of the secondary radiation spectrum analyzer; the tenth input of the analyzer is connected to the input of the tenth oscillatory system at frequencies of 20-40 MHz, the first output of the tenth oscillatory system is connected to the first inputs of the tenth group of five indicators I.10-1 through I.10-5, and the second output of the tenth oscillatory system is connected with the second inputs of the tenth group of five indicators I.10-1 through I.10-5, the third output of the tenth oscillatory system is connected to the tenth output of the secondary radiation spectrum analyzer. 14. A device for studying the electromagnetic field of secondary emitters according to claim 13, characterized in that the oscillating system, any of ten in the spectrum analyzer, contains five oscillatory bridges: 1, 2, 3, 4 and 5; each bridge contains a high-resistance R and four parallel oscillatory circuits: two with parameters L ₁ and C ₁ and two with parameters L ₂ and C ₂ , while the input of the oscillating system is connected in parallel with the five inputs of five bridges and with the third output of the oscillating system, the first the exits of the five bridges (1, 2, 3, 4 and 5) form the first exit, the second exits of the five bridges (1, 2, 3, 4 and 5) form the second exit; the input of each bridge is connected through terminal “c” through the second parallel oscillating circuit L ₂ and C ₂ , through terminal “a” with the first output of the bridge, and in parallel the point “c” is connected through the first parallel oscillating circuit L ₁ and C ₁ , through the terminal "B" with the second exit of the bridge; terminal “a” is connected via a high-resistance resistance R to terminal “b” and in parallel terminal “a” is connected through a first oscillating circuit L ₁ and C ₁ to terminal “d”, terminal “b” is connected through a parallel second oscillating circuit L ₂ and C ₂ connected to terminal “d”, terminal “d” is grounded; the first oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 1.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 2.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 3.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 4.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 5.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 6.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 7.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 8.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 9.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 9.9 kHz; the second oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 11.9 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 15.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 20.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 25.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 30.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 35.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 40.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 44.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 47.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 49.9 kHz; the third oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 52.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 58.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 62.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 68.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 72.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 78.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 82.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 88.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 92.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 98.1 kHz; the fourth oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 110.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 120.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 130.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 140.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 150.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 160.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 170.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 178.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 185.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 198.1 kHz; the fifth oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 210.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 230.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 250.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 270.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 290.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 310.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 330.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 350.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 370.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 390.1 kHz; the sixth oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 410.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 450.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 490.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 530.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 570.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 610.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 650.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 690.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 730.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 790.1 kHz; the seventh oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 810.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 830.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 850.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 870.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 890.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 910.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 930.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 950.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 970.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 990.1 kHz; the eighth oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 1100.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 1900.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 2900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 3900.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 4900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 5900.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 6900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 7900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 8900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 9900.1 kHz; the ninth oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 10100.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 10900.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 12900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 13900.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 14,900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 15,900.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 16,900.1 kHz, and the second parallel oscillatory circuit L ₂ and C _{2 at} 17,900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 18900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 19900.1 kHz; the tenth oscillatory system contains five bridges: the first bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 21100.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 23100.1 kHz; the second bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 25100.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 27900.1 kHz; the third bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 30,100.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 32,900.1 kHz; the fourth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 35100.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ at 37900.1 kHz; the fifth bridge with the first parallel oscillatory circuit L ₁ and C _{1 is} tuned to a frequency of 38,900.1 kHz, and the second parallel oscillatory circuit L ₂ and C ₂ is 39900.1 kHz. 15. The device for studying the electromagnetic field of the secondary emitters according to claim 14, characterized in that the unit for studying the spectrum of the secondary radiation contains a frequency spectrum analyzer and a switch Bk.1 for ten switching positions, while ten inputs of the block for studying the spectrum of secondary radiation are connected in parallel to ten terminals “A” of the switch Vk.1, and ten terminals “b” of the switch Vk.1 are connected in parallel to the input of the frequency spectrum analyzer. 16. The device for studying the electromagnetic field of secondary emitters according to claim 15, characterized in that the upper part of the high-voltage irradiating system contains N lines of emitters, from the first line to N line, each line of emitters contains twenty-eight isolation tanks C ₁ , twenty-eight flat emitting metal plates in each line and twenty-eight valves B1, while the first input of the upper high-voltage feed is connected in parallel with the first inputs of each of the N lines, from the first line to N line ; the second input of the upper high-voltage irradiator is connected in parallel with the second inputs of each of the N lines, from the first line in the N line; the third input of the upper high-voltage irradiator is connected in parallel with the third inputs of each of the N lines, from the first line in the N line; the fourth input of the upper high-voltage irradiator is connected in parallel with the fourth inputs of each of the N lines, from the first line in the N line; the fifth input of the upper high-voltage feed is connected in parallel with the fifth inputs of each of the N lines, from the first line to the N line; the sixth input of the upper high-voltage irradiator is connected in parallel with the sixth inputs of each of the N lines, from the first line to the N line; the seventh input of the upper high-voltage irradiator is connected in parallel with the seventh inputs of each of the N lines, from the first line in the N line; the eighth input of the upper high-voltage irradiator is connected in parallel with the eighth inputs of each of the N lines, from the first line to the N line; the ninth input of the upper high-voltage feed is connected in parallel with the ninth inputs of each of the N lines, from the first line to the N line; the tenth input of the upper high-voltage irradiator is connected in parallel with the tenth inputs of each of the N lines, from the first line in the N line; the twenty-ninth input of the upper high-voltage irradiator is connected in parallel with the twenty-ninth inputs from the first line in the N line; the first line of emitters consists of twenty eight flat radiating metal plates, from the first plate of twenty-eighth, twenty-eight valves and twenty-eight isolation tanks C ₁ , with each of the twenty-eight inputs, from the first to twenty-eighth inputs, of the first line are connected in parallel with twenty-eight outputs of the first line of emitters, and through terminal “b” each of the twenty-eight inputs is connected to its own flat radiating metal plate, from the first to twenty-eighth, through the capacitor B ₁ , the twenty-ninth input of the first line of emitters is connected in parallel with terminal “a” through a valve with its own flat radiating metal plate from the first to the twenty-eighth; the second and subsequent line of emitters, from the second line to line N, are structurally executed like the first line of emitters. 17. A device for studying the electromagnetic field of secondary emitters according to claim 16, characterized in that the lower part of the high-voltage irradiating system contains a grounded metal plate "A" connected to the input of the lower part of the high-voltage irradiating system, the dimensions of the grounded metal plate "A" are not less than the dimensions of the parts of a high voltage irradiation system. 18. A device for studying the electromagnetic field of secondary emitters according to claim 17, characterized in that the high voltage source containing six step-up transformers, from the first Tr. 1 to the sixth Tr. 6, five high-voltage rectifiers, consisting of a high-voltage BBB valve, filter inductance L _Ф and filter capacitance С _Ф , two switches Вк.1 and Вк.2, while the primary winding 1 of the first transformer Tr.1 is connected to a source of voltage of 220 volts, and the secondary winding 11 of the first transformer Tr.1 is connected to terminal “e”, and cl the capacitor “c” is connected in parallel with the five terminals “b” of the second switch Vk.2; terminal “a” of the first position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the second step-up transformer Tr.2, through terminal “d” the primary sheath 1 of the second step-up transformer Tr.2 is grounded, the secondary winding 11 of the second step-up transformer Tr.2 terminal "c" is connected to the terminal "b" of the first position of the first switch BK.1 through a high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal "d" of the secondary winding 11 of the second step-up transformer Tr.2 ; terminal “a” of the second position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the third step-up transformer Tr.3, through terminal “d” the primary sheath 1 of the third step-up transformer Tr.3 is grounded, the secondary winding 11 of the third step-up transformer Tr.3 terminal "c" is connected to terminal "b" of the second position of the first switch VK. 1 through the high-voltage valve BBB, through the filter inductances L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the third step-up transformer Tr. 3 is grounded; terminal “a” of the third position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the fourth step-up transformer Tr.4, through terminal “d” the primary sheath 1 of the fourth step-up transformer Tr.4 is grounded, the secondary winding 11 of the fourth step-up transformer Tr.4 terminal "c" is connected to a terminal "b" of the third position of the first switch valve via a high Vk.1 BBB through the filter inductance L _P and c _P filter capacitance terminal "d" of the secondary winding 11 of the fourth up transformer Tr.4 grounded; terminal “a” of the fourth position of the second switch Bk.2 is connected through terminal “c” to the primary winding of the fifth step-up transformer Tr.5, through terminal “e” the primary shell 1 of the fifth step-up transformer Tr.5 is grounded, the secondary winding 11 of the fifth step-up transformer Tr.5 terminal “c” is connected to terminal “b” of the fourth position of the first switch Vk.1 through a high-voltage valve BBB, through the inductance of the filter L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the fifth step-up transformer Tr.5 ; terminal “a” of the fifth position of the second switch Bk.2 is connected via terminal “c” to the primary winding 1 of the sixth step-up transformer Tr.6, through terminal “d” the primary sheath 1 of the sixth step-up transformer Tr.6 is grounded, the secondary winding 11 of the sixth step-up transformer Tr.6 terminal "c" is connected to terminal "b" of the fifth position of the first switch VK. 1 through the high-voltage BBB valve, through the filter inductances L _Ф and filter capacitance C _Ф , terminal “d” of the secondary winding 11 of the sixth step-up transformer Tr.5 is grounded; the terminals “a” of the first switch Vk.1 are connected in parallel with the first output of the high voltage source; the second output of the high voltage source is connected to the earth wire of the high voltage source.

Images