RU2791148C1 - Nuclear quadrupole resonance signal detection device - Google Patents

Abstract

FIELD: detection of nuclear quadrupole resonance signals.

SUBSTANCE: device for detecting nuclear quadrupole resonance signals additionally includes a control system for one-time and cyclic independent operation of frequency and time pulse generation units, a nuclear quadrupole resonance spectrum analysis unit with high weight and size characteristics, made on the basis of microcircuits: capacitance gyrators G_C and inductance gyrators G_L, an analytical unit of weak NQR signals, an ambient temperature control unit, whereas the output of the sweep frequency generator is connected to the first input of the operating mode selection unit through a frequency pulse shaper, through the first switch Vk.1, through its short-circuited terminals c and d, as well as the output of the sweep frequency generator is connected in parallel with the second input of the operating mode selection unit through the temporary pulse generator, through the second switch Vk.2, through its short-circuited terminals a and b; the third input of the operating mode selection unit is connected through the third switch Vk.3, through its short-circuited terminals d and e with the output of the unit for detecting the emission spectrum of nuclear quadrupole resonance signals; the output of the operating mode selection unit through the input of the power amplifier is connected in parallel with the input of the matching device of the transmitting system and through the n₁ input with the receiving system information generator; n outputs of the matching device of the transmitting system are connected to each of the n emitters, in the system of emitters 7, through the terminal g, starting from 7₁ to 7_N ; n inputs of the information generator of the receiving system are connected to N in-phase lines 6, for example, n inputs of the information generator are connected to the first in-phase receiving line from the first antenna 6₁₁ to n6_1N ; the output of the information generator of the receiving system is connected to a unit for detecting the emission spectrum of nuclear quadrupole resonance signals, through a filter unit and through a unit for analysing the emission spectrum of nuclear quadrupole resonance signals; the output of the filter unit is connected in parallel with the first input of the analytical unit of weak NQR signals, and the second input of the analytical unit of weak NQR signals is connected to the output of the ambient temperature control unit, the output of the analytical unit is connected to the terminal d of the third switch Vk.3 of the third input of the mode selection unit work; the radiating part of the device for detecting emitters of nuclear quadrupole resonance radiation is placed between two shielding planes made in the form of truncated cylindrical planes.

EFFECT: reduced weight and size characteristics of the device, as well as increased reliability of the analysis of the frequency properties of weak radiated NQR fields.

29 cl, 41 dwg

Description

The invention relates to the field of detection and recognition of substances by the method of nuclear quadrupole resonance (NQR) and can be used to solve the problem of searching and identifying explosives, drugs and biological agents located in various environments. The device contains a swept frequency generator, a clock pulse generator, a shaper, transmitting and receiving antenna systems, a filter unit, a radiation spectrum analysis unit, a secondary radiation spectrum study unit. The technical result consists in automating the analysis of the frequency properties of the secondary radiation field, the objects under study and monitoring their levels, reducing the weight and size characteristics of the device.

Known "Method for detecting moving electrically conductive objects", patent 2303290 RU G08B 13/24 dated 20.07.2007. The invention relates to the field of security and is intended to detect moving electrically conductive objects. It consists of a generator that excites the radiation of an electromagnetic field with the help of an antenna system. To register excited currents in moving electrically conductive objects, receiving antenna systems connected to the recording equipment are used. However, it cannot be used for non-moving objects and non-conductive media, nor can it determine the parameters of the secondary radiation, such as the frequency of the secondary radiator, the polarization of the vector and the field level.

Known "Device for the simultaneous detection of several explosives and drugs in luggage", patent 2128832 RU G01N 24/00, G01R 33/20 dated 10.04.1999. The device contains a reference frequency unit, a receiver and an accumulator, a nuclear quadrupole resonance frequency synthesizer unit, and an adjustable switch. However, it cannot be used to determine the parameters of the secondary radiation, such as the frequency of the secondary radiator, the polarization of the vector and the field level.

Patents are known 2165105 RU, 2010102971 RU, 2157002 RU, 98107128 RU, 2205386 RU, 2303290 RU, 2128832 RU, 2595797 RU, 2697023 RU dated 08.08.2019, No. 2757363 of 10.10.2021 G01N 24/00, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N, G01N. /20, G01R29/08. The device contains blocks for determining the frequencies of nuclear quadrupole resonance. However, it cannot be used to determine the parameters of the secondary radiation, such as the frequency of the secondary radiator, the polarization of the vector and the field level.

The base object can be the “Nuclear quadrupole resonance signal detection device”, patent for invention No. 2757363 dated 10/14/2021 according to application No. 2020138510 dated 11/23/2020.

The device for detecting nuclear quadrupole resonance signals contains: a sweep frequency generator, a power amplifier and a matching device, a frequency pulse shaper, a time pulse shaper, a multi-frequency in-phase receiving antenna system, a multi-frequency in-phase transmitting antenna system, a receiving system information shaper, a filter unit, a nuclear spectrum analysis unit quadrupole resonance of radiation, a block for studying the spectrum of nuclear quadrupole resonance of radiation. The base object has the following disadvantages:

- there is no continuous, cyclic operation of frequency pulse shapers, and time pulses, because Implemented a one-time launch by buttons Kn.1, Kn.2, Kn.3 and Kn.4 of the blocks of the frequency pulse shaper and the time pulse shaper, which gives a short cycle of work for the analysis of NQR in media;

- qualitatively low mobility of the device due to very low weight and size characteristics of the oscillatory systems of the filter unit and the signal emission spectrum analysis unit;

- there is no secondary analysis of the products of a weak radiated field excited on the basis of nuclear quadrupole resonance and the use of the detected frequencies to enhance the quadrupole resonance;

- there is no possibility of assessing weak NQR fields and there is no analysis of measurements of the radiated field of nuclear quadrupole resonance, taking into account the ambient temperature.

The purpose of the present invention is:

- development of joint and independent one-time and cyclic operation of blocks: formation of frequency impulses 2 and formation of time impulses 3;

- increasing the weight and size characteristics of the device based on the replacement in bandpass filters from 10.1 to 10.10 and in oscillatory systems from 11.1 to 11.10, built on the use of traditional capacitance and inductance with low weight and size characteristics, microcircuits called gyrators: capacitive gyrator G _C and inductive gyrator G _L ;

- increasing the efficiency of the analysis of the frequency properties of weak radiated fields of the objects under study and their levels based on the introduction of feedback, which ensures the detection of quadrupole resonance frequencies and their use for excitation in the studied media, taking into account the temperature of the media.

Thus, the electromagnetic field source appears to be distributed over the surface and creates directed radiation with a normally polarized wave and a uniform electromagnetic field of NQR excitation in media in the presence of feedback, due to which the NQR frequencies are set and they are applicable to the field exciter in the volume.

To achieve this goal, a device consisting of a swept frequency generator 1, a power amplifier 5.1, a matching device 5.2, frequency pulse generators 2 and time 3, an information generator of the receiving system 9, a filter unit 10, a signal emission spectrum analysis unit 11 and a spectrum research unit radiation signals of quadrupole resonance 12, multi-frequency in-phase receiving antenna system with the reception of normally and parallel polarized electromagnetic waves with uniform energy in the range of 10 kHz. up to 10 MHz. 6 _NN , a 7 _nn multi-frequency in-phase transmitting antenna system emitting a normally polarized wave with uniform energy in the range from 10 kHz. up to 10 MHz, additionally introduced: control system for cyclic operation of frequency 2 and time 3 pulse forming units; oscillatory systems from 11.1 to 11.10 with high weight and size characteristics, are made on the basis of microcircuits: capacitance gyrators G _C and inductance gyrators G _L , analytical unit 13 of weak NQR signals, ambient temperature control unit 14.

The gyrator as an impedance converter is used to replace the capacitance C and inductance L with high weight and size characteristics. So the capacitance C connected as a load of the microcircuit at the input of the latter creates an inductive resistance L and is defined as Г _L. And vice versa, when connected as a load for the microcircuit, the inductance L at the input of the latter creates a capacitance C and is defined as G _C. The principle of operation of the impedance converter (gyrator) is presented in the literature of the authors W. Titze, K. Schenk "Semiconductor circuitry", - M: ed. World, 1983, section 12.6, pp. 180-183. The principle of controlling the change in inductive resistance at the output of the gyrator is shown in the Radio magazine No. 11, 1996, by the author Petin G.P. "Application of the gyrator in resonant amplifiers and generators".

On FIG. 1 shows a device for detecting nuclear quadrupole resonance signals, where 1 is a sweep frequency generator for a frequency range from 10 kHz to 10 MHz, 2 is a frequency pulse shaper, 3 is a temporary pulse shaper, 4 is an operating mode selection unit, 5.1 is a power amplifier, 5.2 - a matching device of the transmitting antenna system, 6 - in-phase receiving antenna system with reception of normally and parallel polarized electromagnetic waves, containing N in-phase receiving lines from 6 _1N to 6 _NN , each of the N in-phase receiving lines contains N receiving antennas (for example, the first in-phase receiving the ruler contains from the first 6 ₁₁ to N antenna 6 _1N ), 7 - transmitting in-phase antenna system with normally polarized wave radiation, containing N emitters from 7 ₁ to 7 _N , 8 - detection object, 9 - information generator of the receiving antenna system, 10 - block of filters, 11 - block for analyzing the spectrum of nuclear quadrupole resonance of radiation, 12 - block for studying the spectrum ra radiation signals of nuclear quadrupole resonance, 13 - analytical unit of weak NQR signals, ambient temperature control unit 14, while the output of the sweeping frequency generator 1 is connected to the first input of the operating mode selection unit 4 through the frequency pulse shaper 2, through the terminals "c" and "g" of the first switch Vk.1, and with the second input of the operating mode selection block 4, the output of the sweep frequency generator 1 is connected through the generator of temporary pulses 3, through the terminals "a" and "b", the second switch Vk.2, and the third input of the block operating mode selection 4 is connected directly to the output of the analytical block of weak NQR signals 13, and through the terminals "d" and "e" of the third switch Vk.3 with the output of the block for studying the emission spectrum of signals of nuclear quadrupole resonance 12; the input of the operating mode selection block 4 is connected to the input of the power amplifier 5.1; the output of the power amplifier 5.1 is connected in parallel with the input of the matching device of the transmitting antenna system 5.2 and through the "n ₁ " input with the driver information of the receiving system 9; "n" outputs of the matching device of the transmitting antenna system 5.2 are connected to each of the "n" emitter systems 7 through the "g" terminal, starting from 7 ₁ to 7 _N ; "n" inputs of the information generator of the receiving antenna system 9 are connected to N in-phase lines 6, for example, "n" inputs of the information generator of the receiving antenna system 9 are connected to the first in-phase receiving line from the first antenna 6 ₁₁ to "n" 6 _1N ; the output of the information generator of the receiving antenna system 9 is connected to the block for studying the radiation spectrum of the nuclear quadrupole resonance signals 12 through the filter block 10 and, through the block for analyzing the radiation spectrum of the signals of the nuclear quadrupole resonance 11; the filter unit 10 is connected in parallel with the first input of the analytical unit of weak NQR signals 13, and the second input of the analytical unit of weak NQR signals 13 is connected to the output of the ambient temperature control unit 14; the radiating part of the device for detecting emitters of nuclear quadrupole resonance radiation is placed between two shielding planes made in the form of truncated cylindrical planes.

On FIG. 2.1 shows the graphs of the reflection coefficient P _II of a parallel polarized electromagnetic wave when it falls from air onto a medium with magnetic properties of change and shows its complete reflection of the wave from the interface between the media.

On FIG. 2.2 shows the graphs of the reflection coefficient P _⊥ of a normally polarized electromagnetic wave when it falls from air onto a medium with magnetic properties and shows the almost complete refraction of the wave into the second medium.

On FIG. 2.3 shows graphs of the refractive index N _{⊥ of} a normally polarized electromagnetic wave when it falls from air onto a medium with magnetic properties and shows the complete refraction of the wave into the second medium.

On FIG. 3 shows one of the identical emitters 7 ₁ of the transmitting in-phase antenna system, which excites a normally polarized electromagnetic wave with the vectors Er and Hr near the air-surface interface of the medium under study with both conventional and magnetic properties 7, containing F1 and F2 - two ferrite cores cylindrical shape, located horizontally and forming a single emitter of a normally polarized wave, K1 and K2 - two frame transmitting antennas with uniform frequency properties of the input impedance in the frequency range from 10 kHz to 10 MHz, placed on ferrite cores F1 and F2, and exciting the magnetic flux in ferrite; a matching transformer Tr.1 with one primary 1 and two secondary windings 2.1 and 2.2, a matching device of the transmission system 5, while the matching transformer Tr.1 is connected by the primary winding to one of the outputs of the matching device of the transmission system 5; and the secondary winding of the transformer Tr.1 is two-section: the first section 2.1 is connected by terminal "a" to the terminal "g1" of the first loop transmitting antenna K1, and by terminal "b" the first section 2.1 is connected to the terminal "g2" of the first loop transmitting antenna K1; the second section 2.2 of the transformer Tr.1 is connected by terminal "g" to the terminal "g3" of the second loop transmitting antenna K2, and by terminal "c" the second section 2.2 is connected to the terminal "g4" of the second loop transmitting antenna K2.

On FIG. 4 shows the structure of the emitter Ф1 (Ф2), as one of the elements in each of N emitters, containing three ferrite cores, each with a diameter of d=4 mm, made using the technology of a three-component structure with magnetic permeability μ=1000, μ=100 and μ=10; on top of three ferrite cores, coils of conductors of three windings Ob.1, Ob.2 and Ob.3 of the loop antenna are placed, with a conductor cross section of 0.5 mm, 35 turns are located on each core with a length of l \u003d 3 cm, and all three loop antennas are connected in series and form a single circuit with a spatially unidirectional current i flowing between the terminals "g1" and "g2"; moreover, all three loop antennas with ferrite cores form a single radiator, shown in Fig. 3 as F1 or F2.

On FIG. 5 shows graphs of the input resistance of the emitter Ф1 (Ф2), and curve 1 shows the change in the input resistance in the frequency range from 10 kHz to 10 MHz for three ferrite cores, each with a cross-sectional diameter of d=4 mm, made using the technology of a three-component structure with a magnetic permeability μ=1000, μ=100 and μ=10, on top of three ferrite cores are coils of conductors of three windings 06.1, 06.2 and Ob. turns, and all three loop antennas are connected in series and form a single circuit with a spatially unidirectional current r flowing between the terminals "g1" and "g2", a change in the input resistance in the frequency range is permissible; and curve 2 shows the change in the input resistance in the frequency range from 10 kHz to 10 MHz for three ferrite cores, each with a cross-sectional diameter of d=4 mm, made using the technology of a three-component structure with magnetic permeability μ=1000, μ=100 and μ=10 , on top of three ferrite cores, coils of conductors of three windings Ob.1, Ob.2 and Ob.3 of the loop antenna are placed, with a conductor cross section of 0.5 mm, 100 turns are located on each core with a length of l \u003d 3 cm, this option for changing the input resistance in frequency range is not allowed.

On FIG. 6 shows a receiving antenna element containing three loop antennas with ferrite cores, all three loop antennas being connected in series and forming a single circuit with an induced current in them, spatially unidirectional i, flowing between terminals "P1" and "P2"; three ferrite cores, each with a diameter of d=4 mm, made according to the technology of a three-component structure with magnetic permeability μ=1000, μ=100 and μ=10; on top of three ferrite cores, coils of conductors of three windings of a loop antenna are placed, with a conductor cross section of 0.5 mm, 35 turns are located on each core with a length of l \u003d 3 cm, and all three loop antennas are connected in series and placed in a vertical plane with a separation angle of 60 ° between loop antennas with ferrite cores.

On FIG. 7 shows a receiving antenna of circular polarization 6 ₁₁ containing two elements of the receiving antenna 6 ₁₁ .1 and 6 ₁₁ .2, as elements of a system consisting of N receiving antennas in each line from the first 6 ₁₁ to 6 _1N and N lines in the system from the first 6 _1N by 6 _NN , while each element, for example, 6 ₁₁ .1 has three loop antennas with ferrite cores, and three loop antennas A1, A2 and A3 are connected in series and form a single circuit with an induced current in them, spatially unidirectional flowing between the terminals "P1" and "P2", and in element 6 _11.2 three loop antennas A4, A5 and A6 are connected in series and form a single circuit with an induced current in them, spatially unidirectional i, flowing between the terminals "P3" and "P4 »; six loop antennas with ferrite cores A1, A2, A3, A4, A5 and A6 are located in a vertical plane and form a circular polarization reception, including the reception of both a normally polarized wave on the loop antennas A2 and A5, and a parallel polarized wave on the loop antennas A1, A3, A4 and A6; moreover, radio reception is carried out simultaneously by elements 6 ₁₁ .1 and 6 ₁₁ .2 based on the operation of the summing transformer Tr.1 containing one primary winding 1 and two secondary windings, while the primary winding is connected to the input terminals of the information generator of the receiving system 9, at the same time the first secondary winding 2 ₁ transformer Tr.1 terminal "a" is connected to the terminal "P1", and terminal "b" to the terminal "P2" element 6 _11.1 , the second secondary winding 2 ₂ transformers Tr.1 terminal "c" is connected to the terminal "P4" ”, and the terminal “e” to the terminal “P3” of element 6 ₁₁ .2.

On FIG. 8 shows a transceiver antenna system, where 6 are elements of a receiving antenna system consisting of N receiving antennas in each line from the first 6 ₁₁ to 6 _1N and N lines in the system from the first 6 _1N to 6 _NN ; in addition, 7 - elements of the transmitting antenna system containing N emitters from the first 7 ₁ to N - 7 _N .

On FIG. 9 shows a frequency pulse shaper 2, where the first shaper of groups of one-millisecond frequency pulses 2.1, the second shaper of groups of two-millisecond frequency pulses 2.2, the third shaper of groups of three-millisecond frequency pulses 2.3, the fourth shaper of groups of four-millisecond frequency pulses 2.4, the generator of one-millisecond pulses 2.5, four four-contact switches: Vk .1, Vk.2, Vk.3 and Vk.4; four elements of AND: the first 2.6, the second 2.7, the third 2.8 and the fourth 2.9; four buttons for a one-time start of the work of four shapers: Kn.1, Kn.2, Kn.3 and Kn.4; while the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the first element And 2.6 and to the second input of the first element And 2.6 through the first button Kn.1 for a one-time start of the first generator, the output of the first element And 2.6 is connected to the first input of the first group generator one-millisecond frequency pulses 2.1, the first output of the first shaper of groups of one-millisecond frequency pulses 2.1 is connected to the output of the shaper of frequency pulses 2 through the terminals "c" and "e" of the first four-pin switch Vk.1, the second output of the first shaper of groups of one-millisecond frequency pulses 2.1 is connected to the second input the first element And 2.6 through the terminals "a" and "b" of the first four-contact switch Vk.1 for cyclic operation of the first shaper; the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the second element And 2.7 and to the second input of the second element And 2.7 through the second button Kn. pulses 2.2, the first output of the second generator of groups of two-millisecond frequency impulses 2.2 is connected to the output of the generator of frequency impulses 2 through the terminals "c" and "d" of the second four-pin switch Vk.2, the second output of the second generator of groups of two-millisecond frequency impulses 2.2 is connected to the second input of the second element And 2.7 through terminals "a" and "b" of the second four-contact switch Vk.2 for cyclic operation of the second shaper; the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the third element And 2.8 and to the second input of the third element And 2.8 through the third button Kn. pulses 2.3, the first output of the third generator of groups of three-millisecond frequency impulses 2.3 is connected to the output of the generator of frequency impulses 2 through the terminals "c" and "d" of the third four-pin switch Vk.3, the second output of the third generator of groups of three-millisecond frequency impulses 2.3 is connected to the second input of the third element And 2.8 through the terminals "a" and "b" of the third four-contact switch Vk.3 for cyclic operation of the third shaper; the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the fourth element And 2.9 and to the second input of the fourth element And 2.9 through the fourth button Kn. pulses 2.4, the first output of the fourth generator of groups of four-millisecond frequency impulses 2.4 is connected to the output of the generator of frequency impulses 2 through the terminals "c" and "d" of the fourth four-pin switch Vk.4, the second output of the fourth generator of groups of four-millisecond frequency impulses 2.4 is connected to the second input of the fourth element And 2.9 through the terminals "a" and "b" of the fourth four-contact switch Vk.4 for cyclic operation of the fourth shaper; the input of the frequency pulse shaper 2 is connected in parallel with the second input of the first shaper of groups of one-millisecond frequency pulses 2.1, with the second input of the second shaper of groups of two-millisecond frequency pulses 2.2, with the second input of the third shaper of groups of three-millisecond frequency pulses 2.3 and with the second input of the fourth shaper of groups of four-millisecond frequency pulses 2.4 .

On FIG. 10 shows the first generator of groups of one-millisecond frequency pulses 2.1, where the first gate B.1, the second gate B.2, the third gate B.3, the fourth gate B.4, the fifth gate B.5, the sixth gate B.6, the seventh gate B .7, eighth gate B.8, ninth gate B.9, tenth gate B.10, first delay line for 2 ms 15.1, second delay line for 2 ms 15.2, third delay line for 4 ms 16, fourth delay line for 2 ms 15.3, fifth delay line for 4 ms 17, one-millisecond trigger 18, sixth delay line for 8 ms 19, seventh delay line for 10 ms 20, first element AND 21.1, second element AND 21.2, frequency multiplier by two button Kn.1 (Fig. 9), to start the one-millisecond trigger 18, for a short time, the one-millisecond pulse generator 2.5 of the frequency pulse shaper 2 is connected to the first input of the first shaper of groups of one-millisecond frequency pulses 2.1, the first input is connected to the input of the one-millisecond trigger 18; the output of the one-millisecond trigger 18 is connected in parallel with the input of the sixth delay line for 8 ms 19, and through the first gate B.1, through the first delay line for 2 ms 15.1 with the second input of the first element AND 21.1, also through the second gate B.2 with the second input the first element AND 21.1; the output of the sixth delay line for 8 ms 19 is connected in parallel with the input of the seventh delay line for 10 ms 20, and through the third gate B.3 and through the second delay line for 2 ms 15.2 with the second input of the second element And 21.2, also through the fourth gate B. 4 and through the third delay line for 4 ms 16 with the second input of the first element And 21.1, as well as through the fifth gate B.5 with the second input of the first element And 21.1; the output of the seventh delay line for 10 ms 20 is connected in parallel through the sixth gate B.6 through the fourth delay line for 2 ms 15.3 with the second input of the first element AND 21.1, and through the seventh gate B.7 and through the fifth delay line for 4 ms 17 in parallel through the ninth gate B.9 with the second input of the second element And 21.2, and through the tenth gate B. 10 with the second output of the first generator of groups of one-millisecond frequency pulses 2.1, in addition, the output of the seventh delay line for 10 ms 20 is connected through the eighth gate B.8 with the second input of the second element And 21.2; the output of the second element And 21.2 connected to the first output of the first shaper groups of one-millisecond frequency pulses 2.1; the second input of the first generator of groups of one-millisecond frequency pulses 2.1 is connected in parallel with the first input of the first element And 21.1 and through a frequency multiplier by two 22 with the first input of the second element And 21.2; the output of the first element And 21.1 connected to the first output of the first shaper groups of one-millisecond frequency pulses 2.1.

On FIG. 11 shows the distribution of pulses and their duration, which are formed by the first group generator of one-millisecond frequency pulses 2.1, where the duration of all pulses generated by the first group generator of one-millisecond groups with frequency filling of pulses corresponds to τ = 1 ms, and three groups of pulses are formed: the first group is two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 12 shows the second generator of groups of two-millisecond frequency pulses 2.2, where the eleventh gate B.11, the twelfth gate B.12, the thirteenth gate B.13, the fourteenth gate B.14, the fifteenth gate B.15, the sixteenth gate B.16, the seventeenth gate B .17, eighteenth gate B.18, nineteenth gate 19, twentieth gate B.20, first delay line for 3 ms 23, second delay line for 3 ms 24, third delay line for 6 ms 25, fourth delay line for 3 ms 26 , fifth delay line for 6 ms 27, two-millisecond trigger 28, sixth delay line for 10 ms 29, seventh delay line for 13 ms 30, first element AND 31.1, second element AND 31.2, frequency multiplier by two 32, with the second button Kn.2 (Fig. 9) trigger two-millisecond trigger 28 for a short time generator 2.5 is connected to the first input of the second shaper groups of two-millisecond frequency pulses 2.2, the first input of the second shaper groups of two-millisecond frequency pulses 2.2 s connected to 2ms trigger input 28; the output of the two-millisecond trigger 28 is connected in parallel with the input of the sixth delay line for 10 ms 29, and through the eleventh gate B.11 and through the first delay line for 3 ms 23 with the second input of the first element AND 31.1, also the output of the two-millisecond trigger 28 is connected through the twelfth gate B .12 with the second input of the first element AND 31.1; the output of the sixth delay line for 10 ms 29 is connected in parallel with the input of the seventh delay line for 13 ms 30, and through the thirteenth gate B.13 and through the second delay line for 3 ms 24 with the second input of the second element And 31.2; also, the output of the sixth delay line for 10 ms 29 is connected through the fourteenth gate B.14 and through the third delay line for 6 ms 25 with the second input of the first element And 31.1, and the output of the sixth delay line for 10 ms 29 is connected through the fifteenth gate B.15 with the second input of the first element And 31.1; the output of the seventh delay line for 13 ms 30 is connected in parallel through the sixteenth gate B.16 and through the fourth delay line for 3 ms 26 with the second input of the first element AND 31.1, also the output of the seventh delay line for 13 ms 30 through the eighteenth gate B.18 is connected to the second input of the second element And 31.2, and the output of the seventh delay line for 13 ms 30 is connected through the seventeenth gate B.17 and through the fifth delay line for 6 ms 27 in parallel: through the nineteenth gate B.19 with the second input of the second element And 31.2, and through the twentieth valve 20 with the second output of the second shaper groups of two millisecond frequency pulses 2.2; the output of the second element And 31.2 is connected to the first output of the second generator groups of two-millisecond frequency pulses 2.2; the second input of the second shaper of groups of two-millisecond frequency pulses 2.2 is connected in parallel with the first input of the first element And 31.1 and also through a frequency multiplier by two 32 with the first input of the second element And 31.2; the output of the first element And 31.1 is connected to the first output of the second generator groups of two-millisecond frequency pulses 2.2.

On FIG. 13 shows the temporal distribution of pulses and their duration, which are formed by the second generator of groups of two-millisecond frequency pulses 2.2, where the duration of all pulses created by the second group generator are two-millisecond with frequency filling of pulses, i.e. corresponds to τ=2 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 14 shows the third generator of groups of three-millisecond frequency pulses 2.3, where the twenty-first gate B.21, the twenty-second gate B.22, the twenty-third gate B.23, the twenty-fourth gate B.24, the twenty-fifth gate B.25, the twenty-sixth gate B .26, twenty-seventh gate B.27, twenty-eighth gate B.28, twenty-ninth gate B.29, thirtieth gate 30, first delay line for 4 ms 33, second delay line for 4 ms 34, third delay line for 8 ms 35, fourth delay line for 4 ms 36, fifth delay line for 8 ms 37, sixth delay line for 12 ms 39, seventh delay line for 16 ms 40, three millisecond trigger 38, first element AND 41.1, second element AND 41.2, frequency multiplier by two 42, while the third button Kn.3 (Fig. 9) trigger three-millisecond trigger 38 for a short time generator of one-millisecond pulses 2.5 shaper 2 is connected to the first input of the third shaper groups of three-millisecond frequency pulses 2.3, the first th input of the third shaper groups of three-millisecond frequency pulses 2.3 is connected to the input of the three-millisecond trigger 38; the output of the three-millisecond trigger 38 is connected in parallel with the input of the sixth delay line for 12 ms 39, and through the twenty-first gate B.21 and through the first delay line for 4 ms 33 with the second input of the first element And 41.1; in parallel, the output of the three-millisecond trigger 38 is connected through the twenty-second gate B.22 to the second input of the first element And 41.1; the output of the sixth delay line for 12 ms 39 is connected in parallel with the input of the seventh delay line for 16 ms 40, in parallel the output of the sixth delay line for 12 ms 39 through the twenty-third gate B.23 and through the second delay line for 4 ms 34 is connected to the second input of the second element And 41.2, also the output of the sixth delay line for 12 ms 39 is connected through the twenty-fourth gate B.24 and through the third delay line for 8 ms 35 with the second input of the first element And 41.1, as well as the output of the sixth delay line for 12 ms 39 is connected through twenty-fifth valve B.25 with the second input of the first element And 41.1; the output of the seventh delay line for 16 ms 40 is connected in parallel through the twenty-sixth gate B.26 and through the fourth delay line for 4 ms 36 with the second input of the first element And 41.1, and the output of the seventh delay line for 16 ms 40 is connected through the twenty-seventh gate B. 27, through the fifth delay line for 8 ms 37 in parallel: through the twenty-ninth gate B.29 with the second input of the second element And 41.2, and through the thirtieth gate 30 with the second output of the third generator of groups of three-millisecond frequency pulses 2.3; in addition, the output of the seventh delay line for 16 ms 40 is connected through the twenty-eighth gate B.28 with the second input of the second element And 41.2; the output of the second element And 41.2 connected to the first output of the third shaper groups of three-millisecond frequency pulses 2.3; the second input of the third shaper of groups of three-millisecond frequency pulses 2.3 is connected in parallel with the first input of the first element And 41.1 and also through a frequency multiplier by two 42 with the first input of the second element And 41.2; the output of the first element And 41.1 is connected to the first output of the third shaper groups of three-millisecond frequency pulses 2.3.

On FIG. 15 shows the temporal distribution of pulses and their duration, which are generated by the third generator of groups of three-millisecond frequency pulses 2.3, where the duration of all pulses created by the third generator of groups are three-millisecond with frequency filling of pulses, i.e. corresponds to τ=3 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 16 shows the fourth generator of groups of four-millisecond frequency pulses 2.4, where the thirty-first gate B.31, the thirty-second gate B.32, the thirty-third gate B.33, the thirty-fourth gate B.34, the thirty-fifth gate B.35, the thirty-sixth gate B .36, thirty-seventh gate B.37, thirty-eighth gate B.38, thirty-ninth gate B.39, fortieth gate B.40 first delay line for 5 ms 43, second delay line for 5 ms 44, third delay line for 10 ms 45, fourth delay line for 5 ms 46, fifth delay line for 10 ms 47, four millisecond trigger 48, sixth delay line for 14 ms 49, seventh delay line for 19 ms 50, first element AND 51.1, second element AND 51.2, multiplier frequency by two 52, while the fourth button Kn.4 (Fig. 9) launching the four-millisecond trigger 48 for a short time, the one-millisecond pulse generator 2.5 of the shaper 2 is connected to the first input of the fourth shaper of the four-millisecond frequency groups th pulses 2.4, the first input of the fourth generator of groups of four-millisecond frequency pulses 2.4 is connected to the input of a four-millisecond trigger 48; the output of the four-millisecond trigger 48 is connected in parallel with the input of the sixth delay line for 14 ms 49, and through the thirty-first gate B.31 and through the first delay line for 5 ms 43 with the second input of the first element And 51.1, also the output of the four-millisecond trigger 48 is connected through the thirty-second valve B.32 with the second input of the first element And 51.1; the output of the sixth delay line for 14 ms 49 is connected in parallel with the input of the seventh delay line for 19 ms 50, and the output of the sixth delay line for 14 ms 49 through the thirty-third gate B.33 and through the second delay line for 5 ms 44 is connected to the second input the second element And 51.2; also the output of the sixth delay line for 14 ms 49 is connected through the thirty-fourth gate B.34 and through the third delay line for 10 ms 45 with the second input of the first element And 51.1; and also the output of the sixth delay line for 14 ms 49 is connected through the thirty-fifth gate B.35 with the second input of the first element And 51.1; the output of the seventh delay line for 19 ms 50 is connected in parallel through the thirty-sixth gate B.36 and through the fourth delay line for 5 ms 46 with the second input of the first element And 51.1, and the output of the seventh delay line for 19 ms 50 is connected through the thirty-seventh gate B. 37 and through the fourth delay line for 10 ms 47 in parallel: through the thirty-ninth gate B.39 with the second output of the second element And 51.2, and through the fortieth gate B.40 with the second output of the fourth generator of groups of four-millisecond frequency pulses 2.4; in addition, the output of the seventh delay line for 19 ms 50 is connected through the thirty-eighth gate B.38 with the second input of the second element And 51.2; the output of the second element And 51.2 is connected to the output of the fourth generator groups of four-millisecond frequency pulses 2.4; the second input of the fourth generator groups of four-millisecond frequency pulses 2.4 is connected in parallel with the first input of the first element And 51.1 and also through a frequency multiplier by two 52 with the first input of the second element And 51.2; the output of the first element And 51.1 is connected to the first output of the fourth generator groups of four-millisecond frequency pulses 2.4.

On FIG. 17 shows the temporal distribution of pulses and their duration, which are formed by the fourth generator of groups of four-millisecond frequency pulses 2.4, corresponds to τ=4 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 Hz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 18 shows a temporary pulse shaper 3, where the first shaper of groups of one- and two-millisecond pulses 3.1, the second shaper of groups of two- and four-millisecond pulses 3.2, the third shaper of groups of three- and six-millisecond pulses 3.3, the fourth shaper of groups of four- and eight-millisecond pulses 3.4, the generator of one-millisecond impulses 3.5, four four-contact switches: Vk.1, Vk.2, Vk.3 and Vk.4; four elements of AND: the first 3.6, the second 3.7, the third 3.8 and the fourth 3.9; four buttons for a one-time start of the work of four shapers: Kn.1, Kn.2, Kn.3 and Kn.4; while the output of the one-millisecond pulse generator 3.5 is connected to the first input of the first generator of groups of one- and two-millisecond pulses 3.1 through the first input of the first element And 3.6, in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the first element And 3.6 through the first button Kn.1 for a one-time start the operation of the first shaper 3.1, the first output of the first shaper of groups of one- and two-millisecond pulses 3.1 is connected to the output of the shaper of temporary pulses 3 through the terminals "c" and "d" of the first four-pin switch Vk.1, and the second output of the first shaper of groups of one- and two-millisecond pulses 3.1 is connected to the second input of the first element And 3.6 through terminals "a" and "b" of the first four-contact switch Vk.1 for cyclic operation of the first shaper of groups of one- and two-millisecond pulses 3.1; the output of the one-millisecond pulse generator 3.5 is connected to the first input of the second generator of groups of two- and four-millisecond pulses 3.2 through the first input of the second element And 3.7, and in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the second element And 3.7 through the second button Kn.2 for a one-time start the operation of the second generator 3.2, the first output of the second generator of groups of two- and four-millisecond pulses 3.2 is connected to the output of the generator of temporary impulses 3 through the terminals "c" and "d" of the second four-contact switch Vk.2, and the second output of the second generator of groups of two- and four-millisecond pulses 3.2 is connected to the second input of the second element And 3.7 through the terminals "a" and "b" of the second four-contact switch Vk.2 for cyclic operation of the second shaper of groups of two- and four-millisecond pulses 3.2; the output of the one-millisecond pulse generator 3.5 is connected to the first input of the third generator of groups of three- and six-millisecond pulses 3.3 through the first input of the third element And 3.8, in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the third element And 3.8 through the third button Kn.3 for a one-time start of work of the third shaper 3.3, the first output of the third shaper of groups of three- and six-millisecond pulses 3.3 is connected to the output of the shaper of temporary pulses 3 through the terminals "c" and "d" of the third four-pin switch Vk.3, and the second output of the third shaper of groups of three- and six-millisecond pulses 3.3 connected to the second input of the third element And 3.8 through the terminals "a" and "b" of the third four-contact switch Vk.3 for cyclic operation of the third shaper of groups of three- and six-millisecond pulses 3.2; the output of the one-millisecond pulse generator 3.5 is connected to the first input of the fourth generator of groups of four- and eight-millisecond pulses 3.4 through the first input of the fourth element And 3.9, in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the fourth element And 3.9 through the fourth button Kn. shaper 3.4, the first output of the fourth shaper of groups of four- and eight-millisecond pulses 3.4 is connected to the output of the shaper of temporary pulses 3 through the terminals "c" and "e" of the fourth four-pin switch Vk.4, and the second output of the fourth shaper of groups of four- and eight-millisecond pulses 3.4 is connected with the second input of the fourth element AND 3.9 through terminals "a" and "b" of the fourth four-contact switch Vk.4 for cyclic operation of the fourth generator of groups of four- and eight-millisecond pulses 3.4.; the input of the temporary pulse shaper 3 is connected in parallel with the second input of the first shaper of groups of one- and two-millisecond pulses 3.1, with the second input of the second shaper of groups of two- and four-millisecond pulses 3.2, with the second input of the third shaper of groups of three- and six-millisecond pulses 3.3 and with the second input of the fourth shaper of groups of four- and eight-millisecond pulses 3.4.

On FIG. 19 shows the first generator of groups of one and two millisecond pulses 3.1, where the first gate is B.41, the second gate is B.42, the third gate is B.43, the fourth gate is B.44, the fifth gate is B.45, the sixth gate is B.46, the seventh gate B.47, eighth gate B.48, ninth gate B.49, first delay line by 2 ms. 53, the second delay line for 8ms 54, the third delay line for 13ms 55, the fourth delay line for 22ms 56, the fifth delay line for 10ms 57, the sixth delay line for 19ms 58, the seventh delay line for 10ms 60, the first trigger for 1 ms 59, the second trigger for 2 ms 61, element AND 62; while the first button Kn.1 (Fig. 18) to run the first trigger one-millisecond 1 ms 59 for a short time, the one-millisecond pulse generator 3.5 of the shaper 3 is connected to the first input of the first shaper groups of one- and two-millisecond pulses 3.1; the first input of the first shaper groups of one and two millisecond pulses 3.1 connected to the input of the first trigger one millisecond 1 ms 59; the output of the first trigger of one millisecond 1 ms 59 is connected in parallel on five lines with the second input of the element And 62: on the first line through the first gate B.41; on the second line - through the first delay line for 2 ms 53 and through the second gate B.42; on the third line - through the seventh delay line for 10 ms 60 and through the third gate B.43; on the fourth line through the seventh delay line for 10 ms 60, the second delay line for 8 ms 54 and through the fourth gate B.44; on the fifth line - through the seventh delay line for 10 ms 60, through the third delay line for 13 ms 55 and through the fifth gate 45; the output of the seventh delay line for 10 ms 60 is connected to the second trigger for 2 ms 61; the output of the second trigger for 2 ms 61 is connected in three lines with the second input of the element And 62: on the first line through the fourth delay line for 22 ms 56 and through the sixth gate B.46; on the second line - through the fifth delay line for 10 ms 57 and through the seventh gate B.47; on the third line - through the sixth delay line for 19 ms 58, through the eighth gate B.48 and through the ninth gate B.49; at the same time, the output of the eighth valve B.48 is connected to the second output of the first shaper of groups of one- and two-millisecond pulses 3.1; the second input of the first shaper groups of one - and two-millisecond pulses 3.1 is connected to the first input of the element And 62; the output of the element And 62 is connected to the first output of the first shaper of groups of one- and two-millisecond pulses 3.1.

On FIG. 20 shows the temporal distribution of pulses and their duration, which are generated by the first generator of groups of one and two millisecond pulses 3.1, where the duration of the pulses created by the first generator of groups of one and two millisecond pulses with the same frequency filling of pulses, i. corresponds to τ=1 ms, and τ=2 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 1 ms; two pulses of the first and third of the second group with a duration of 1 ms, and the second pulse in the group of 2 ms; in the third group, the first and third pulses are 2 ms each, and the second pulse is 1 ms.

On FIG. 21 shows the second generator of groups of two and four millisecond pulses 3.2, where the first gate is B.50, the second gate is B.51, the third gate is B.52, the fourth gate is B.53, the fifth gate is B.54, the sixth gate is B.55, the seventh gate B.56, eighth gate B.57, ninth gate B.58, first delay line for 3 ms. 63, second delay line 10ms 64, third delay line 18ms 65, fourth delay line 30ms 66, fifth delay line 13ms 67, sixth delay line 25ms 68, seventh delay line 10ms 70, the first trigger for 2 ms 69, the second trigger for 4 ms 71, element And 72, while the second button Kn. the input of the second shaper of groups of two- and four-millisecond pulses 3.2; the first input of the second shaper of groups of two and four millisecond pulses 3.2 is connected to the input of the first trigger for 2 ms 69; the output of the first trigger for 2 ms 69 is connected in parallel on five lines with the second input of the element And 72: on the first line through the first gate B.50; on the second line - through the first delay line for 3 ms 63 and through the second gate B.51; on the third line - through the seventh delay line for 10 ms 70 and through the third gate B.52; on the fourth line - through the seventh delay line for 10 ms 70, through the second delay line for 10 ms 64 and through the fourth gate B.53; on the fifth line - through the seventh delay line for 10 ms 70, through the third delay line for 18 ms 65 and through the fifth gate B.54; in addition, the output of the first flip-flop for 2 ms 69 is connected to the input of the second flip-flop for 4 ms 71 through the seventh delay line for 10 ms 70; the output of the second trigger for 4 ms 71 is connected on three lines with the second input of the element And 72: on the first line through the fourth delay line for 30 ms 66 and through the sixth gate B.55; on the second line - through the fifth delay line for 13 ms 67 and through the seventh gate B.56; on the third line - through the sixth delay line for 25 ms 68, through the eighth gate B.57 and through the ninth gate B.58; at the same time, the output of the eighth gate 58 is connected to the second output of the second generator of groups of two- and four-millisecond pulses 3.2; the second input of the second generator of groups of two and four millisecond pulses 3.2 is connected to the first input of the element AND72; the output of the And 72 element is connected to the first output of the second generator of groups of two- and four-millisecond pulses 3.2.

On FIG. 22 shows the temporal distribution of pulses and their duration, which are formed by the second generator of groups of two and four millisecond pulses 3.2, where the duration of the pulses created by the second generator of groups of two and four millisecond pulses with the same frequency filling of pulses, i.e. corresponds to τ=2 ms, and τ=4 ms, and formed three groups of pulses: the first group of two pulses, the second group of three and the third group of three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 2 ms; two pulses of the first and third of the second group with a duration of 2 ms, and the second pulse in the second group of 4 ms; in the third group, the first and third pulses are 4 ms each, and the second pulse is 2 ms.

On FIG. 23 shows the third generator of groups of three- and six-millisecond pulses 3.3, where the first gate is B.59, the second gate is B.60, the third gate is B.61, the fourth gate is B.62, the fifth gate is B.63, the sixth gate is B.64, the seventh gate B.65, eighth gate B.66, ninth gate B.67, first delay line for 4 ms. 73, second delay line at 23ms 74, third delay at 37ms 75, fourth delay at 15ms 76, fifth delay at 11ms 77, sixth delay at 4ms 78, seventh delay at 12ms 80, the first trigger for 3 ms 79, the second trigger for 6 ms 81, the element And 82, while the third button Kn. the input of the third shaper of groups of three- and six-millisecond pulses 3.3; the first input of the third shaper of groups of three and six millisecond pulses 3.3 is connected to the input of the first trigger for 3 ms 79; the output of the first trigger for 3 ms 79 is connected in parallel on five lines with the second input of the element And 82: on the first line - through the first valve B.59; on the second line - through the first delay line for 4 ms 73 and through the second gate B.60; on the third line - through the seventh delay line for 12 ms 80 and through the third gate B.61; on the fourth line - through the seventh delay line for 12 ms 80, through the second delay line for 23 ms 74, and through the fourth gate B.62; on the fifth line - through the seventh delay line for 12 ms 80, through the third delay line for 37 ms 75, and through the fifth gate B.63; in addition, the output of the seventh delay line for 12 ms 80 is connected to the input of the second trigger for 6 ms 81; the output of the second trigger for 6 ms 81 is connected in three lines with the second input of the element And 82: on the first line through the fourth delay line for 15 ms 76 and through the sixth gate B.64; on the second line - through the fifth delay line for 11 ms 77 and through the seventh gate B.65; on the third line - through the seventh delay line for 4 ms 78, through the eighth gate B.66 and through the ninth gate B.67; at the same time, the output of the eighth gate B.66 is connected to the second output of the third generator of groups of three- and six-millisecond pulses 3.3; the second input of the third shaper groups of three - and six-millisecond pulses 3.3 is connected to the first input of the element And 82; the output of the element And 82 is connected to the first output of the third generator groups of three - and six-millisecond pulses 3.3.

On FIG. 24 shows the temporal distribution of pulses and their duration, which are generated by the third generator of groups of three and six millisecond pulses 3.3, where the duration of the pulses generated by the third generator of groups of three and six millisecond pulses with the same frequency filling of pulses, i.e. corresponds to τ=3 ms, and τ=6 ms, and formed three groups of pulses: the first group of two pulses, the second group of three and the third group of three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 3 ms; two pulses of the first and third of the second group with a duration of 3 ms, and the second pulse in the second group of 6 ms; in the third group, the first and third pulses are 6 ms each, and the second pulse is 3 ms.

On FIG. 25 shows the fourth four- and eight-millisecond pulse group generator 3.4, where the first gate is B.68, the second gate is B.69, the third gate is B.70, the fourth gate is B.71, the fifth gate is B.72, the sixth gate is B.73, the seventh gate B.74, eighth gate B.75, ninth gate B.76, first delay line for 5 ms. 83, second delay line 14ms 84, third delay line 32ms 85, fourth delay line 5ms 86, fifth delay line 23ms 87, sixth delay line 37ms 88, seventh delay line 14ms 90, the first trigger for 4 ms 89, the second trigger for 8 ms 91, the element And 92, while the fourth button Kn.4 (Fig. 18) to start the first four-millisecond trigger 4 ms 89 for a short time, the one-millisecond pulse generator 3.5 of the shaper 3 is connected to the first input of the fourth shaper of groups of four- and eight-millisecond pulses 3.4; the first input of the fourth shaper of groups of four and eight millisecond pulses 3.4 is connected to the input of the first trigger for 4 ms 89; the output of the first trigger for 4 ms 89 is connected in parallel on five lines with the second input of the element And 92: on the first line - through the first valve B.68; on the second line - through the first delay line for 5 ms 83 and through the second gate B.69; on the third line - through the seventh delay line for 14 ms 90 and through the third gate B.70; on the fourth line - through the seventh delay line for 14 ms 90, through the second delay line for 14 ms 84 and through the fourth gate B.71; on the fifth line - through the seventh delay line for 14 ms 90, through the third delay line for 32 ms 85 and through the fifth gate B.72; in addition, the output of the seventh delay line for 14 ms 90 is connected to the input of the second trigger for 8 ms 91; the output of the second trigger for 8 ms 91 is connected on three lines with the second input of the element And 92: on the first line - through the fourth delay line for 5 ms 86 and through the sixth gate B.73; on the second line - through the fifth delay line for 23 ms 87 and through the seventh gate B.74; on the third line - through the sixth delay line for 37 ms 88, through the eighth gate B.75 and through the ninth gate B.76; at the same time, the output of the eighth valve B.75 is connected in parallel with the second output of the fourth generator of groups of four and eight millisecond pulses 3.4; the second input of the fourth generator groups of four - and eight-millisecond pulses 3.4 is connected to the first input of the element And 92; the output of the element And 92 is connected to the first output of the fourth generator of groups of four and eight millisecond pulses 3.4.

On FIG. 26 shows the temporal distribution of pulses and their duration, which are formed by the fourth generator of groups of four and eight millisecond pulses 3.4, where the duration of the pulses created by the fourth generator of groups of four and eight millisecond pulses with the same frequency filling of pulses, i.e. corresponds to τ=4 ms, and τ=8 ms, and formed three groups of pulses: the first group of two pulses, the second group of three and the third group of three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 4 ms; two pulses of the first and third of the second group with a duration of 4 ms, and the second pulse in the second group of 8 ms; in the third group, the first and third pulses are 8 ms each, and the second pulse is 4 ms.

On FIG. 27 shows the operating mode selection block 4, where the transformer Tr.1 with three primary windings and one secondary winding, while the first input of the operating mode selection block 4 is connected to terminal "b ₁ " of the first primary winding of the transformer Tr.1, and terminal "a ₁ » the first primary winding of the transformer Tr.1 is grounded; the second input of the operating mode selection block 4 is connected to the terminal "b ₂ " of the second primary winding of the transformer Tr.1, and the terminal "a ₂ " the second primary winding of the transformer Tr.1 is grounded; the third input of the operating mode selection block 4 is connected to the terminal "b ₃ " of the third primary winding of the transformer Tr.1, and the terminal "a ₃ " the third primary winding of the transformer Tr.1 is grounded; the secondary winding of the transformer Tr.1 is connected by terminal "e" to the output of the operating mode selection block 4, and the secondary winding of the transformer Tr.1 is grounded by terminal "c".

On FIG. 28 shows the matching device of the transmission system 5.2, where the transformer Tr.1 with the primary winding 1 and N secondary windings, while the input of the matching device of the transmission system 5.2 is connected to the terminal "C" of the primary winding 1 of the transformer Tr.1, the terminal "D" of this primary transformer windings Tr.1 is grounded; output 7 ₁ of the matching device of the transmission system 5.2 is connected to the terminal "a ₁ " of the first secondary winding 1 of the transformer Tr.1, and the terminal "in ₁ " of this first secondary winding is grounded; output 7 ₂ of the matching device of the transmission system 5.2 is connected to the terminal "a ₂ " of the second secondary winding 2 of the transformer Tr.1, and the terminal " in ₂ " of this second secondary winding is grounded; output ₇₃ of the matching device of the transmission system 5.2 is connected to the terminal "a ₃ " of the third secondary winding 3 of the transformer Tr.1, and the terminal "in ₃ " of this third secondary winding is grounded; output 7 _N-1 of the matching device of the transmission system 5.2 is connected to the terminal "a _N-1 " N-1 of the secondary winding of the transformer Tr.1, and the terminal "in _N-1 " of this N-1 secondary winding is grounded; the output 7 _N of the matching device of the transmission system 5.2 is connected to the terminal “a _N ” N of the secondary winding of the transformer Tr.1, and the terminal “in _n ” of this N secondary winding is grounded.

On FIG. 29 shows the information generator of the receiving system 9, where 9.1 is the matching device of the first in-phase receiving antenna line containing information from the first line from 6 ₁₁ to N antenna 6 _1N ; 9.2 - matching device of the second in-phase receiving antenna line containing information from the second antenna line from 6 ₂₁ to N antenna 6 _2N ; 9.3 - matching device of the third in-phase receiving antenna line containing information from the third antenna line from 6 ₃₁ to N antenna 6 _3N ; 9.N-1 - matching device N-1 in-phase receiving antenna array containing information from N-1 antenna array from 6 _N-1.1 to N antenna 6 _N-1.N ; 9.N - matching device N in-phase receiving antenna array containing information from N antenna array from 6 _1N to N antenna 6 _nn ; 9.0 - amplifier in each of the N receiver lines; 9.00 - matching device of the receiving antenna system; at the same time, the first input of the information generator of the receiving system 9 is connected through the first input of the matching device of the first in-phase receiving antenna line 9.1, through the amplifier 9.0 with the first input of the matching device of the receiving antenna system 9.00; the second input of the information generator of the receiving system 9 is connected through the first input of the matching device of the second in-phase receiving antenna line 9.2, through the amplifier 9.0 with the second input of the matching device of the receiving antenna system 9.00; the third input of the information generator of the receiving system 9 is connected through the first input of the matching device of the third in-phase receiving antenna line 9.3, through the amplifier 9.0 with the third input of the matching device of the receiving antenna system 9.00; n-1 input of the information generator of the receiving system 9 is connected through the first input of the matching device N-1 of the in-phase receiving antenna line 9.N-1, through the amplifier 9.0 with the n-1 input of the matching device of the receiving antenna system 9.00; n the input of the information generator of the receiving system 9 is connected through the first input of the matching device N of the in-phase receiving antenna line 9.N, through the amplifier 9.0 with the n input of the matching device of the receiving antenna system 9.00; n ₁ the input of the information generator of the receiving system 9 is connected in parallel with the second input of the matching device of the first in-phase receiving antenna line 9.1, with the second input of the matching device of the second in-phase receiving antenna line 9.2, with the second input of the matching device of the third in-phase receiving antenna line 9.3, with the second input of the matching device N-1 in-phase receiving antenna line 9.N-1, with the second input of the matching device N in-phase receiving antenna line 9.N; the output of the matching device of the receiving antenna system 9.00 is connected to the output of the information generator of the receiving system 9.

On FIG. 30 shows a matching device for antennas of the first in-phase receiving antenna line 9.1 (identical for the second 9.2; third 9.3; ...; 9.N-1; 9.N), where the switching unit is 9.a, the transformer Tr.1 with one secondary winding and N primary windings, while the one-to-one input 1.1 of the matching device 9.1, as the output of the first antenna 6 ₁₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a with the terminal "a ₁ " of the first primary windings of the transformer Tr.1, and the terminal "in ₁ " of the first primary winding is grounded; input one-two 1.2 of the matching device 9.1, as the output of the second antenna 6 ₂₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a to the terminal "a ₂ " of the second primary winding of the air transformer Tr.1 , and the terminal "in ₂ " of the second primary winding is grounded; input one-three 1.3 of the matching device 9.1, as the output of the third antenna 6 ₃₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a to the terminal "a ₃ " of the third primary winding of the transformer Tr.1, terminal "in ₃ " of the third primary winding is grounded; input 1.n-1 of the matching device 9.1, as the output N-1 of the antenna 6 _N-1.1 from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a with the terminal "a _N-1 " N -1 of the primary winding of the transformer Tr.1, and the terminal "in _N-1 " N-1 of the primary winding is grounded; the input one-n 1.n of the matching device 9.1, as the output N of the receiving antenna 6 _N.1 from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a with the terminal "a _N " N of the primary winding transformer Tr.1, and the terminal "in _N " N of the primary winding is grounded; the second input 2 of the matching device 9.1 is connected in parallel with the second inputs of all N switching units 9.a; the terminal "K" of the secondary winding of the transformer Tr.1 is connected to the output of the matching device 9.1, and the terminal "M" of the secondary winding of the transformer Tr.1 is grounded.

On FIG. 31 shows the switching unit 9.a, where 9.a.1 is the AND element, 9.a.2 is the NOT element, while the first input of the switching unit 9.a is connected to the first input of the AND element, and the second input of the switching unit 9. and through the element NOT 9.a.2 connected to the second input of the element And 9.a.1; the output of the element And 9.a.1 is connected to the output of the switching unit 9.a.

On FIG. 32 shows the matching device of the receiving antenna system 9.00, where the transformer Tr.1 with "n" primary windings and one secondary winding, while the first input 1 of the matching device of the receiving antenna system 9.00, as the output of the first in-phase receiving antenna line 6 ₁₁ -6 _1N , connected to the terminal "a ₁ " of the first primary winding of the transformer Tr.1, and the terminal "in ₁ " of the first primary winding of the transformer Tr.1 is grounded; the second input 2 of the matching device of the receiving antenna system 9.00, as the output of the second in-phase receiving antenna line 6 ₂₁ -6 _2N , is connected to the terminal "a ₂ " of the second primary winding of the transformer Tr.1, and the terminal "in ₂ " of the second primary winding of the transformer Tr. 1 grounded; the third input of the matching device of the receiving antenna system 9.00, as the output of the third in-phase receiving antenna line 6 ₃₁ -6 _3N , is connected to the terminal "a ₃ " of the third primary winding of the transformer Tr.1, and the terminal "in ₃ " of the third primary winding of the transformer Tr.1 grounded; "n-1" input of the matching device of the receiving antenna system 9.00, as the output N-1 of the in-phase receiving antenna line 6 _(n-1)1 -6 _(n-1)n , is connected to the terminal "a _N-1 " N-1 the primary winding of the transformer Tr.1, and the terminal "in _N-1 " N-1 of the primary winding of the transformer Tr.1 is grounded; "n" the input of the matching device of the receiving antenna system 9.00, as the output N of the in-phase receiving antenna line 6 _N1 -6 _NN , is connected to the terminal "a _N " N of the primary winding of the transformer Tr.1, and the terminal "in _N " N of the primary winding of the transformer Tr .1 grounded; the terminal "C" of the secondary winding of the transformer Tr.1 is connected to the output of the matching device of the receiving antenna system 9.00, and the terminal "D" of the secondary winding of the transformer Tr.1 is grounded.

In FIG. 33 shows a filter block 10 for ten channels, where 10.1 is the first band-pass filter for frequencies of 1-10 kHz, 10.2 is the second band-pass filter for frequencies of 10-50 kHz, 10.3 is the third band-pass filter for frequencies of 50-100 kHz, 10.4 is the fourth band-pass filter filter for frequencies 100-200 kHz, 10.5 - the fifth band-pass filter for frequencies 200-400 kHz, 10.6 - the sixth band-pass filter for frequencies 400-800 kHz, 10.7 - the seventh band-pass filter for frequencies 800-1000 kHz, 10.8 - the eighth band-pass filter for frequencies 1-10 MHz, 10.9 - the ninth band-pass filter for frequencies 10-20 MHz, 10-10 - the tenth band-pass filter for frequencies 20-40 MHz; 10.11 - the first narrow-band amplifier for a frequency band of 1-10 kHz., 10.12 - the second narrow-band amplifier for a frequency band of 10-50 kHz, 10.13 - the third narrow-band amplifier for a frequency band of 50-100 kHz, 200 kHz, 10.15 - the fifth narrow-band amplifier for the frequency band 200-400 kHz, 10.16 - the sixth narrow-band amplifier for the frequency band 400-800 kHz, 10.17 - the seventh narrow-band amplifier for the frequency band 800-1000 kHz, 10.18 - the eighth narrow-band amplifier for the frequency band 1-10 MHz, 10.19 - the ninth narrow-band amplifier for the frequency band 10-20 MHz, 10.20 - the tenth narrow-band amplifier for the frequency band 20-40 MHz; each of the ten band-pass filters, from the first 10.1 to the tenth 10.10, contains two resistors R ₁ and R ₂ and two capacitive gyrators G _C1 and G _C2 , while the input of the filter unit for ten channels 10 is connected in parallel with ten inputs of ten band-pass filters from the first 10.1 to tenth 10.10; the outputs of ten band-pass filters through ten narrow-band amplifiers form ten outputs of the filter unit for ten channels 10; the input of the filter unit for ten channels 10 through the output of the first bandpass filter 10.1 with a bandwidth of 1 kHz to 10 kHz is connected to the first output of the filter unit through the first narrow-band amplifier 10.11; the input of the filter unit for ten channels 10 through the output of the second bandpass filter 10.2 with a bandwidth from 10 kHz to 50 kHz is connected to the second output of the filter unit 10 through the second narrow-band amplifier 10.12; the input of the filter unit for ten channels 10 through the output of the third bandpass filter 10.3 with a bandwidth of 50 kHz to 100 kHz is connected to the third output of the filter unit 10 through the third narrow-band amplifier 10.13; the input of the filter unit for ten channels 10 through the output of the fourth bandpass filter 10.4 with a bandwidth from 100 kHz to 200 kHz is connected to the fourth output of the filter unit 10 through the fourth narrow-band amplifier 10.14; the input of the filter unit for ten channels 10 through the output of the fifth bandpass filter 10.5 with a bandwidth of 200 kHz to 400 kHz is connected to the fifth output of the filter unit 10 through the fifth narrow-band amplifier 10.15; the input of the filter unit for ten channels 10 through the output of the sixth bandpass filter 10.6 with a bandwidth from 400 kHz to 800 kHz is connected to the sixth output of the filter unit 10 through the sixth narrow-band amplifier 10.16; the input of the filter unit for ten channels 10 through the output of the seventh bandpass filter 10.7 with a bandwidth from 800 kHz to 1000 kHz is connected to the seventh output of the filter unit 10 through the seventh narrow-band amplifier 10.17; the input of the filter unit for ten channels 10 through the output of the eighth bandpass filter 10.8 with a bandwidth of 1.0 to 10 MHz is connected to the eighth output of the filter unit 10 through the eighth narrow-band amplifier 10.18; the input of the filter unit for ten channels 10 through the output of the ninth bandpass filter 10.9 with a bandwidth of 10 to 20 MHz is connected to the ninth output of the filter unit 10 through the ninth narrow-band amplifier 10.19; the input of the filter unit for ten channels 10 through the output of the tenth bandpass filter 10.10 with a bandwidth of 20 to 40 MHz is connected to the tenth output of the filter unit 10 through the tenth narrow-band amplifier 10.20; the input of each of the ten band-pass filters, from the first 10.1 to the tenth 10.10, is connected through the terminal "c" to the terminal "d", the terminal "d" is connected through the first capacitive gyrator Ga and through the first resistor R ₁ with the output of the band-pass filter, and through the second resistor R ₂ terminal "d" is grounded, while terminal "c" is grounded through the second capacitive gyrator G _C2 (Fig. 33, (a)).

On FIG. 34 shows a block for analyzing the spectrum of nuclear quadrupole resonance radiation 11, containing ten oscillatory systems from the first 11.1 to the tenth 11.10 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, as well as ten groups of five resonance clamps in each group or fifty resonance clamps 1 (photodiodes 1), in addition, ten indicators of justifying the resonance frequency from the first indicator I.1-6 to the tenth I.10 -6; the first input of the nuclear quadrupole resonance spectrum analysis unit 11 is connected to the input of the first oscillatory system 11.1 at frequencies of 1-10 kHz, the first output of the first oscillatory system 11.1 is connected to the first inputs of the first group of five indicators from I.1-1 to I.1 -5, and the second output of the first oscillatory system 11.1 is connected to the second inputs of the first group of five indicators from I.1-1 to I.1-5, the third output of the first oscillatory system is connected to the first output of the nuclear quadrupole resonance spectrum analysis unit 11, the fourth the output of the first oscillatory system 11.1 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the first frequency justification indicator I.1-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the first group I.1-1 is connected to the third input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the first group I.1-2 is connected to the sixth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the first group I.1-3 is connected to the ninth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the first group I.1-4 is connected to the twelfth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the first group I.1-5 is connected to the fifteenth input of the first indicator of the resonance frequency justification I.1-6; the output of the first frequency justification indicator I.1-6 is connected to the first conditional output 1.1 of the nuclear quadrupole resonance spectrum analysis block 11; the second input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the second oscillatory system 11.2 at frequencies of 10-50 kHz, the first output of the second oscillatory system 11.2 is connected to the first inputs of the second group of five indicators from I.2-1 to I.2-5, and the second output of the second oscillatory system 11.2 is connected to the second inputs of the second group of five indicators from I.2-1 to I.2-5, the third output of the second oscillatory system 11.2 is connected to the second output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the second oscillatory system 11.2 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the second frequency justification indicator I.2-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the second group I.2-1 is connected to the third input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the second group I.2-2 is connected to the sixth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the second group I.2-3 is connected to the ninth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance clamp 1 (photodiode 1) of the fourth indicator determined by the LED in the second group I.2-4 is connected to the twelfth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the second group I.2-5 is connected to the fifteenth input of the second indicator of the resonance frequency justification I.2-6; the output of the second frequency justification indicator I.2-6 is connected to the second conditional output 2.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the third input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the third oscillatory system 11.3 at frequencies of 50-100 kHz, the first output of the third oscillatory system 11.3 is connected to the first inputs of the third group of five indicators from I.3-1 to I.3-5, and the second output of the third oscillatory system 11.3 is connected to the second inputs of the third group of five indicators from I.3-1 to I.3-5, the third output of the third oscillatory system 11.3 is connected to the third output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the third oscillatory system 11.3 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the third frequency justification indicator I.3-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the third group I.3-1 is connected to the third input of the third indicator of the justification of the resonance frequency I.3-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the third group I.3-2 is connected to the sixth input of the third indicator of the justification of the resonance frequency I.3-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the third group I.3-3 is connected to the ninth input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the third group I.3-4 is connected to the twelfth input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the third group I.3-5 is connected to the fifteenth input of the third indicator of the resonance frequency justification I.3-6; the output of the third indicator justifying the frequency I.3-6 is connected to the third conditional output 3.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the fourth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the fourth oscillatory system 11.4 at frequencies of 100-200 kHz, the first output of the fourth oscillatory system 11.4 is connected to the first inputs of the fourth group of five indicators from I.4-1 to I.4-5, and the second output of the fourth oscillatory system 11.4 is connected to the second inputs of the fourth group of five indicators from I.4-1 to I.4-5, the third output of the fourth oscillatory system 11.4 is connected to the fourth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the fourth oscillatory system 11.4 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the fourth frequency justification indicator I.4-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the fourth group I.4-1 is connected to the third input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the fourth group I.4-2 is connected to the sixth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the fourth group I.4-3 is connected to the ninth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the fourth group I.4-4 is connected to the twelfth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the fourth group I.4-5 is connected to the fifteenth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the fourth frequency justification indicator I.4-6 is connected to the fourth conditional output 4.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the fifth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the fifth oscillatory system 11.5 at frequencies of 200-400 kHz, the first output of the fifth oscillatory system 11.5 is connected to the first inputs of the fifth group of five indicators from I.5-1 to I.5-5, and the second output of the fifth oscillatory system 11.5 is connected to the second inputs of the fifth group of five indicators from I.5-1 to I.5-5, the third output of the fifth oscillatory system 11.5 is connected to the fifth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the fifth oscillatory system 11.5 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the fifth frequency justification indicator I.5-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the fifth group I.5-1 is connected to the third input of the fifth indicator of the resonance frequency justification I.5-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the fifth group I.5-2 is connected to the sixth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the fifth group I.5-3 is connected to the ninth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the fifth group I.5-4 is connected to the twelfth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the fifth group I.5-5 is connected to the fifteenth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the fifth indicator justifying the frequency I.5-6 is connected to the fifth conditional output 5.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the sixth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the sixth oscillatory system 11.6 at frequencies of 400-800 kHz, the first output of the sixth oscillatory system 11.6 is connected to the first inputs of the sixth group of five indicators from I.6-1 to I.6-5, and the second output of the sixth oscillatory system is connected to the second inputs of the sixth group of five indicators from I.6-1 to I.6-5, the third output of the sixth oscillatory system 11.6 is connected to the sixth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the sixth oscillatory system 11.6 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the sixth frequency justification indicator I.6-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the sixth group I.6-1 is connected to the third input of the sixth indicator of the resonance frequency justification I.6-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the sixth group I.6-2 is connected to the sixth input of the sixth indicator of the justification of the resonance frequency I.6-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the sixth group I.6-3 is connected to the ninth input of the sixth indicator of the justification of the resonance frequency I.6-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the sixth group I.6-4 is connected to the twelfth input of the sixth indicator of the resonance frequency justification I.6-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the sixth group I.6-5 is connected to the fifteenth input of the sixth indicator of the justification of the resonance frequency I.6-6; the output of the sixth frequency justification indicator I.6-6 is connected to the sixth conditional output 6.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the seventh input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the seventh oscillatory system 11.7 at frequencies of 800-1000 kHz, the first output of the seventh oscillatory system 11.7 is connected to the first inputs of the seventh group of five indicators from I.7-1 to I.7-5, and the second output of the seventh oscillatory system 11.7 is connected to the second inputs of the seventh group of five indicators from I.7-1 to I.7-5, the third output of the seventh oscillatory system 11.7 is connected to the seventh output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the seventh oscillatory system 11.7 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the seventh frequency justification indicator I.7-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the seventh group I.7-1 is connected to the third input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the seventh group I.7-2 is connected to the sixth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the seventh group I.7-3 is connected to the ninth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the seventh group I.7-4 is connected to the twelfth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the seventh group I.7-5 is connected to the fifteenth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the seventh frequency justification indicator I.7-6 is connected to the seventh conditional output 7.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the eighth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the eighth oscillatory system 11.8 at frequencies of 1-10 MHz, the first output of the eighth oscillatory system 11.8 is connected to the first inputs of the eighth group of five indicators from I.8-1 to I.8-5, and the second output of the eighth oscillatory system 11.8 is connected to the second inputs of the eighth group of five indicators from I.8-1 to I.8-5, the third output of the eighth oscillatory system 11.8 is connected to the eighth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the eighth oscillatory system 11.8 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the eighth frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the eighth group I.8-1 is connected to the third input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance clamp 1 (photodiode 1) of the second indicator determined by the LED in the eighth group I.8-2 is connected to the sixth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the eighth group I.8-3 is connected to the ninth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the eighth group I.8-4 is connected to the twelfth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the eighth group I.8-5 is connected to the fifteenth input of the eighth resonance frequency justification indicator I.8-6; the output of the eighth frequency justification indicator I.8-6 is connected to the eighth conditional output 8.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the ninth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the ninth oscillatory system at frequencies of 10-20 MHz, the first output of the ninth oscillatory system 11.9 is connected to the first inputs of the ninth group of five indicators from I.9-1 to I.9-5, and the second output of the ninth oscillatory system 11.9 is connected to the second inputs of the ninth group of five indicators from I.9-1 to I.9-5, the third output of the ninth oscillatory system 11.9 is connected to the ninth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the ninth oscillatory system 11.9 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the ninth frequency justification indicator I.9-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the ninth group I.9-1 is connected to the third input of the ninth indicator of the resonance frequency justification I.9-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the ninth group I.9-2 is connected to the sixth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the ninth group I.9-3 is connected to the ninth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the ninth group I.9-4 is connected to the twelfth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the resonance clamp 1 (photodiode 1) of the fifth indicator determined by the LED in the ninth group I.9-5 is connected to the fifteenth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the ninth indicator justifying the frequency I.9-6 is connected to the ninth conditional output 9.1 of the nuclear quadrupole resonance spectrum analysis unit I; the tenth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the tenth oscillatory system 11.10 at frequencies of 20-40 MHz, the first output of the tenth oscillatory system 11.10 is connected to the first inputs of the tenth group of five indicators from I.10-1 to I.10-5, and the second output of the tenth oscillatory system 11.10 is connected to the second inputs of the tenth group of five indicators from I.10-1 to I.10-5, the third output of the tenth oscillatory system 11.10 is connected to the tenth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the tenth oscillatory system 11.10 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the tenth frequency justification indicator I.10-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the tenth group I.10-1 is connected to the third input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the tenth group I.10-2 is connected to the sixth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the tenth group I.10-3 is connected to the ninth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the tenth group I.10-4 is connected to the twelfth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the tenth group I.10-5 is connected to the fifteenth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the tenth frequency justification indicator I.10-6 is connected to the tenth conditional output 10.1 of the nuclear quadrupole resonance spectrum analysis unit 11.

On FIG. 35 shows the oscillatory system 11.1 (any of ten with 11.1; 11.2; 11.3; ...; 11.10), contains five oscillatory bridges: 1, 2, 3, 4 and 5; each bridge contains high-resistance R, four parallel oscillatory circuits made on the basis of microcircuits - capacitive gyrators Gs and inductive gyrators GL: two oscillatory circuits with parameters gyrator GL1 as inductance L ₁ and gyrator Gs1 as capacitance C ₁ , as well as two oscillatory circuits with parameters GL2 as inductance L ₂ and Gc2 as capacitance C ₂ , to control the resonance of oscillatory systems, two voltage dividers are connected in parallel, made of two series-connected high-resistance resistors connected in parallel to two parallel oscillatory circuits; while the input of the oscillatory system 11.1 is connected in parallel with the five inputs of the five bridges and with the third output of the oscillatory system 11.1, the first outputs of the five bridges (1, 2, 3, 4 and 5) form the first output, the second outputs of the five bridges (1, 2, 3 , 4 and 5) form the second outlet; the input of each bridge is connected through the terminal "c" to the terminal "g" and through the second parallel oscillatory circuit with the parameters GL2 and Gc2 to the terminal "m" and then through the terminal "a" with the first output of the bridge, and in parallel the terminal "c" is connected to terminal "n" and through the first parallel oscillatory circuit with parameters GL1 and Gc1 with terminal "k" and then through terminal "b" with the second output of the bridge; terminal "a" is connected in parallel through high-resistance R with terminal "b" and in parallel terminal "a" is connected through terminal "l", through the first oscillatory circuit with parameters GL1 and Gc1 through terminal "n" with terminal "d", terminal " d” is grounded; in addition, the terminal "b" is connected through the terminal "h", through the second parallel oscillatory circuit with the parameters TL2 and Gc2 through the terminal "x" with the grounded terminal "d"; terminal "n" of the first oscillatory circuit with parameters GL1 and Gc1 is connected through terminal "t" through high-resistance R1, through terminal "h", through high-resistance R2, through terminal "w" with terminal "k" of the first oscillating circuit with parameters GL1 and Гс1, while the “z” terminal is connected to the third output in each of the five oscillatory bridges (1, 2, 3, 4 and 5); the “h” terminal of the second oscillatory circuit with the parameters GL2 and Gc2 is connected through the “i” terminal through the high-resistance R3, through the “p” terminal, through the high-resistance R4, through the “o” terminal with the “x” terminal of the second oscillatory circuit with the GL2 parameters and Гс2, while the "r" terminal is connected to the fourth output in each of the five oscillatory bridges (1, 2, 3, 4 and 5); moreover, the third and fourth outputs in each of the five oscillatory bridges from the first to the fifth form a parallel fourth output 4 in any of the ten oscillatory systems with 11.1; 11.2; 11.3; …; according to 11.10, wherein the third output of the first oscillatory bridge is connected to the fourth output of the oscillatory system through its first input, and the fourth output of the first oscillatory bridge is connected to the fourth output of the oscillatory system through its second input; further, the third output of the second oscillatory bridge is connected to the fourth output of the oscillatory system through its fourth input, and the fourth output of the second oscillatory bridge is connected to the fourth output of the oscillatory system through its fifth input; further, the third output of the third oscillatory bridge is connected to the fourth output of the oscillatory system through its seventh input, and the fourth output of the third oscillatory bridge is connected to the fourth output of the oscillatory system through its eighth input; further, the third output of the fourth oscillatory bridge is connected to the fourth output of the oscillatory system through its tenth input, and the fourth output of the fourth oscillatory bridge is connected to the fourth output of the oscillatory system through its eleventh input; further, the third output of the fifth oscillatory bridge is connected to the fourth output of the oscillatory system through its thirteenth input, and the fourth output of the fifth oscillatory bridge is connected to the fourth output of the oscillatory system through its fourteenth input; the first oscillatory system 11.1 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 1.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 2.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 3.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 4.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 5.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 6.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 7.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 8.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 9.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 9.9 kHz; the second oscillatory system 11.2 contains five bridges: the first bridge with the first parallel oscillatory circuit with the parameters GL1 and Gs 1 is tuned to a frequency of 11.9 kHz, and the second oscillatory circuit with the parameters GL2 and Gs2 is tuned to a frequency of 15.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 20.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 25.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 30.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 35.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 40.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 44.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 47.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 49.9 kHz; the third oscillatory system 11.3 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 52.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 58.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 62.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 68.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 72.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 78.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 82.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 88.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 92.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 98.9 kHz; the fourth oscillatory system 11.4 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 110.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 120.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 130.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 140.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 150.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 160.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 170.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 178.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 185.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 198.1 kHz; the fifth oscillatory system 11.5 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 210.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 230.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 250.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 270.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 290.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 310.1 kHz; the fourth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 330.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 350.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 370.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 390.1 kHz; the sixth oscillatory system 11.6 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 410.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 450.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 490.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 530.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 570.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 610.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 650.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 690.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 730.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 790.1 kHz; the seventh oscillatory system 11.7 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 810.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 830.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 850.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 880.1 kHz; the third bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 890.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 910.1 kHz; the fourth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 930.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 950.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 970.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 990.1 kHz; the eighth oscillatory system 11.8 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 1100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 1900.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 2900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 3900.1 kHz; the third bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 4900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 5900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 6900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 7900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 8900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 9900.1 kHz; the ninth oscillatory system 11.9 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 10100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 10900.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 12900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 13900.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 14900.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 15900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 16900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 17900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 18900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 19900.1 kHz; the tenth oscillatory system 11.10 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 21100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 23100.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 25100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 27900.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 30100.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 32900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 35100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 37900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 38900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 39900.1 kHz;

On FIG. 36 resonance frequency justification indicator I.1-6 (any of ten from I.1-6 to I.10-6) containing five switches, transformer Tr.1 with one secondary winding and five primary windings, each of the five primary windings transformer Tr.1 consists of two identical sections separated by the middle terminal, while the first input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a1" of the first 1 primary winding of the transformer Tr.1, the second input of the resonance frequency justification indicator AND .1-6 is connected to the terminal "a2" of the first 1 primary winding of the transformer TR.1, the third input of the resonance frequency justification indicator I.1-6 is connected to the first switch of the relay Vk.1, the first primary winding is connected to the grounded terminal "a3" by the middle terminal terminal "a4" when switching the first switch Vk.1 terminal "a5"; the fourth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a6" of the second 2 primary winding of the transformer TR.1, the fifth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a7" of the second 2 primary winding of the transformer TR. 1, the sixth input of the resonance frequency justification indicator I.1-6 is connected to the second switch of the relay Vk.2, the second primary winding is connected by the middle terminal "a8" to the grounded terminal "a9" when switched by the second switch Vk.2 terminal "a10"; the seventh input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a11" of the third 3 primary winding of the transformer TR.1, the eighth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a12" of the third 3 primary winding of the transformer TR. 1, the ninth input of the resonance frequency justification indicator I.1-6 is connected to the third switch of the relay Vk.3, the third primary winding is connected by the middle terminal "a13" to the grounded terminal "a14" when switched by the third switch Vk.3 terminal "a15"; the tenth input of the resonance frequency justification indicator I.1-6 is connected to terminal "a16" of the fourth 4 primary winding of the transformer TR.1, the eleventh input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a17" of the fourth 4 primary winding of the transformer TR. 1, the twelfth input of the resonance frequency justification indicator I.1-6 is connected to the fourth switch of the relay Vk.4, the fourth primary winding is connected by the middle terminal "a18" to the grounded terminal "a19" when switched by the fourth switch Vk.4 by the terminal "a20"; the thirteenth input of the resonance frequency justification indicator I.1-6 is connected to terminal "a21" of the fifth 5 primary winding of the transformer TR.1, the fourteenth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a22" of the fifth 5 primary winding of the transformer TR. 1, the fifteenth input of the resonance frequency justification indicator I.1-6 is connected to the fifth switch of the relay Vk.5, the fifth primary winding is connected by the middle terminal "a23" to the grounded terminal "a24" when switching the fifth switch Vk.5 to the terminal "a25"; the secondary winding of the transformer Tr.1 is grounded by the “d” terminal, and the “c” terminal is connected to the output 1.1 of the resonance frequency justification indicator I.1-6.

On FIG. 37 shows a block for studying the emission spectrum of nuclear quadrupole resonance signals 12, containing a frequency spectrum analyzer 12.1 and a ten-pin switch Vk.1 for ten switching positions and a transformer Tr.1, while ten inputs from the first 1 to the tenth 10 of the block for studying the radiation spectrum 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 12.1; in addition, the one-one input 1.1 of the nuclear quadrupole resonance radiation spectrum research unit 12 is connected to the terminal "a1" of the first primary winding of the transformer Tr.1, and the first primary winding of the transformer Tr.1 is grounded by terminal "d1"; input two-one 2.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a2" of the second primary winding of the transformer Tr.1, and the second primary winding of the transformer Tr.1 is grounded by terminal "d2"; the three-one input 3.1 of the nuclear quadrupole resonance radiation spectrum study block 12 is connected to terminal "a3" of the third primary winding of the transformer Tr.1, and the third primary winding of the transformer Tr.1 is grounded by terminal "d3"; four-one input 4.1 of the nuclear quadrupole resonance radiation spectrum study block 12 is connected to the terminal "a4" of the fourth primary winding of the transformer Tr.1, and the fourth primary winding of the transformer Tr.1 is grounded by terminal "d4"; the input five-one 5.1 of the block for studying the radiation spectrum of the signals of nuclear quadrupole resonance 12 is connected to the terminal "a5" of the fifth primary winding of the transformer Tr.1, and the terminal "d5" the fifth primary winding of the transformer Tr.1 is grounded; input six-one 6.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a6" of the sixth primary winding of the transformer Tr.1, and the sixth primary winding of the transformer Tr.1 is grounded by terminal "d6"; input seven-one 7.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a7" of the seventh primary winding of the transformer Tr.1, and the seventh primary winding of the transformer Tr.1 is grounded by terminal "d7"; the input eight-one 8.1 of the block for studying the radiation spectrum of the signals of nuclear quadrupole resonance 12 is connected to the terminal "a8" of the eighth primary winding of the transformer Tr.1, and the eighth primary winding of the transformer Tr.1 is grounded by terminal "d8"; input nine-one 9.1 of the block for studying the emission spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a9" of the ninth primary winding of the transformer Tr.1, and the terminal "d9" the ninth primary winding of the transformer Tr.1 is grounded; input ten-one 10.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a10" of the tenth primary winding of the transformer Tr.1, and the tenth primary winding of the transformer Tr.1 is grounded by terminal "d10"; the secondary winding of the transformer Tr.1 is grounded by the “k” terminal, and by the “c” terminal it is connected to the output of the block for studying the emission spectrum of nuclear quadrupole resonance signals 12.

On FIG. 38 shows an analytical block 13 of weak NQR signals, containing: a transformer Tr.1 with ten primary windings and one secondary winding, ten microprocessors from the first - 13.1 to the tenth - 13.10, ten valves from the first - D.1 to the tenth - D.10, ten high-resistance resistors with a nominal value of 100 kOhm from the first - R ₁ to the tenth - R ₁₀ , the first input contains ten inputs from the first to the tenth for connection with ten outputs of the filter unit 10 (Fig. 1), the second input contains ten inputs from the eleventh to the twentieth for connections with ten outputs of the ambient temperature control unit 14 (Fig. 1 and Fig. 39), while the first input 1 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the first switch Vk.1, through the first valve D ₁ , through the first terminal "c ₁ " with the first input 1 of the first microprocessor 13.1, in parallel, the terminal "c ₁ " through the first high-resistance resistor R ₁ is grounded, the eleventh input of the analytical unit 13 of weak NQR signals is connected to about the second input 2 of the first microprocessor 13.1; the output of the first microprocessor 13.1 is connected to the first primary winding of the transformer Tr.1 through the terminal "a1", and the terminal "d1" of the first primary winding of the transformer Tr.1 is grounded; the second input 2 of the analytical block 13 of weak NQR signals is connected through the terminals "a" and "b" of the second switch Vk.2, through the second valve D ₂ , through the second terminal "c ₂ " with the first input 1 of the second microprocessor 13.2, in parallel with the terminal "c ₂ "through the second high-resistance resistor R ₂ is grounded, the twelfth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the second microprocessor 13.2; the output of the second microprocessor 13.2 is connected to the second primary winding of the transformer Tr.1 through the terminal "a2", and the terminal "d2" of the second primary winding of the transformer Tr.1 is grounded; the third input 3 of the analytical block 13 of weak NQR signals is connected through the terminals "a" and "b" of the third switch Vk.3, through the third valve D ₃ , through the third terminal "c ₃ " with the first input 1 of the third microprocessor 13.3, in parallel with the terminal "c ₃ "through the third high-resistance resistor R ₃ is grounded, the thirteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the third microprocessor 13.3; the output of the third microprocessor 13.3 is connected to the third primary winding of the transformer Tr.1 through the terminal "a3", and the terminal "d3" of the third primary winding of the transformer Tr.1 is grounded; the fourth input 4 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the fourth switch Vk.4, through the fourth valve D ₄ , through the fourth terminal "c ₄ " with the first input 1 of the fourth microprocessor 13.4, in parallel with the terminal "c ₄ "through the fourth high-resistance resistor R ₄ is grounded, the fourteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the fourth microprocessor 13.4; the output of the fourth microprocessor 13.4 is connected to the fourth primary winding of the transformer Tr.1 through the terminal "a4", and the terminal "d4" of the fourth primary winding of the transformer Tr.1 is grounded; the fifth input 5 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the fifth switch Vk.5, through the fifth valve D ₅ , through the fifth terminal "c ₅ " with the first input 1 of the fifth microprocessor 13.5, in parallel with the terminal "c ₅ "through the fifth high-resistance resistor R ₅ is grounded, the fifteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the fifth microprocessor 13.5; the output of the fifth microprocessor 13.5 is connected to the fifth primary winding of the transformer Tr.1 through the terminal "a5", and the terminal "d5" of the fifth primary winding of the transformer Tr.1 is grounded; the sixth input 6 of the analytical block 13 of weak NQR signals is connected through the terminals "a" and "b" of the sixth switch Vk.6, through the sixth valve D ₆ , through the sixth terminal "c ₆ " with the first input 1 of the sixth microprocessor 13.6, in parallel with the terminal "c ₆ "through the sixth high-resistance resistor R ₆ is grounded, the sixteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the sixth microprocessor 13.6; the output of the sixth microprocessor 13.6 is connected to the sixth primary winding of the transformer Tr.1 through the terminal "a6", and the terminal "d6" of the sixth primary winding of the transformer Tr.1 is grounded; the seventh input 7 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the seventh switch Vk.7, through the seventh valve D ₇ , through the seventh terminal "c ₇ " with the first input 1 of the seventh microprocessor 13.7, in parallel with the terminal "c ₇ "through the seventh high-resistance resistor R ₇ is grounded, the seventeenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the seventh microprocessor 13.7; the output of the seventh microprocessor 13.7 is connected to the seventh primary winding of the transformer Tr.1 through the terminal "a7", and the terminal "d7" of the seventh primary winding of the transformer Tr.1 is grounded; the eighth input 8 of the analytical block 13 of weak NQR signals is connected through the terminals "a" and "b" of the eighth switch Vk.8, through the eighth valve D ₈ , through the eighth terminal "c ₈ " with the first input 1 of the eighth microprocessor 13.8, in parallel with the terminal "c ₈ "through the eighth high-resistance resistor R ₈ is grounded, the eighteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the eighth microprocessor 13.8; the output of the eighth microprocessor 13.8 is connected to the eighth primary winding of the transformer Tr.1 through the terminal "a8", and the terminal "d8" of the eighth primary winding of the transformer Tr.1 is grounded; the ninth input 9 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the ninth switch Vk.9, through the ninth valve D ₉ , through the ninth terminal "c ₉ " with the first input 1 of the ninth microprocessor 13.9, in parallel with the terminal "c ₉ "through the ninth high-resistance resistor R ₉ is grounded, the nineteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the ninth microprocessor 13.9; the output of the ninth microprocessor 13.9 is connected to the ninth primary winding of the transformer Tr.1 through the terminal "a9", and the terminal "d9" of the ninth primary winding of the transformer Tr.1 is grounded; the tenth input 10 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the tenth switch Vk.10, through the tenth valve D ₁₀ , through the tenth terminal "c ₁₀ " with the first input 1 of the tenth microprocessor 13.10, in parallel with the terminal "c ₁₀ "through the tenth high-resistance resistor R ₁₀ is grounded, the twentieth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the tenth microprocessor 13.10; the output of the tenth microprocessor 13.10 is connected to the tenth primary winding of the transformer Tr.1 through the terminal "a10", and the terminal "d10" of the tenth primary winding of the transformer Tr.1 is grounded; the secondary winding of the transformer Tr.1 is connected by terminal "c" to the output of the analytical unit 13 of weak NQR signals, and the secondary winding of the transformer Tr.1 is grounded by the terminal "k".

On FIG. 39 shows the ambient temperature control unit 14 containing the temperature converter - electric potential 14.1 and the ten-pin switch Vk.14.2, while the output of the temperature converter - electric potential 14.1 is connected in parallel with the terminal "b" of each switch from the first switch 1 to the tenth switch 10 in the ten-pin switch Vk.14.2, terminal "a" of the first switch 1 is connected to the eleventh output of the ambient temperature control unit 14, terminal "a" of the second switch 2 is connected to the twelfth output of the ambient temperature control unit 14, terminal "a" of the third switch 3 is connected to the thirteenth output of the ambient temperature control unit 14, the terminal "a" of the fourth switch 4 is connected to the fourteenth output of the ambient temperature control unit 14, the terminal "a" of the fifth switch 5 is connected to the fifteenth output of the ambient temperature control unit 14, the terminal "a" of the sixth switch 6 is connected to the gear the tenth output of the ambient temperature control unit 14, the terminal "a" of the seventh switch 7 is connected to the seventeenth output of the ambient temperature control unit 14, the terminal "a" of the eighth switch 8 is connected to the eighteenth output of the ambient temperature control unit 14, the terminal "a" of the ninth switch 9 is connected to the nineteenth output of the ambient temperature control unit 14, terminal "a" of the tenth switch 10 is connected to the twentieth output of the ambient temperature control unit 14.

The operation of the device for detecting signals of nuclear quadrupole resonance.

The purpose of the present invention is:

- increasing the efficiency of the devices during one-time and cyclic operation of blocks of frequency pulse shapers 2 and time pulses 3; increasing the analysis of the frequency properties of the field of the objects under study and their levels based on the improvement of the system;

- increasing the weight and size characteristics of the device based on replacement in oscillatory systems from 11.1 to 11.10, built on the use of traditional capacitance and inductance with low weight and size characteristics, microcircuits called gyrators: capacitive gyrator G _C and inductive gyrator G _L ;

- increasing the efficiency of the analysis of the frequency properties of weak radiated fields of the objects under study and their levels based on the introduction of feedback, which ensures the detection of quadrupole resonance frequencies and their use for excitation in the studied media, taking into account the temperature of the media.

The operation of the device for detecting nuclear quadrupole resonance signals is based on the creation of conditions for energy transfer through the media interface. It is known that a normally polarized wave at the air-semiconducting medium interface has no attenuation. Moreover, an electromagnetic wave arising in a semiconducting medium is a plane wave propagating deep into the medium in the direction of the normal to the interface between the media and undergoes absorption determined by the parameters of the second medium. The task of searching for nuclear quadrupole resonance signals in media with magnetic properties is a difficult task; therefore, this work is aimed at developing a device that provides signal detection in the presence of magnetic properties of the medium under study. The penetration depth is determined by the skin layer. This law is established by the Leontovich-Shchukin boundary conditions. Consequently, for maximum excitation of the second medium, it is necessary to irradiate it with a normally polarized wave. To do this, let us analyze the propagation of electromagnetic wave energy through the interface between media.

It is known that the propagation of electromagnetic waves in real conditions is accompanied by the phenomena of reflection and refraction of waves at the interface between different media. The reflection of electromagnetic waves from the interface between media, as a rule, is not complete. Along with reflected waves, there are also refracted waves, due to which the energy of the incident wave from one medium partially passes through the interface into the second medium. In practice, it is very important to determine the spatial orientation, amplitude and phase of the field vectors and the direction of propagation of the reflected and refracted waves. In a number of cases, when the interfaces between media can be considered plane with sufficient accuracy, the problem posed is solved relatively simply, since for a plane incident wave, the reflected and refracted waves will also be plane.

On FIG. Figures 2.1 and 2.2 show graphs for reflection coefficients only. As we can see from Figures 3 and 4, for μ ₂ >ξ _2, the reflection coefficient of a parallel polarized wave loses the Brewster angle and asymptotically shifts to the straight line P _II =1. For a normally polarized wave, on the contrary, the Brewster angle appears only when μ ₂ >ξ ₂ , as μ ₂ grows, it shifts to 90°.

And the last case, when the second medium, having magnetic properties, has magnetic losses, that is, ξ _k1 \u003d 1, ξ _k2 \u003d ξ ₂ , μ _k1 =1, μ _k2 \u003d μ ₂ -iσ _m2 / ωμ ₀ .

The calculation results are shown in the graphs of Fig. 2.1 and Fig 2.2.

For a normally polarized wave, the Brewster angle appears only when μ ₂ >ξ ₂ , as μ ₂ grows, it shifts to 90°.

And the last case, when the second medium, having magnetic properties, has magnetic losses, that is, ξ _k1 \u003d 1, ξ _k2 \u003d ξ ₂ , μ _k1 \u003d 1, μ _k2 \u003d μ ₂ -iσ _m2 / ωμ ₀ , The calculation results are presented in the graphs Fig. 2.3.

The calculated graphs show curves reflecting the change in the Fresnel coefficients at an electromagnetic wave frequency of 10 MHz, ξ ₂ =10 and σ _m2 =10, as well as various indicators μ ₂ , which gives magnetic losses in the region of 10 ^-4 ... 10 ^-3 , which are quite consistent with the properties ferrites.

Also, as in the case of the complex permittivity, the presence of σ _m2 causes a change in the phase of the vector of electric strength of the electromagnetic

waves, which reflects the argument of the complex Fresnel coefficient, but at low magnetic losses, the phase changes are also insignificant.

The obtained calculations for media with magnetic properties show that the reflection is minimal when the relative permittivity and permeability are equal, even if these coefficients individually are quite high. In the considered case, at μ ₂ =ξ ₂ =10, the normally incident wave is practically not reflected. The same is observed for other values of μ ₂ =ξ ₂ .

Thus, a normally polarized wave is the most promising for excitation of nuclear quadrupole resonance in the study of objects located in media.

(Literature: 1. Markov G.T., Petrov B.M., Grudinskaya G.P. Electrodynamics and propagation of radio waves - M .: "Sov. Radio", 1979. - 374 p.

2. Terletsky Ya.P., Rybakov Yu.P. Electrodynamics: Proc. allowance for physics students. specialist. universities; 2nd ed., revised. - M.: Higher school, 1990. - 352 p.

3. Goldstein L.D., Zernov N.V. Electromagnetic fields and waves - M .: "Sov. Radio", 1971. - 664 p.)

Based on the research performed, a feature of this device is the use of normally polarized waves near the interface between media.

The nuclear quadrupole resonance signal detection device shown in FIG. 1 fully gives an idea of the work. To radiate a magnetic field in a given direction, and this is shown as "incident magnetic flux", a reasonable configuration of the irradiating system is adopted. Radiating elements 7 ₁ (also 7 ₂ ; 7 ₃ ; ...; 7 _N-1 ; 7 _N ) are placed between two closed cylindrical surfaces, which are presented as a "screen of the radiating system". In a closed volume, between the screens, there are blocks for generating the studied frequencies: a sweep frequency generator 1 through an operating mode selection block 4 connected to the input of a power amplifier 5.1, through one of the blocks, depending on the selected operating mode. In this case, the output of the sweep frequency generator 1 is connected in parallel with the first input of the operation mode selection unit 4 through the frequency pulse shaper 2, through the first switch Vk.1, and with the second input of the operation mode selection unit 4 through the temporary pulse shaper 3, through the second switch Vk. 2, and the third input of the operating mode selection block 4 is connected through the third switch Vk.3 to the output of the block for studying the emission spectrum of nuclear quadrupole resonance signals 12 or to the output of the analytical block 13 of weak NQR signals, the ambient temperature control block 14 .; the output of the power amplifier 5.1 is connected in parallel with the input of the matching device of the transmitting system 5.2 and through the "n ₁ "input with the information generator of the receiving system 9; "n" outputs of the matching device of the transmitting system 5.2 are connected to each of the "n" emitter system 7 through the "g" terminal, starting from 7 ₁ to 7 _N (Fig. 1).

The formation of a powerful magnetic flux of a normally polarized wave is carried out by excitation of the flux in the ferrite rods F1 and F2 by the current in two windings of the transformer Tr.1, the primary winding of which is connected to the output of the matching device 5.

On FIG. 3 shows one of the identical radiators 7 ₁ of the transmitting in-phase antenna system, which excites a normally polarized electromagnetic wave with the vectors Er and Hr near the air-surface interface of the investigated medium 7, containing F1 and F2 - two cylindrical ferrite cores located horizontally and forming a single radiator normally polarized wave, K1 and K2 - two frame transmitting antennas with uniform frequency properties in the frequency range from 10 kHz to 10 MHz, placed on ferrite cores F1 and F2, and exciting the magnetic flux in the ferrite; a matching transformer Tr.1 with one primary 1 and two secondary windings 2.1 and 2.2, a matching device of the transmission system 5, while the matching transformer Tr.1 is connected by the primary winding to one of the outputs of the matching device of the transmission system 5; and the secondary winding of the transformer Tr.1 is two-section: the first section 2.1 is connected by terminal "a" to the terminal "g1" of the first loop transmitting antenna K1, and by terminal "b" the first section 2.1 is connected to the terminal "g2" of the first loop transmitting antenna K1; the second section 2.2 of the transformer Tr.1 is connected by terminal "g" to the terminal "g3" of the second loop transmitting antenna K2, and the second section 2.2 is connected by terminal "b" to the terminal "g4" of the second loop transmitting antenna K2.

On FIG. 4 shows the structure of the emitter Ф1 (Ф2), as one of the elements in each of N emitters, containing three ferrite cores, each with a diameter of d=4 mm, made using the technology of a three-component structure with magnetic permeability μ=T000, μ=100 and μ=T0; on top of three ferrite cores, coils of conductors of three windings Ob.1, Ob.2 and Ob.3 of the loop antenna are placed, with a conductor cross section of 0.5 mm, 35 turns are located on each core with a length of l \u003d 3 cm, and all three loop antennas are connected in series and form a single circuit with a spatially unidirectional current i flowing between the terminals "g1" and "g2"; moreover, all three loop antennas with ferrite cores form a single radiator, shown in Fig. 3 as F1 or F2.

On FIG. 5 shows graphs of the input resistance of the emitter Ф1 (Ф2), and curve 1 shows the change in the input resistance in the frequency range from 10 kHz to 10 MHz for three ferrite cores, each with a cross-sectional diameter of d=4 mm, made using the technology of a three-component structure with a magnetic permeability μ=1000, μ=100 and μ=10, on top of three ferrite cores are coils of conductors of three windings Ob.1, Ob.2 and Ob.3 of the loop antenna, with a conductor cross section of 0.5 mm, on each core with a length l=3 cm is located in 35 turns, and all three loop antennas are connected in series and form a single circuit with a spatially unidirectional current i flowing between the terminals "g1" and "g2", a change in the input resistance in the frequency range is permissible; and curve 2 shows the change in the input resistance in the frequency range from 10 kHz to 10 MHz for three ferrite cores, each with a cross-sectional diameter of d=4 mm, made using the technology of a three-component structure with magnetic permeability μ=1000, μ=100 and μ=10 , over three ferrite cores are placed turns of conductors of three windings Ob.1, Ob.2 and Ob.3 of the loop antenna, with a conductor cross section of 0.5 mm, 100 turns are located on each core with a length of l \u003d 3 cm, this option for changing the input resistance in frequency range is not allowed.

On FIG. 6 shows an element of a receiving antenna containing three loop antennas with ferrite cores, all three loop antennas being connected in series and forming a single circuit with an induced current in them, spatially unidirectional i, flowing between terminals "P1" and "P2"; three ferrite cores, each with a diameter of d=4 mm, made according to the technology of a three-component structure with magnetic permeability μ=1000, μ=100 and μ=10; on top of three ferrite cores, coils of conductors of three windings of a loop antenna are placed, with a conductor cross section of 0.5 mm, 35 turns are located on each core with a length of l \u003d 3 cm, and all three loop antennas are connected in series and placed in a vertical plane with a separation angle of 60 ° between loop antennas with ferrite cores.

On FIG. 7 shows a receiving antenna of circular polarization 6 ₁₁ containing two elements of the receiving antenna 6 ₁₁ .1 and 6 ₁₁ .2, as elements of a system consisting of N receiving antennas in each line from the first 6 ₁₁ to 6 _1N and N lines in the system from the first 6 _1N by 6 _NN , while in each element, for example, 6 ₁₁ . 1 has three loop antennas with ferrite cores, and three loop antennas A1, A2 and A3 are connected in series and form a single circuit with an induced current in them, spatially unidirectional i, flowing between terminals "P1" and "P2", and in element 6 ₁₁ .2 three loop antennas A4, A5 and A6 are connected in series and form a single circuit with induced current in them, spatially unidirectional r, flowing between terminals "P3" and "P4"; six loop antennas with ferrite cores A1, A2, A3, A4, A5 and A6 are located in a vertical plane and form a circular polarization reception, including the reception of both a normally polarized wave on the loop antennas A2 and A5, and a parallel polarized wave on the loop antennas A1, A3, A4 and A6; moreover, radio reception is carried out simultaneously by elements 6 ₁₁ .1 and 6 ₁₁ .2 based on the operation of the summing transformer Tr.1 containing one primary winding 1 and two secondary windings, while the primary winding is connected to the input terminals of the information generator of the receiving system 9, at the same time the first secondary winding 2 ₁ transformer Tr.1 terminal "a" is connected to the terminal "Sh", and terminal "b" to the terminal "P2" element 6 ₁₁ .1, the second secondary winding 2 ₂ transformers Tr.1 terminal "c" is connected to the terminal "P4 ”, and the terminal “e” to the terminal “P3” of element 6 ₁₁ .2.

The receiving part of the device for detecting nuclear quadrupole resonance signals, shown in Fig. 1 is represented by a receiving antenna system 6 containing N in-phase receiving antenna lines, which are connected to the “and” inputs of the information generator of the receiving system 9. The output of the information generator of the receiving system 9 is connected through a filter unit 10, the output of the filter unit 10 is connected in parallel with the first input of the analytical block 13 of weak NQR signals, and through the block for analyzing the spectrum of signals of nuclear quadrupole resonance 11 with the block for studying the spectrum of radiation of signals of nuclear quadrupole resonance 12 and through the latter, i.e. a block for studying the radiation spectrum of nuclear quadrupole resonance signals 12 with the terminal "e" of the third switch Vk.3, and the output of the analytical block 13 of weak NQR signals with the terminal "d" of the third switch Vk.3, the second input of the analytical block 13 is connected to the output of the temperature control unit environment 14 (Fig. 1).

On FIG. 8 shows a transceiver antenna system, where 6 are elements of a receiving antenna system consisting of N receiving antennas in each line from the first 6 ₁₁ to 6 _1N and N lines in the system from the first 6 _1N to 6 _NN ; in addition, 7 - elements of the transmitting antenna system containing N emitters from the first 7 ₁ to N - 7 _N .

To create radiation that excites signals of nuclear quadrupole resonance, a frequency pulse shaper 2 is used.

On FIG. 9 shows a frequency pulse shaper 2, where the first shaper of groups of one-millisecond frequency pulses 2.1, the second shaper of groups of two-millisecond frequency pulses 2.2, the third shaper of groups of three-millisecond frequency pulses 2.3, the fourth shaper of groups of four-millisecond frequency pulses 2.4, the generator of one-millisecond pulses 2.5, four four-contact switches: Vk .1, Vk.2, Vk.3 and Vk.4; four elements of AND: the first 2.6, the second 2.7, the third 2.8 and the fourth 2.9; four buttons for a one-time start of the work of four shapers: Kn.1, Kn.2, Kn.3 and Kn.4; while the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the first element And 2.6 and to the second input of the first element And 2.6 through the first button Kn.1 for a one-time start of the first generator, the output of the first element And 2.6 is connected to the first input of the first group generator one-millisecond frequency pulses 2.1, the first output of the first shaper of groups of one-millisecond frequency pulses 2.1 is connected to the output of the shaper of frequency pulses 2 through the terminals "c" and "e" of the first four-pin switch Vk.1, the second output of the first shaper of groups of one-millisecond frequency pulses 2.1 is connected to the second input the first element And 2.6 through the terminals "a" and "b" of the first four-contact switch Vk.1 for cyclic operation of the first shaper; the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the second element And 2.7 and to the second input of the second element And 2.7 through the second button Kn. pulses 2.2, the first output of the second generator of groups of two-millisecond frequency impulses 2.2 is connected to the output of the generator of frequency impulses 2 through the terminals "c" and "d" of the second four-pin switch Vk.2, the second output of the second generator of groups of two-millisecond frequency impulses 2.2 is connected to the second input of the second element And 2.7 through terminals "a" and "b" of the second four-contact switch Vk.2 for cyclic operation of the second shaper; the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the third element And 2.8 and to the second input of the third element And 2.8 through the third button Kn. pulses 2.3, the first output of the third generator of groups of three-millisecond frequency impulses 2.3 is connected to the output of the generator of frequency impulses 2 through the terminals "c" and "d" of the third four-pin switch Vk.3, the second output of the third generator of groups of three-millisecond frequency impulses 2.3 is connected to the second input of the third element And 2.8 through the terminals "a" and "b" of the third four-contact switch Vk.3 for cyclic operation of the third shaper; the output of the one-millisecond pulse generator 2.5 is connected in parallel directly to the first input of the fourth element And 2.9 and to the second input of the fourth element And 2.9 through the fourth button Kn. pulses 2.4, the first output of the fourth generator of groups of four-millisecond frequency impulses 2.4 is connected to the output of the generator of frequency impulses 2 through the terminals "c" and "d" of the fourth four-pin switch Vk.4, the second output of the fourth generator of groups of four-millisecond frequency impulses 2.4 is connected to the second input of the fourth element And 2.9 through the terminals "a" and "b" of the fourth four-contact switch Vk.4 for cyclic operation of the fourth shaper; the input of the frequency pulse shaper 2 is connected in parallel with the second input of the first shaper of groups of one-millisecond frequency pulses 2.1, with the second input of the second shaper of groups of two-millisecond frequency pulses 2.2, with the second input of the third shaper of groups of three-millisecond frequency pulses 2.3 and with the second input of the fourth shaper of groups of four-millisecond frequency pulses 2.4 .

When closing a four-contact switch of one of the four: for example, for Vk.1 when closing terminals "a" and "b" and terminals "c" and "d", in the case of switched off switches Vk.2, Vk.3 and Vk.4, cyclic operation of the generator of groups of one-millisecond frequency impulses 2.1 is carried out, and when only terminals “c” and “d” are closed and terminals “a” and “b” of the first switch Vk.1 are open, for one-time operation of the generator of groups of one-millisecond frequency impulses 2.1, it is necessary to press the first button Kn.1, only three groups of pulses will appear at the output of the frequency pulse shaper 2. Also, when terminals “a” and “b” and terminals “c” and “d” of the second switch Vk.2 are closed, in the case of switched off switches Vk.1, Vk.3 and Vk.4, the generator of two-millisecond frequency groups is cyclically pulses 2.2, and when the terminals "c" and "d" are closed and the terminals "a" and "b" of the second switch Vk.2 are closed, for a one-time operation of the shaper of groups of two-millisecond frequency pulses 2.2, it is necessary to press the second button Kn.2, at the output of the pulse shaper frequency 2, only three groups of pulses will appear. In a similar way, it is launched for a one-time operation or cyclic for the third shaper of groups of three-millisecond frequency pulses 2.3 and for the fourth shaper of groups of four-millisecond frequency pulses 2.4. based on the closure of the terminals of the switches Vk.3 and Vk.4.

Theoretical studies have shown the necessary duration of the pulses and their frequency filling. It is advisable to consider circuit solutions for pulse shaping units.

On FIG. 10 shows the first generator of groups of one-millisecond frequency pulses 2.1, where the first gate B.1, the second gate B.2, the third gate B.3, the fourth gate B.4, the fifth gate B.5, the sixth gate B.6, the seventh gate B .7, eighth gate B.8, ninth gate B.9, tenth gate B.10, first delay line for 2 ms 15.1, second delay line for 2 ms 15.2, third delay line for 4 ms 16, fourth delay line for 2 ms 15.3, fifth delay line for 4 ms 17, one-millisecond trigger 18, sixth delay line for 8 ms 19, seventh delay line for 10 ms 20, first element AND 21.1, second element AND 21.2, frequency multiplier by two button Kn.1 (Fig. 9), to start the one-millisecond trigger 18, for a short time, the one-millisecond pulse generator 2.5 of the frequency pulse shaper 2 is connected to the first input of the first shaper of groups of one-millisecond frequency pulses 2.1, the first input is connected to the input of the one-millisecond trigger 18; the output of the one-millisecond trigger 18 is connected in parallel with the input of the sixth delay line for 8 ms 19, and through the first gate B.1, through the first delay line for 2 ms 15.1 with the second input of the first element AND 21.1, also through the second gate B.2 with the second input the first element AND 21.1; the output of the sixth delay line for 8 ms 19 is connected in parallel with the input of the seventh delay line for 10 ms 20, and through the third gate B.3 and through the second delay line for 2 ms 15.2 with the second input of the second element And 21.2, also through the fourth gate B. 4 and through the third delay line for 4 ms 16 with the second input of the first element And 21.1, as well as through the fifth gate B.5 with the second input of the first element And 21.1; the output of the seventh delay line for 10 ms 20 is connected in parallel through the sixth gate B.6 through the fourth delay line for 2 ms 15.3 with the second input of the first element AND 21.1, and through the seventh gate B.7 and through the fifth delay line for 4 ms 17 in parallel through the ninth gate B.9 with the second input of the second element AND 21.2, and through the tenth gate B.10 with the second output of the first generator of groups of one-millisecond frequency pulses 2.1, in addition, the output of the seventh delay line for 10 ms 20 is connected through the eighth gate B.8 with the second input of the second element And 21.2; the output of the second element And 21.2 connected to the first output of the first shaper groups of one-millisecond frequency pulses 2.1; the second input of the first generator of groups of one-millisecond frequency pulses 2.1 is connected in parallel with the first input of the first element And 21.1 and through a frequency multiplier by two 22 with the first input of the second element And 21.2; the output of the first element And 21.1 connected to the first output of the first shaper groups of one-millisecond frequency pulses 2.1. As you can see, the start of the shaper is carried out by pressing the VK.1 button in the frequency pulse shaper 2 both for a one-time start of the shaper of groups of one-millisecond frequency pulses 2.1, and for its cyclic operation.

On FIG. 11 shows the distribution of pulses and their duration, which are formed by the first group generator of one-millisecond frequency pulses 2.1, where the duration of all pulses generated by the first group generator of one-millisecond groups with frequency filling of pulses corresponds to τ=1 ms, and three groups of pulses are formed: the first group is two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 12 shows the second generator of groups of two-millisecond frequency pulses 2.2, where the eleventh gate B.11, the twelfth gate B.12, the thirteenth gate B.13, the fourteenth gate B.14, the fifteenth gate B.15, the sixteenth gate B.16, the seventeenth gate B .17, eighteenth gate B.18, nineteenth gate 19, twentieth gate B.20, first delay line for 3 ms 23, second delay line for 3 ms 24, third delay line for 6 ms 25, fourth delay line for 3 ms 26 , the fifth delay line for 6 ms 27, the two-millisecond trigger 28, the sixth delay line for 10 ms 29, the seventh delay line for 13 ms 30, the first element AND 31.1, the second element AND 31.2, the frequency multiplier by two 32, while the second button Kn .2 (Fig. 9) trigger two-millisecond trigger 28 for a short time, the generator 2.5 is connected to the first input of the second shaper of groups of two-millisecond frequency pulses 2.2, the first input of the second shaper of groups of two-millisecond frequency pulses 2.2 with Shared with 2ms trigger input 28; the output of the two-millisecond trigger 28 is connected in parallel with the input of the sixth delay line for 10 ms 29, and through the eleventh gate B.11 and through the first delay line for 3 ms 23 with the second input of the first element AND 31.1, also the output of the two-millisecond trigger 28 is connected through the twelfth gate B .12 with the second input of the first element AND 31.1; the output of the sixth delay line for 10 ms 29 is connected in parallel with the input of the seventh delay line for 13 ms 30, and through the thirteenth gate B.13 and through the second delay line for 3 ms 24 with the second input of the second element And 31.2; also, the output of the sixth delay line for 10 ms 29 is connected through the fourteenth gate B.14 and through the third delay line for 6 ms 25 with the second input of the first element And 31.1, and the output of the sixth delay line for 10 ms 29 is connected through the fifteenth gate B.15 with the second input of the first element And 31.1; the output of the seventh delay line for 13 ms 30 is connected in parallel through the sixteenth gate B.16 and through the fourth delay line for 3 ms 26 with the second input of the first element And 31.1, also the output of the seventh delay line for 13 ms 30 through the eighteenth gate B.18 is connected to the second input of the second element And 31.2, and the output of the seventh delay line for 13 ms 30 is connected through the seventeenth gate B.17 and through the fifth delay line for 6 ms 27 in parallel: through the nineteenth gate B.19 with the second input of the second element And 31.2, and through the twentieth valve 20 with the second output of the second shaper groups of two millisecond frequency pulses 2.2; the output of the second element And 31.2 is connected to the first output of the second generator groups of two-millisecond frequency pulses 2.2; the second input of the second shaper of groups of two-millisecond frequency pulses 2.2 is connected in parallel with the first input of the first element And 31.1 and also through a frequency multiplier by two 32 with the first input of the second element And 31.2; the output of the first element And 31.1 is connected to the first output of the second generator groups of two-millisecond frequency pulses 2.2. As you can see, the start of the shaper is carried out by pressing the VK.2 button in the frequency pulse shaper 2, both for a one-time start of the shaper of groups of two-millisecond frequency pulses 2.2, and for its cyclic operation.

On FIG. 13 shows the temporal distribution of pulses and their duration, which are formed by the second generator of groups of two-millisecond frequency pulses 2.2, where the duration of all pulses created by the second group generator are two-millisecond with frequency filling of pulses, i.e. corresponds to τ=2 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 14 shows the third generator of groups of three-millisecond frequency pulses 2.3, where the twenty-first gate B.21, the twenty-second gate B.22, the twenty-third gate B.23, the twenty-fourth gate B.24, the twenty-fifth gate B.25, the twenty-sixth gate B .26, twenty-seventh gate B.27, twenty-eighth gate B.28, twenty-ninth gate B.29, thirtieth gate 30, first delay line for 4 ms 33, second delay line for 4 ms 34, third delay line for 8 ms 35, fourth delay line for 4 ms 36, fifth delay line for 8 ms 37, sixth delay line for 12 ms 39, seventh delay line for 16 ms 40, three millisecond trigger 38, first element AND 41.1, second element AND 41.2, frequency multiplier by two 42, while the third button Kn.3 (Fig. 9) trigger three-millisecond trigger 38 for a short time generator of one-millisecond pulses 2.5 shaper 2 is connected to the first input of the third shaper groups of three-millisecond frequency pulses 2.3, the first th input of the third shaper groups of three-millisecond frequency pulses 2.3 is connected to the input of the three-millisecond trigger 38; the output of the three-millisecond trigger 38 is connected in parallel with the input of the sixth delay line for 12 ms 39, and through the twenty-first gate B.21 and through the first delay line for 4 ms 33 with the second input of the first element And 41.1; in parallel, the output of the three-millisecond trigger 38 is connected through the twenty-second gate B.22 to the second input of the first element And 41.1; the output of the sixth delay line for 12 ms 39 is connected in parallel with the input of the seventh delay line for 16 ms 40, in parallel the output of the sixth delay line for 12 ms 39 through the twenty-third gate B.23 and through the second delay line for 4 ms 34 is connected to the second input of the second element And 41.2, also the output of the sixth delay line for 12 ms 39 is connected through the twenty-fourth gate B.24 and through the third delay line for 8 ms 35 with the second input of the first element And 41.1, as well as the output of the sixth delay line for 12 ms 39 is connected through twenty-fifth valve B.25 with the second input of the first element And 41.1; the output of the seventh delay line for 16 ms 40 is connected in parallel through the twenty-sixth gate B.26 and through the fourth delay line for 4 ms 36 with the second input of the first element And 41.1, and the output of the seventh delay line for 16 ms 40 is connected through the twenty-seventh gate B. 27, through the fifth delay line for 8 ms 37 in parallel: through the twenty-ninth gate B.29 with the second input of the second element And 41.2, and through the thirtieth gate 30 with the second output of the third generator of groups of three-millisecond frequency pulses 2.3; in addition, the output of the seventh delay line for 16 ms 40 is connected through the twenty-eighth gate B.28 with the second input of the second element And 41.2; the output of the second element And 41.2 connected to the first output of the third shaper groups of three-millisecond frequency pulses 2.3; the second input of the third shaper of groups of three-millisecond frequency pulses 2.3 is connected in parallel with the first input of the first element And 41.1 and also through a frequency multiplier by two 42 with the first input of the second element And 41.2; the output of the first element And 41.1 is connected to the first output of the third shaper groups of three-millisecond frequency pulses 2.3. As you can see, the shaper is started by pressing the Vk.3 button in the frequency pulse shaper 2, both for a one-time start of the shaper of groups of three-millisecond frequency pulses 2.3, and for its cyclic operation.

On FIG. 15 shows the temporal distribution of pulses and their duration, which are generated by the third group generator of three-millisecond frequency pulses 2.3, where the duration of all impulses generated by the third group generator are three-millisecond with frequency filling of pulses, i. corresponds to τ=3 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 16 shows the fourth generator of groups of four-millisecond frequency pulses 2.4, where the thirty-first gate B.31, the thirty-second gate B.32, the thirty-third gate B.33, the thirty-fourth gate B.34, the thirty-fifth gate B.35, the thirty-sixth gate B .36, thirty-seventh gate B.37, thirty-eighth gate B.38, thirty-ninth gate B.39, fortieth gate B.40 first delay line for 5 ms 43, second delay line for 5 ms 44, third delay line for 10 ms 45, fourth delay line for 5 ms 46, fifth delay line for 10 ms 47, four millisecond trigger 48, sixth delay line for 14 ms 49, seventh delay line for 19 ms 50, first element AND 51.1, second element AND 51.2, multiplier frequency by two 52, while the fourth button Kn.4 (Fig. 9) triggering the four-millisecond trigger 48 for a short time, the one-millisecond pulse generator 2.5 of the shaper 2 is connected to the first input of the fourth shaper of the four-millisecond frequency groups x pulses 2.4, the first input of the fourth generator groups of four-millisecond frequency pulses 2.4 is connected to the input of the four-millisecond trigger 48; the output of the four-millisecond trigger 48 is connected in parallel with the input of the sixth delay line for 14 ms 49, and through the thirty-first gate B.31 and through the first delay line for 5 ms 43 with the second input of the first element And 51.1, also the output of the four-millisecond trigger 48 is connected through the thirty-second valve B.32 with the second input of the first element And 51.1; the output of the sixth delay line for 14 ms 49 is connected in parallel with the input of the seventh delay line for 19 ms 50, and the output of the sixth delay line for 14 ms 49 through the thirty-third gate B.33 and through the second delay line for 5 ms 44 is connected to the second input the second element And 51.2; also the output of the sixth delay line for 14 ms 49 is connected through the thirty-fourth gate B.34 and through the third delay line for 10 ms 45 with the second input of the first element And 51.1; and also the output of the sixth delay line for 14 ms 49 is connected through the thirty-fifth gate B.35 with the second input of the first element And 51.1; the output of the seventh delay line for 19 ms 50 is connected in parallel through the thirty-sixth gate B.36 and through the fourth delay line for 5 ms 46 with the second input of the first element And 51.1, and the output of the seventh delay line for 19 ms 50 is connected through the thirty-seventh gate B. 37 and through the fourth delay line for 10 ms 47 in parallel: through the thirty-ninth gate B.39 with the second output of the second element And 51.2, and through the fortieth gate B.40 with the second output of the fourth generator of groups of four-millisecond frequency pulses 2.4; in addition, the output of the seventh delay line for 19 ms 50 is connected through the thirty-eighth gate B.38 with the second input of the second element And 51.2; the output of the second element And 51.2 is connected to the output of the fourth generator groups of four-millisecond frequency pulses 2.4; the second input of the fourth generator groups of four-millisecond frequency pulses 2.4 is connected in parallel with the first input of the first element And 51.1 and also through a frequency multiplier by two 52 with the first input of the second element And 51.2; the output of the first element And 51.1 is connected to the first output of the fourth generator groups of four-millisecond frequency pulses 2.4. As you can see, the shaper is started by pressing the Vk.4 button in the frequency pulse shaper 2, both for a one-time start of the four-millisecond frequency pulse group shaper 2.4, and for its cyclic operation.

On FIG. 17 shows the temporal distribution of pulses and their duration, which are generated by the fourth generator of groups of four-millisecond frequency pulses 2.4, corresponds to τ=4 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 Hz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ .

On FIG. 18 shows a temporary pulse shaper 3, where the first shaper of groups of one- and two-millisecond pulses 3.1, the second shaper of groups of two- and four-millisecond pulses 3.2, the third shaper of groups of three- and six-millisecond pulses 3.3, the fourth shaper of groups of four- and eight-millisecond pulses 3.4, the generator of one-millisecond impulses 3.5, four four-contact switches: Vk.1, Vk.2, Vk.3 and Vk.4; four elements of AND: the first 3.6, the second 3.7, the third 3.8 and the fourth 3.9; four buttons for a one-time start of the work of four shapers: Kn.1, Kn.2, Kn.3 and Kn.4; while the output of the one-millisecond pulse generator 3.5 is connected to the first input of the first generator of groups of one- and two-millisecond pulses 3.1 through the first input of the first element And 3.6, in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the first element And 3.6 through the first button Kn.1 for a one-time start the operation of the first shaper 3.1, the first output of the first shaper of groups of one- and two-millisecond pulses 3.1 is connected to the output of the shaper of temporary pulses 3 through the terminals "c" and "d" of the first four-pin switch Vk.1, and the second output of the first shaper of groups of one- and two-millisecond pulses 3.1 is connected to the second input of the first element And 3.6 through terminals "a" and "b" of the first four-contact switch Vk.1 for cyclic operation of the first shaper of groups of one- and two-millisecond pulses 3.1; the output of the one-millisecond pulse generator 3.5 is connected to the first input of the second generator of groups of two- and four-millisecond pulses 3.2 through the first input of the second element And 3.7, and in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the second element And 3.7 through the second button Kn.2 for a one-time start the operation of the second generator 3.2, the first output of the second generator of groups of two- and four-millisecond pulses 3.2 is connected to the output of the generator of temporary impulses 3 through the terminals "c" and "d" of the second four-contact switch Vk.2, and the second output of the second generator of groups of two- and four-millisecond pulses 3.2 is connected to the second input of the second element And 3.7 through the terminals "a" and "b" of the second four-contact switch Vk.2 for cyclic operation of the second shaper of groups of two- and four-millisecond pulses 3.2; the output of the one-millisecond pulse generator 3.5 is connected to the first input of the third generator of groups of three- and six-millisecond pulses 3.3 through the first input of the third element And 3.8, in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the third element And 3.8 through the third button Kn.3 for a one-time start of work of the third shaper 3.3, the first output of the third shaper of groups of three- and six-millisecond pulses 3.3 is connected to the output of the shaper of temporary pulses 3 through the terminals "c" and "d" of the third four-pin switch Vk.3, and the second output of the third shaper of groups of three- and six-millisecond pulses 3.3 connected to the second input of the third element And 3.8 through the terminals "a" and "b" of the third four-contact switch Vk.3 for cyclic operation of the third shaper of groups of three- and six-millisecond pulses 3.2; the output of the one-millisecond pulse generator 3.5 is connected to the first input of the fourth generator of groups of four- and eight-millisecond pulses 3.4 through the first input of the fourth element And 3.9, in parallel the output of the one-millisecond pulse generator 3.5 is connected to the second input of the fourth element And 3.9 through the fourth button Kn. shaper 3.4, the first output of the fourth shaper of groups of four- and eight-millisecond pulses 3.4 is connected to the output of the shaper of temporary pulses 3 through the terminals "c" and "e" of the fourth four-pin switch Vk.4, and the second output of the fourth shaper of groups of four- and eight-millisecond pulses 3.4 is connected with the second input of the fourth element AND 3.9 through terminals "a" and "b" of the fourth four-contact switch Vk.4 for cyclic operation of the fourth generator of groups of four- and eight-millisecond pulses 3.4.; the input of the temporary pulse shaper 3 is connected in parallel with the second input of the first shaper of groups of one- and two-millisecond pulses 3.1, with the second input of the second shaper of groups of two- and four-millisecond pulses 3.2, with the second input of the third shaper of groups of three- and six-millisecond pulses 3.3 and with the second input of the fourth shaper of groups of four- and eight-millisecond pulses 3.4.

When closing a four-contact switch of one of the four: for example, for Vk.1 when closing terminals "a" and "b" and terminals "c" and "d", in the case of switched off switches Vk.2, Vk.3 and Vk.4, cyclic operation of the first generator of groups of one- and two-millisecond pulses 3.1 is carried out, and when only terminals “c” and “d” are closed and terminals “a” and “b” of the first switch Vk.1 are open, for one-time operation of the first generator of groups of one- and two-millisecond pulses 3.1, it is necessary to press the first button Kn.1, only three groups of pulses will appear at the output of the temporary pulse shaper 3.1. Also, when terminals “a” and “b” and terminals “c” and “d” of the second switch Vk.2 are closed, in the case of switched off switches Vk.1, Vk.3 and Vk.4, the generator of groups of two- and four-millisecond pulses 3.2, and when the terminals "c" and "e" are closed and the terminals "a" and "b" of the second switch Vk.2 are open, for a one-time operation of the shaper of groups of two- and four-millisecond pulses 3.2, it is necessary to press the second button Kn.2, only three groups of pulses will appear at the output of the temporary pulse shaper 3. In a similar way, it is launched for a one-time operation or cyclic for the third generator of groups of three- and six-millisecond pulses 3.3 and for the fourth generator of groups of four- and eight-millisecond pulses 3.4. based on the closure of the terminals of the switches Vk.3 and Vk.4.

Theoretical studies have shown the necessary duration of the pulses and their frequency filling. It is advisable to consider circuit solutions for pulse shaping units.

On FIG. 19 shows the first generator of groups of one and two millisecond pulses 3.1, where the first gate is B.41, the second gate is B.42, the third gate is B.43, the fourth gate is B.44, the fifth gate is B.45, the sixth gate is B.46, the seventh gate B.47, eighth gate B.48, ninth gate B.49, first delay line by 2 ms. 53, the second delay line for 8ms 54, the third delay line for 13ms 55, the fourth delay line for 22ms 56, the fifth delay line for 10ms 57, the sixth delay line for 19ms 58, the seventh delay line for 10ms 60, the first trigger for 1 ms 59, the second trigger for 2 ms 61, element AND 62; while the first button Kn.1 (Fig. 18) to run the first trigger one-millisecond 1 ms 59 for a short time, the one-millisecond pulse generator 3.5 of the shaper 3 is connected to the first input of the first shaper groups of one- and two-millisecond pulses 3.1; the first input of the first shaper groups of one and two millisecond pulses 3.1 connected to the input of the first trigger one millisecond 1 ms 59; the output of the first trigger of one millisecond 1 ms 59 is connected in parallel on five lines with the second input of the element And 62: on the first line through the first gate B.41; on the second line - through the first delay line for 2 ms 53 and through the second gate B.42; on the third line - through the seventh delay line for 10 ms 60 and through the third gate B.43; on the fourth line through the seventh delay line for 10 ms 60, the second delay line for 8 ms 54 and through the fourth gate B.44; on the fifth line - through the seventh delay line for 10 ms 60, through the third delay line for 13 ms 55 and through the fifth valve 45; the output of the seventh delay line for 10 ms 60 is connected to the second trigger for 2 ms 61; the output of the second trigger for 2 ms 61 is connected in three lines with the second input of the element And 62: on the first line through the fourth delay line for 22 ms 56 and through the sixth gate B.46; on the second line - through the fifth delay line for 10 ms 57 and through the seventh gate B.47; on the third line - through the sixth delay line for 19 ms 58, through the eighth gate B.48 and through the ninth gate B.49; at the same time, the output of the eighth valve B.48 is connected to the second output of the first shaper of groups of one- and two-millisecond pulses 3.1; the second input of the first shaper groups of one - and two-millisecond pulses 3.1 is connected to the first input of the element And 62; the output of the element And 62 is connected to the first output of the first generator of groups of one- and two-millisecond pulses 3.1. As you can see, the launch of the first shaper of groups of one- and two-millisecond pulses 3.1 is carried out by pressing the VK.1 button in the temporary pulse shaper 3, both for a one-time start of the shaper 3.1, and for its cyclic operation.

On FIG. 20 shows the temporal distribution of pulses and their duration, which are generated by the first generator of groups of one and two millisecond pulses 3.1, where the duration of the pulses created by the first generator of groups of one and two millisecond pulses with the same frequency filling of pulses, i. corresponds to τ=1 ms, and τ=2 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 1 ms; two pulses of the first and third of the second group with a duration of 1 ms, and the second pulse in the group of 2 ms; in the third group, the first and third pulses are 2 ms each, and the second pulse is 1 ms.

On FIG. 21 shows the second generator of groups of two and four millisecond pulses 3.2, where the first gate is B.50, the second gate is B.51, the third gate is B.52, the fourth gate is B.53, the fifth gate is B.54, the sixth gate is B.55, the seventh gate B.56, eighth gate B.57, ninth gate B.58, first delay line for 3 ms. 63, second delay line 10ms 64, third delay line 18ms 65, fourth delay line 30ms 66, fifth delay line 13ms 67, sixth delay line 25ms 68, seventh delay line 10ms 70, the first trigger for 2 ms 69, the second trigger for 4 ms 71, element And 72, while the second button Kn. the input of the second shaper of groups of two- and four-millisecond pulses 3.2; the first input of the second shaper of groups of two and four millisecond pulses 3.2 is connected to the input of the first trigger for 2 ms 69; the output of the first trigger for 2 ms 69 is connected in parallel on five lines with the second input of the element And 72: on the first line through the first gate B.50; on the second line - through the first delay line for 3 ms 63 and through the second gate B.51; on the third line - through the seventh delay line for 10 ms 70 and through the third gate B.52; on the fourth line - through the seventh delay line for 10 ms 70, through the second delay line for 10 ms 64 and through the fourth gate B.53; on the fifth line - through the seventh delay line for 10 ms 70, through the third delay line for 18 ms 65 and through the fifth gate B.54; in addition, the output of the first flip-flop for 2 ms 69 is connected to the input of the second flip-flop for 4 ms 71 through the seventh delay line for 10 ms 70; the output of the second trigger for 4 ms 71 is connected on three lines with the second input of the element And 72: on the first line through the fourth delay line for 30 ms 66 and through the sixth gate B.55; on the second line - through the fifth delay line for 13 ms 67 and through the seventh gate B.56; on the third line - through the sixth delay line for 25 ms 68, through the eighth gate B.57 and through the ninth gate B.58; at the same time, the output of the eighth gate 58 is connected to the second output of the second generator of groups of two- and four-millisecond pulses 3.2; the second input of the second shaper of groups of two and four millisecond pulses 3.2 is connected to the first input of the element I72; the output of the And 72 element is connected to the first output of the second generator of groups of two- and four-millisecond pulses 3.2. As you can see, the launch of the second shaper of groups of two- and four-millisecond pulses 3.2 is carried out by pressing the VK.2 button in the temporary pulse shaper 3, both for a one-time start of the shaper 3.2, and for its cyclic operation.

On FIG. 22 shows the temporal distribution of pulses and their duration, which are formed by the second generator of groups of two and four millisecond pulses 3.2, where the duration of the pulses created by the second generator of groups of two and four millisecond pulses with the same frequency filling of pulses, i.e. corresponds to τ=2 ms, and τ=4 ms, and formed three groups of pulses: the first group of two pulses, the second group of three and the third group of three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 2 ms; two pulses of the first and third of the second group with a duration of 2 ms, and the second pulse in the second group of 4 ms; in the third group, the first and third pulses are 4 ms each, and the second pulse is 2 ms.

On FIG. 23 shows the third generator of groups of three- and six-millisecond pulses 3.3, where the first gate is B.59, the second gate is B.60, the third gate is B.61, the fourth gate is B.62, the fifth gate is B.63, the sixth gate is B.64, the seventh gate B.65, eighth gate B.66, ninth gate B.67, first delay line for 4 ms. 73, second delay line at 23ms 74, third delay at 37ms 75, fourth delay at 15ms 76, fifth delay at 11ms 77, sixth delay at 4ms 78, seventh delay at 12ms 80, the first trigger for 3 ms 79, the second trigger for 6 ms 81, the element And 82, while the third button Kn. the input of the third shaper of groups of three- and six-millisecond pulses 3.3; the first input of the third shaper of groups of three and six millisecond pulses 3.3 is connected to the input of the first trigger for 3 ms 79; the output of the first trigger for 3 ms 79 is connected in parallel on five lines with the second input of the element And 82: on the first line - through the first valve B.59; on the second line - through the first delay line for 4 ms 73 and through the second gate B.60; on the third line - through the seventh delay line for 12 ms 80 and through the third gate B.61; on the fourth line - through the seventh delay line for 12 ms 80, through the second delay line for 23 ms 74, and through the fourth gate B.62; on the fifth line - through the seventh delay line for 12 ms 80, through the third delay line for 37 ms 75, and through the fifth gate B.63; in addition, the output of the seventh delay line for 12 ms 80 is connected to the input of the second trigger for 6 ms 81; the output of the second trigger for 6 ms 81 is connected in three lines with the second input of the element And 82: on the first line through the fourth delay line for 15 ms 76 and through the sixth gate B.64; on the second line - through the fifth delay line for 11 ms 77 and through the seventh gate B.65; on the third line - through the seventh delay line for 4 ms 78, through the eighth gate B.66 and through the ninth gate B.67; at the same time, the output of the eighth gate B.66 is connected to the second output of the third generator of groups of three- and six-millisecond pulses 3.3; the second input of the third shaper groups of three - and six-millisecond pulses 3.3 is connected to the first input of the element And 82; the output of the element And 82 is connected to the first output of the third generator groups of three - and six-millisecond pulses 3.3. As you can see, the launch of the third shaper of groups of three- and six-millisecond pulses 3.3 is carried out by pressing the Vk.3 button in the temporary pulse shaper 3, both for a one-time start of the shaper 3.3, and for its cyclic operation.

On FIG. 24 shows the temporal distribution of pulses and their duration, which are generated by the third generator of groups of three and six millisecond pulses 3.3, where the duration of the pulses generated by the third generator of groups of three and six millisecond pulses with the same frequency filling of pulses, i.e. corresponds to τ=3 ms, and τ=6 ms, and formed three groups of pulses: the first group of two pulses, the second group of three and the third group of three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 3 ms; two pulses of the first and third of the second group with a duration of 3 ms, and the second pulse in the second group of 6 ms; in the third group, the first and third pulses are 6 ms each, and the second pulse is 3 ms.

On FIG. 25 shows the fourth four- and eight-millisecond pulse group generator 3.4, where the first gate is B.68, the second gate is B.69, the third gate is B.70, the fourth gate is B.71, the fifth gate is B.72, the sixth gate is B.73, the seventh gate B.74, eighth gate B.75, ninth gate B.76, first delay line for 5 ms. 83, second delay line 14ms 84, third delay line 32ms 85, fourth delay line 5ms 86, fifth delay line 23ms 87, sixth delay line 37ms 88, seventh delay line 14ms 90, the first trigger for 4 ms 89, the second trigger for 8 ms 91, the element And 92, while the fourth button Kn.4 (Fig. 18) to start the first four-millisecond trigger 4 ms 89 for a short time, the one-millisecond pulse generator 3.5 of the shaper 3 is connected to the first input of the fourth shaper of groups of four- and eight-millisecond pulses 3.4; the first input of the fourth shaper of groups of four and eight millisecond pulses 3.4 is connected to the input of the first trigger for 4 ms 89; the output of the first trigger for 4 ms 89 is connected in parallel on five lines with the second input of the element And 92: on the first line - through the first valve B.68; on the second line - through the first delay line for 5 ms 83 and through the second gate B.69; on the third line - through the seventh delay line for 14 ms 90 and through the third gate B.70; on the fourth line - through the seventh delay line for 14 ms 90, through the second delay line for 14 ms 84 and through the fourth gate B.71; on the fifth line - through the seventh delay line for 14 ms 90, through the third delay line for 32 ms 85 and through the fifth gate B.72; in addition, the output of the seventh delay line for 14 ms 90 is connected to the input of the second trigger for 8 ms 91; the output of the second trigger for 8 ms 91 is connected on three lines with the second input of the element And 92: on the first line - through the fourth delay line for 5 ms 86 and through the sixth gate B.73; on the second line - through the fifth delay line for 23 ms 87 and through the seventh gate B.74; on the third line - through the sixth delay line for 37 ms 88, through the eighth gate B.75 and through the ninth gate B.76; at the same time, the output of the eighth valve B.75 is connected in parallel with the second output of the fourth generator of groups of four and eight millisecond pulses 3.4; the second input of the fourth generator groups of four - and eight-millisecond pulses 3.4 is connected to the first input of the element And 92; the output of the element And 92 is connected to the first output of the fourth generator of groups of four and eight millisecond pulses 3.4. As you can see, the launch of the fourth generator of groups of four- and eight-millisecond pulses 3.4 is carried out by pressing the VK.4 button in the temporary pulse generator 3, both for a one-time start of the generator 3.4, and for its cyclic operation.

On FIG. 26 shows the temporal distribution of pulses and their duration, which are generated by the fourth generator of groups of four and eight millisecond pulses 3.4, where the duration of the pulses generated by the fourth generator of groups of four and eight millisecond pulses with the same frequency filling of pulses, i.e. corresponds to τ=4 ms, and τ=8 ms, and formed three groups of pulses: the first group of two pulses, the second group of three and the third group of three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 (Fig. 1) in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 4 ms; two pulses of the first and third of the second group with a duration of 4 ms, and the second pulse in the second group of 8 ms; in the third group, the first and third pulses are 8 ms each, and the second pulse is 4 ms.

Thus, the pulses created by the frequency pulse shaper 2 through the terminals "c" and "g" of the first switch Vk.1 (Fig. 1), if it is turned on, come through the first input of the operating mode selection block 4, through the input of the power amplifier 5.1 to the input matching device of the transmitting system 5.2. The matching device of the transmitting system 5.2 ensures the matching of one input with N outputs.

And the pulses created by the temporary pulse shaper 3 through the terminals "a" and "b" of the second switch Vk.2 (Fig. 1), if it is turned on, come through the second input of the operating mode selection block 4, through the input of the power amplifier 5.1 to the input of the matching device transmission system 5.2. The matching device of the transmitting system 5.2 ensures the matching of one input with N outputs.

Excited frequencies in the medium due to the property of NQR from the output of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 12 (Fig. 1), through the terminals "d" and "e" of the third switch Vk.3, if it is turned on, come through the third input of the mode selection block work 4, through the input of the power amplifier 5.1 to the input of the matching device of the transmission system 5.2. Moreover, the third switch Vk.3 can be permanently switched on, and Vk.1 and Vk.2 alternately. The matching device of the transmitting system 5.2 ensures the matching of one input with N outputs.

10 - block of filters, 11 - block for analyzing the spectrum of nuclear quadrupole resonance of radiation, 12 - block for studying the spectrum of radiation of signals of nuclear quadrupole resonance, 13 - analytical block for weak NQR signals, block for controlling ambient temperature 14,

Also, weak excited NQR frequencies through the filter unit 10 are fed through the first input through the analytical unit of weak NQR signals 13 to the third input of the operating mode selection unit 4 through the terminal "d" of the third switch Vk.3 (Fig. 1).

On FIG. 27 shows the operating mode selection block 4, where the transformer Tr.1 with three primary windings and one secondary winding, while the first input of the operating mode selection block 4 is connected to the terminal "b ₁ " of the first primary winding of the transformer Tr.1, and the terminal "a ₁ » the first primary winding of the transformer Tr.1 is grounded; the second input of the operating mode selection block 4 is connected to the terminal "b ₂ " of the second primary winding of the transformer Tr.1, and the terminal "a ₂ " the second primary winding of the transformer Tr.1 is grounded; the third input of the operating mode selection block 4 is connected to the terminal "b ₃ " of the third primary winding of the transformer Tr.1, and the terminal "a ₃ " the third primary winding of the transformer Tr.1 is grounded; the secondary winding of the transformer Tr.1 is connected by terminal "e" to the output of the operating mode selection block 4, and the secondary winding of the transformer Tr.1 is grounded by terminal "c".

This allows you to distribute evenly the output power of the power amplifier 5.1 to the input of each of the N emitters 7 from the first emitter 7 ₁ to the N-th - 7 _N . The matching principle is shown in Fig. 28. The matching device of the transmission system 5.2 is structurally represented by the following elements: Tr.1 transformer with one primary winding 1 and N secondary windings, while the input of the matching device of the transmission system 5.2 is connected to the terminal "C" of the primary winding 1 of the transformer Tr.1, terminal " D "of this primary winding of the transformer Tr.1 is grounded; the first output 1 of the matching device of the transmission system 5.2 on the one hand (Fig. 1) is connected to the terminal "F" of the first emitter 7 ₁ , and on the other hand, is connected to the terminal "a ₁ " of the first secondary winding 1 of the transformer Tr.1, and the terminal "in ₁ " of this first secondary winding is grounded (Fig. 28); the second output 2 of the matching device of the transmission system 5.2 is connected on the one hand to the terminal "F" of the second emitter 7 ₂ , and on the other hand, is connected to the terminal "a ₂ " of the second secondary winding 2 of the transformer Tr.1, and the terminal "in ₂ " of this the second secondary winding is grounded; the third output 3 of the matching device of the transmitting system 5.2 is connected on the one hand to the terminal "F" of the third emitter 7 ₃ , and on the other hand, is connected to the terminal "a ₂ " of the third secondary winding 3 of the transformer Tr.1, and the terminal " in ₃ " of this the third secondary winding is grounded; N-1 output of the matching device of the transmission system 5.2 on the one hand is connected to the terminal "G" N-1 of the emitter 7 _N-1 , and on the other hand, it is connected to the terminal "a _N-1 " N-1 of the secondary winding of the transformer Tr.1, and the terminal "in _N-1 " of this N-1 secondary winding is grounded; N the output of the matching device of the transmission system 5.2 on the one hand is connected to the N emitter 7 _N , and on the other hand, it is connected to the terminal "a _N " N of the secondary winding of the transformer Tr.1, and the terminal "in _N " of this N secondary winding is grounded. Given the identity of the parameters of the secondary windings, it is possible to achieve a uniform distribution of the energy of the power amplifier at the input of each of the emitters.

The information generator of the receiving system 9 (Fig. 29) provides in-phase addition of the received information from N receiving antennas in each antenna line. For example, addition for the first line using the matching device of the first in-phase receiving antenna line 9.1, addition for the second line using the matching device of the first in-phase receiving antenna line 9.2, and so on. The information generator of the receiving system 9 in Fig. 29, where 9.1 is the matching device of the first in-phase receiving antenna line containing information from the first line from 6_eleven by N antenna 6_1N; 9.2 - matching device of the second in-phase receiving antenna line containing information from the second antenna line from 6₂₁ by N antenna 6_2N; 9.3 - matching device of the third in-phase receiving antenna line containing information from the third antenna line from 6₃₁ by N antenna 6_3N; 9.N-1 - matching device N-1 in-phase receiving antenna array containing information from N-1 antenna array from 6_N-1.1, by N antenna 6_N-1.N; 9.N - matching device of the N in-phase receiving antenna array containing information from the N antenna array from 6_N1 by N antenna 6_{N N}; 9.0 - amplifier in each of the N receiver lines; 9.00 - matching device of the receiving antenna system; at the same time, the first input of the information generator of the receiving system 9 is connected through the first input of the matching device of the first in-phase receiving antenna line 9.1, through the amplifier 9.0 with the first input of the matching device of the receiving antenna system 9.00; the second input of the information generator of the receiving system 9 is connected through the first input of the matching device of the second in-phase receiving antenna line 9.2, through the amplifier 9.0 with the second input of the matching device of the receiving antenna system 9.00; the third input of the information generator of the receiving system 9 is connected through the first input of the matching device of the third in-phase receiving antenna line 9.3, through the amplifier 9.0 with the third input of the matching device of the receiving antenna system 9.00; n-1 input of the information generator of the receiving system 9 is connected through the first input of the matching device N-1 of the in-phase receiving antenna line 9.N-1, through the amplifier 9.0 with the n-1 input of the matching device of the receiving antenna system 9.00; n the input of the information generator of the receiving system 9 is connected through the first input of the matching device N of the in-phase receiving antenna line 9.N, through the amplifier 9.0 with the n input of the matching device of the receiving antenna system 9.00; n₁ the input of the information generator of the receiving system 9 is connected in parallel with the second input of the matching device of the first in-phase receiving antenna line 9.1, with the second input of the matching device of the second in-phase receiving antenna line 9.2, with the second input of the matching device of the third in-phase receiving antenna line 9.3, with the second input of the matching device N -1 in-phase receiving antenna of the line 9.N-1, with the second input of the matching device N of the in-phase receiving antenna of the line 9.N; the output of the matching device of the receiving antenna system 9.00 is connected to the output of the information generator of the receiving system 9.

On FIG. 30 shows a matching device for antennas of the first in-phase receiving antenna line 9.1 (identical for the second 9.2; third 9.3; ...; 9.N-1; 9.N), where the switching unit is 9.a, the transformer Tr.1 with one secondary winding and N primary windings, while the one-to-one input 1.1 of the matching device 9.1, as the output of the first antenna 6 ₁₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a with the terminal "a," of the first primary windings of the transformer Tr.1, and the terminal "in," of the first primary winding is grounded; input one or two 1.2 of the matching device 9.1, as the output of the second antenna 6 ₁₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a to the terminal "a ₂ " of the second primary winding of the transformer Tr.1, and the terminal "in ₂ " of the second primary winding is grounded; input one-three 1.3 of the matching device 9.1, as the output of the third antenna 6 ₃₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a to the terminal "a ₃ " of the third primary winding of the transformer Tr.1, terminal "in ₃ " of the third primary winding is grounded; input 1.n-1 of the matching device 9.1, as the output N-1 of the antenna 6 _n-1.1 from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a to the terminal "a _N-1 " N -1 of the primary winding of the transformer Tr.1, and the terminal "in _N1 " N-1 of the primary winding is grounded; the one-n ln input of the matching device 9.1, as the output N of the receiving antenna 6 _1N from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit 9.a to the terminal "a _N " N of the primary winding of the transformer Tr.1 , and the terminal "in _N " N of the primary winding is grounded; the second input 2 of the matching device 9.1 is connected in parallel with the second inputs of all N switching units 9.a; the terminal "K" of the secondary winding of the transformer Tr.1 is connected to the output of the matching device 9.1, and the terminal "M" of the secondary winding of the transformer Tr.1 is grounded.

On FIG. 31 shows the switching unit 9.a, where 9.a.1 is the AND element, 9.a.2 is the NOT element, while the first input of the switching unit 9.a is connected to the first input of the AND element, and the second input of the switching unit 9. and through the element NOT 9.a.2 connected to the second input of the element And 9.a.1; the output of the element And 9.a.1 is connected to the output of the switching unit 9.a.

On FIG. 32 shows the matching device of the receiving antenna system 9.00, where the transformer Tr.1 with "n" primary windings and one secondary winding, while the first input 1 of the matching device of the receiving antenna system 9.00, as the output of the first in-phase receiving antenna line 6 ₁₁ -6 _1N , connected to the terminal "a ₁ " of the first primary winding of the transformer Tr.1, and the terminal "in ₁ " of the first primary winding of the transformer Tr.1 is grounded; the second input 2 of the matching device of the receiving antenna system 9.00, as the output of the second in-phase receiving antenna line 6 ₂₁ -6 _2N , is connected to the terminal "a ₂ " of the second primary winding of the transformer Tr.1, and the terminal "in ₂ " of the second primary winding of the transformer Tr. 1 grounded; the third input of the matching device of the receiving antenna system 9.00, as the output of the third in-phase receiving antenna line 6 ₃₁ -6 _3N , is connected to the terminal "a ₃ " of the third primary winding of the transformer Tr.1, and the terminal "in ₃ " of the third primary winding of the transformer Tr.1 grounded; "n-1" input of the matching device of the receiving antenna system 9.00, as the output N-1 of the in-phase receiving antenna line 6 _(N-1)1 -6 _(N-1)N , is connected to the terminal "a _N-1 " N-1 the primary winding of the transformer Tr.1, and the terminal "in _N-1 " N-1 of the primary winding of the transformer Tr.1 is grounded; "n" the input of the matching device of the receiving antenna system 9.00, as the output N of the common-mode receiving antenna line 6 _N1 -6 _NN , is connected to the terminal "a _N " N of the primary winding of the transformer Tr.1, and the terminal "in _N " N of the primary winding of the transformer Tr .1 grounded; the terminal "C" of the secondary winding of the transformer Tr.1 is connected to the output of the matching device of the receiving antenna system 9.00, and the terminal "D" of the secondary winding of the transformer Tr.1 is grounded.

The received information at the output of the matching device of the receiving antenna system 9.00 is subject to analysis based on the frequency spectrum. For a wide reception band of the receiving device does not have a uniform gain, therefore it is advisable to decompose the received spectrum using band-pass filters and amplify each frequency band separately. This is provided by the filter unit 10 in the receiving system. Moreover, band-pass filters, made on the basis of real capacitances, have low weight and size characteristics (large weight and dimensions). To reduce weight and size characteristics in the filter unit 10 implemented gyrators - microprocessors with capacitive input resistance - L _c . (see Girator, p. 180. W. Titze, K. Schenk. Semiconductor circuitry. - M: ed. Mir, 1983)

In FIG. 33 shows a filter block 10 for ten channels, where 10.1 is the first band-pass filter for frequencies of 1-10 kHz, 10.2 is the second band-pass filter for frequencies of 10-50 kHz, 10.3 is the third band-pass filter for frequencies of 50-100 kHz, 10.4 is the fourth band-pass filter filter for frequencies 100-200 kHz, 10.5 - the fifth band-pass filter for frequencies 200-400 kHz, 10.6 - the sixth band-pass filter for frequencies 400-800 kHz, 10.7 - the seventh band-pass filter for frequencies 800-1000 kHz, 10.8 - the eighth band-pass filter for frequencies 1-10 MHz, 10.9 - the ninth band-pass filter for frequencies 10-20 MHz, 10-10 - the tenth band-pass filter for frequencies 20-40 MHz, 10.11 - the first narrow-band amplifier for the frequency band 1-10 kHz., 10.12 - the second narrow-band amplifier for the frequency band 10-50 kHz, 10.13 - the third narrow-band amplifier for the frequency band 50-100 kHz, 10.14 - the fourth narrow-band amplifier for the frequency band 100-200 kHz, 10.15 - the fifth narrow-band amplifier for the frequency band 200-400 kHz, 10.16 - the sixth narrow-band amplifier for the frequency band 400-800 kHz, 10.17 - the seventh narrow-band amplifier for the frequency band 800-1000 kHz, 10.18 - the eighth narrow-band amplifier for the frequency band 1-10 MHz, 10.19 - the ninth narrow-band amplifier for the frequency band 10-20 MHz, 10.20 - the tenth narrow-band amplifier for the frequency band 20 -40 MHz; each of the ten band-pass filters, from the first 10.1 to the tenth 10.10, contains two resistors R ₁ and R ₂ and two capacitive gyrators G _C1 and G _C2 , while the input of the filter unit for ten channels 10 is connected in parallel with ten inputs of ten band-pass filters from the first 10.1 through the tenth 10.10, the outputs of ten band pass filters through ten narrow band amplifiers form ten outputs of the filter unit for ten channels 10; the input of the filter unit for ten channels 10 through the output of the first bandpass filter 10.1 with a bandwidth of 1 kHz to 10 kHz is connected to the first output of the filter unit through the first narrow-band amplifier 10.11; the input of the filter unit for ten channels 10 through the output of the second bandpass filter 10.2 with a bandwidth from 10 kHz to 50 kHz is connected to the second output of the filter unit 10 through the second narrow-band amplifier 10.12; the input of the filter unit for ten channels 10 through the output of the third bandpass filter 10.3 with a bandwidth of 50 kHz to 100 kHz is connected to the third output of the filter unit 10 through the third narrow-band amplifier 10.13; the input of the filter unit for ten channels 10 through the output of the fourth bandpass filter 10.4 with a bandwidth from 100 kHz to 200 kHz is connected to the fourth output of the filter unit 10 through the fourth narrow-band amplifier 10.14; the input of the filter unit for ten channels 10 through the output of the fifth bandpass filter 10.5 with a bandwidth of 200 kHz to 400 kHz is connected to the fifth output of the filter unit 10 through the fifth narrow-band amplifier 10.15; the input of the filter unit for ten channels 10 through the output of the sixth bandpass filter 10.6 with a bandwidth from 400 kHz to 800 kHz is connected to the sixth output of the filter unit 10 through the sixth narrow-band amplifier 10.16; the input of the filter unit for ten channels 10 through the output of the seventh bandpass filter 10.7 with a bandwidth from 800 kHz to 1000 kHz is connected to the seventh output of the filter unit 10 through the seventh narrow-band amplifier 10.17; the input of the filter unit for ten channels 10 through the output of the eighth bandpass filter 10.8 with a bandwidth of 1.0 to 10 MHz is connected to the eighth output of the filter unit 10 through the eighth narrow-band amplifier 10.18; the input of the filter unit for ten channels 10 through the output of the ninth bandpass filter 10.9 with a bandwidth of 10 to 20 MHz is connected to the ninth output of the filter unit 10 through the ninth narrow-band amplifier 10.19; the input of the filter unit for ten channels 10 through the output of the tenth bandpass filter 10.10 with a bandwidth of 20 to 40 MHz is connected to the tenth output of the filter unit 10 through the tenth narrow-band amplifier 10.20; the input in each of the ten band-pass filters, from the first 10.1 to the tenth 10.10, is connected through the terminal "c" to the terminal "d", the terminal "d" is connected through the first capacitive gyrator G _C1 and through the first resistor R ₁ with the output of the band-pass filter, and through the second resistor R ₂ , the “d” terminal is grounded, while the “c” terminal is grounded through the second capacitive gyrator G _C2 (Fig. 33, (a)), (see Bandpass filter, p. 19. W. Titze, K. Schenk Semiconductor circuitry - M: ed. "Mir" 1983)

After amplification of each frequency band, it is advisable to analyze all ten bands in order to determine the possible appearance of the effect of nuclear quadrupole resonance arising in the objects of study under the influence of the exciting magnetic field of the emitters. This goal is solved by the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11. If a response appears in the form of an NQR frequency, it is necessary to detect the frequency, and the response must also be analyzed in order to determine the frequency shifts of the nuclear quadrupole resonance. To do this, the oscillatory systems, from the first 11.1 to the tenth 11.10, respond and the LED lights up, the photodiode fixes and connects the resonant frequency of the excited circuit to the output of the nuclear quadrupole resonance spectrum analysis unit 11 to the input of the operation mode selection unit 4 in order to enhance the excited NQR mode.

Therefore, in FIG. 34 shows a block for analyzing the spectrum of nuclear quadrupole resonance of radiation 11, a block for analyzing the spectrum of nuclear quadrupole resonance of radiation 11 is presented, containing ten oscillatory systems from the first 11.1 to the tenth 11.10 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, as well as ten groups of five resonance clamps in each group or fifty resonance clamps 1 (photodiodes 1), in addition, ten indicators of justifying the resonance frequency from the first indicator I.1-6 to the tenth I.10-6; wherein the first input of the nuclear quadrupole resonance spectrum analysis unit AND is connected to the input of the first oscillatory system 11.1 at frequencies of 1-10 kHz, the first output of the first oscillatory system 11.1 is connected to the first inputs of the first group of five indicators from I.1-1 to I.1 -5, and the second output of the first oscillatory system 11.1 is connected to the second inputs of the first group of five indicators from I.1-1 to I.1-5, the third output of the first oscillatory system is connected to the first output of the nuclear quadrupole resonance spectrum analysis unit 11, the fourth the output of the first oscillatory system 11.1 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the first frequency justification indicator I.1-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the first group I.1-1 is connected to the third input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the first group I.1-2 is connected to the sixth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the first group I.1-3 is connected to the ninth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the first group I.1-4 is connected to the twelfth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the first group I.1-5 is connected to the fifteenth input of the first indicator of the resonance frequency justification I.1-6; the output of the first frequency justification indicator I.1-6 is connected to the first conditional output 1.1 of the nuclear quadrupole resonance spectrum analysis block 11; the second input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the second oscillatory system 11.2 at frequencies of 10-50 kHz, the first output of the second oscillatory system 11.2 is connected to the first inputs of the second group of five indicators from I.2-1 to I.2-5, and the second output of the second oscillatory system 11.2 is connected to the second inputs of the second group of five indicators from I.2-1 to I.2-5, the third output of the second oscillatory system 11.2 is connected to the second output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the second oscillatory system 11.2 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the second frequency justification indicator I.2-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the second group I.2-1 is connected to the third input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the second group I.2-2 is connected to the sixth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the second group I.2-3 is connected to the ninth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance clamp 1 (photodiode 1) of the fourth indicator determined by the LED in the second group I.2-4 is connected to the twelfth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the second group I.2-5 is connected to the fifteenth input of the second indicator of the resonance frequency justification I.2-6; the output of the second frequency justification indicator I.2-6 is connected to the second conditional output 2.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the third input of the nuclear quadrupole resonance analysis unit AND is connected to the input of the third oscillatory system 11.3 at frequencies of 50-100 kHz, the first output of the third oscillatory system 11.3 is connected to the first inputs of the third group of five indicators from I.3-1 to I.3-5, and the second output of the third oscillatory system 11.3 is connected to the second inputs of the third group of five indicators from I.3-1 to I.3-5, the third output of the third oscillatory system 11.3 is connected to the third output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the third oscillatory system 11.3 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the third frequency justification indicator I.3-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the third group I.3-1 is connected to the third input of the third indicator of the justification of the resonance frequency I.3-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the third group I.3-2 is connected to the sixth input of the third indicator of the justification of the resonance frequency I.3-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the third group I.3-3 is connected to the ninth input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the third group I.3-4 is connected to the twelfth input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the third group I.3-5 is connected to the fifteenth input of the third indicator of the resonance frequency justification I.3-6; the output of the third indicator justifying the frequency I.3-6 is connected to the third conditional output 3.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the fourth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the fourth oscillatory system 11.4 at frequencies of 100-200 kHz, the first output of the fourth oscillatory system 11.4 is connected to the first inputs of the fourth group of five indicators from I.4-1 to I.4-5, and the second output of the fourth oscillatory system 11.4 is connected to the second inputs of the fourth group of five indicators from I.4-1 to I.4-5, the third output of the fourth oscillatory system 11.4 is connected to the fourth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the fourth oscillatory system 11.4 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the fourth frequency justification indicator I.4-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the fourth group I.4-1 is connected to the third input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the fourth group I.4-2 is connected to the sixth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the fourth group I.4-3 is connected to the ninth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the fourth group I.4-4 is connected to the twelfth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the fourth group I.4-5 is connected to the fifteenth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the fourth frequency justification indicator I.4-6 is connected to the fourth conditional output 4.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the fifth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the fifth oscillatory system 11.5 at frequencies of 200-400 kHz, the first output of the fifth oscillatory system 11.5 is connected to the first inputs of the fifth group of five indicators from I.5-1 to I.5-5, and the second output of the fifth oscillatory system 11.5 is connected to the second inputs of the fifth group of five indicators from I.5-1 to I.5-5, the third output of the fifth oscillatory system 11.5 is connected to the fifth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the fifth oscillatory system 11.5 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the fifth frequency justification indicator I.5-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the fifth group I.5-1 is connected to the third input of the fifth indicator of the resonance frequency justification I.5-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the fifth group I.5-2 is connected to the sixth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the fifth group I.5-3 is connected to the ninth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the fifth group I.5-4 is connected to the twelfth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the fifth group I.5-5 is connected to the fifteenth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the fifth indicator justifying the frequency I.5-6 is connected to the fifth conditional output 5.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the sixth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the sixth oscillatory system 11.6 at frequencies of 400-800 kHz, the first output of the sixth oscillatory system 11.6 is connected to the first inputs of the sixth group of five indicators from I.6-1 to I.6-5, and the second output of the sixth oscillatory system is connected to the second inputs of the sixth group of five indicators from I.6-1 to I.6-5, the third output of the sixth oscillatory system 11.6 is connected to the sixth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the sixth oscillatory system 11.6 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the sixth frequency justification indicator I.6-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the sixth group I.6-1 is connected to the third input of the sixth indicator of the resonance frequency justification I.6-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the sixth group I.6-2 is connected to the sixth input of the sixth indicator of the justification of the resonance frequency I.6-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the sixth group I.6-3 is connected to the ninth input of the sixth indicator of the justification of the resonance frequency I.6-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the sixth group I.6-4 is connected to the twelfth input of the sixth indicator of the resonance frequency justification I.6-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the sixth group I.6-5 is connected to the fifteenth input of the sixth indicator of the justification of the resonance frequency I.6-6; the output of the sixth frequency justification indicator I.6-6 is connected to the sixth conditional output 6.1 of the nuclear quadrupole resonance spectrum analysis block 11; the seventh input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the seventh oscillatory system 11.7 at frequencies of 800-1000 kHz, the first output of the seventh oscillatory system 11.7 is connected to the first inputs of the seventh group of five indicators from I.7-1 to I.7-5, and the second output of the seventh oscillatory system 11.7 is connected to the second inputs of the seventh group of five indicators from I.7-1 to I.7-5, the third output of the seventh oscillatory system 11.7 is connected to the seventh output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the seventh oscillatory system 11.7 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the seventh frequency justification indicator I.7-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the seventh group I.7-1 is connected to the third input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the seventh group I.7-2 is connected to the sixth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the seventh group I.7-3 is connected to the ninth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the seventh group I.7-4 is connected to the twelfth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the seventh group I.7-5 is connected to the fifteenth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the seventh frequency justification indicator I.7-6 is connected to the seventh conditional output 7.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the eighth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the eighth oscillatory system 11.8 at frequencies of 1-10 MHz, the first output of the eighth oscillatory system 11.8 is connected to the first inputs of the eighth group of five indicators from I.8-1 to I.8-5, and the second output of the eighth oscillatory system 11.8 is connected to the second inputs of the eighth group of five indicators from I.8-1 to I.8-5, the third output of the eighth oscillatory system 11.8 is connected to the eighth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the eighth oscillatory system 11.8 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the eighth frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the eighth group I.8-1 is connected to the third input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance clamp 1 (photodiode 1) of the second indicator determined by the LED in the eighth group I.8-2 is connected to the sixth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the eighth group I.8-3 is connected to the ninth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the eighth group I.8-4 is connected to the twelfth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the eighth group I.8-5 is connected to the fifteenth input of the eighth resonance frequency justification indicator I.8-6; the output of the eighth frequency justification indicator I.8-6 is connected to the eighth conditional output 8.1 of the nuclear quadrupole resonance spectrum analysis block 11; the ninth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the ninth oscillatory system at frequencies of 10-20 MHz, the first output of the ninth oscillatory system 11.9 is connected to the first inputs of the ninth group of five indicators from I.9-1 to I.9-5, and the second output of the ninth oscillatory system 11.9 is connected to the second inputs of the ninth group of five indicators from I.9-1 to I.9-5, the third output of the ninth oscillatory system 11.9 is connected to the ninth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the ninth oscillatory system 11.9 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the ninth frequency justification indicator I.9-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the ninth group I.9-1 is connected to the third input of the ninth indicator of the resonance frequency justification I.9-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the ninth group I.9-2 is connected to the sixth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the ninth group I.9-3 is connected to the ninth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the ninth group I.9-4 is connected to the twelfth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the resonance clamp 1 (photodiode 1) of the fifth indicator determined by the LED in the ninth group I.9-5 is connected to the fifteenth input of the ninth indicator of the justification of the resonance frequency I.9-6; the output of the ninth indicator of frequency justification I.9-6 is connected to the ninth conditional output 9.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the tenth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the tenth oscillatory system 11.10 at frequencies of 20-40 MHz, the first output of the tenth oscillatory system 11.10 is connected to the first inputs of the tenth group of five indicators from I.10-1 to I.10-5, and the second output of the tenth oscillatory system 11.10 is connected to the second inputs of the tenth group of five indicators from I.10-1 to I.10-5, the third output of the tenth oscillatory system 11.10 is connected to the tenth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the tenth oscillatory system 11.10 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the tenth frequency justification indicator I.10-6; the output of the resonance latch 1 (photodiode 1) of the first indicator determined by the LED in the tenth group I.10-1 is connected to the third input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the second indicator determined by the LED in the tenth group I.10-2 is connected to the sixth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the third indicator determined by the LED in the tenth group I.10-3 is connected to the ninth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the fourth indicator determined by the LED in the tenth group I.10-4 is connected to the twelfth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the resonance latch 1 (photodiode 1) of the fifth indicator determined by the LED in the tenth group I.10-5 is connected to the fifteenth input of the tenth indicator of the justification of the resonance frequency I.10-6; the output of the tenth frequency justification indicator I.10-6 is connected to the tenth conditional output 10.1 of the nuclear quadrupole resonance spectrum analysis unit 11.

The improvement of weight and size characteristics is associated with the replacement of the real parameters of capacitance C and inductance L to create an oscillatory system 11.1 (any of ten with 11.1; 11.2; 11.3; ...; 11.10) gyrators: inductance gyrator Gr _L and capacitance gyrator Gr _C. It is significant that the gyrator is a microprocessor, which, if loaded on a capacitance of 1 μF at the input, has an inductive resistance equal to 100 H. If the gyrator is loaded with a small inductive resistance at the input, it has a large capacitance value. (W. Titze, K. Schenk. Semiconductor circuitry. - M: Mir publishing house. 1983, pp. 180-181). The use of gyrators will improve the weight and size characteristics of the proposed device. This is due to the fact that it is necessary to build oscillatory circuits for frequencies from 1 kHz to 10 MHz. With the real capacitance parameters and inductances for oscillatory systems, weight and dimensions can only be placed in rooms with dimensions that are not acceptable for placement.

On FIG. 35 shows the oscillatory system 11.1 (any of ten with 11.1; 11.2; 11.3; ...; 11.10), contains five oscillatory bridges: 1, 2, 3, 4 and 5; each bridge contains high-resistance R, four parallel oscillatory circuits made on the basis of microcircuits - capacitive gyrators Gs and inductive gyrators GL: two oscillatory circuits with parameters gyrator GL1 as inductance L ₁ and gyrator Gs1 as capacitance C ₁ , as well as two oscillatory circuits with parameters GL2 as inductance L ₂ and Gc2 as capacitance C ₂ ; to control the resonance of oscillatory systems, two voltage dividers are connected in parallel, made of two series-connected high-resistance resistors connected in parallel to two parallel oscillatory circuits; while the input of the oscillatory system 11.1 is connected in parallel with the five inputs of the five bridges and with the third output of the oscillatory system 11.1, the first outputs of the five bridges (1, 2, 3, 4 and 5) form the first output, the second outputs of the five bridges (1, 2, 3 , 4 and 5) form the second outlet; the input of each bridge is connected through the terminal "c" to the terminal "g" and through the second parallel oscillatory circuit with the parameters GL2 and Gc2 to the terminal "m" and then through the terminal "a" with the first output of the bridge, and in parallel the terminal "c" is connected to terminal "n" and through the first parallel oscillatory circuit with parameters GL1 and Gc1 with terminal "k" and then through terminal "b" with the second output of the bridge; terminal "a" is connected in parallel through high-resistance R with terminal "b" and in parallel terminal "a" is connected through terminal "l", through the first oscillatory circuit with parameters GL1 and Gc1 through terminal "n" with terminal "d", terminal " d” is grounded; in addition, the terminal "b" is connected through the terminal "h", through the second parallel oscillatory circuit with the parameters GL2 and Gc2 through the terminal "x" with the grounded terminal "d"; terminal "n" of the first oscillatory circuit with parameters GL1 and Gc1 is connected through terminal "t" through high-resistance R1, through terminal "h", through high-resistance R2, through terminal "w" with terminal "k" of the first oscillating circuit with parameters GL1 and Гс1, while the “z” terminal is connected to the third output in each of the five oscillatory bridges (1, 2, 3, 4 and 5); the “h” terminal of the second oscillatory circuit with the parameters GL2 and Gc2 is connected through the “i” terminal through the high-resistance R3, through the “p” terminal, through the high-resistance R4, through the “o” terminal with the “x” terminal of the second oscillatory circuit with the GL2 parameters and Гс2, while the "r" terminal is connected to the fourth output in each of the five oscillatory bridges (1, 2, 3, 4 and 5); moreover, the third and fourth outputs in each of the five oscillatory bridges from the first to the fifth form a parallel fourth output 4 in any of the ten oscillatory systems with 11.1; 11.2; 11.3; …; according to 11.10, wherein the third output of the first oscillatory bridge is connected to the fourth output of the oscillatory system through its first input, and the fourth output of the first oscillatory bridge is connected to the fourth output of the oscillatory system through its second input; further, the third output of the second oscillatory bridge is connected to the fourth output of the oscillatory system through its fourth input, and the fourth output of the second oscillatory bridge is connected to the fourth output of the oscillatory system through its fifth input; further, the third output of the third oscillatory bridge is connected to the fourth output of the oscillatory system through its seventh input, and the fourth output of the third oscillatory bridge is connected to the fourth output of the oscillatory system through its eighth input; further, the third output of the fourth oscillatory bridge is connected to the fourth output of the oscillatory system through its tenth input, and the fourth output of the fourth oscillatory bridge is connected to the fourth output of the oscillatory system through its eleventh input; further, the third output of the fifth oscillatory bridge is connected to the fourth output of the oscillatory system through its thirteenth input, and the fourth output of the fifth oscillatory bridge is connected to the fourth output of the oscillatory system through its fourteenth input; the first oscillatory system 11.1 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 1.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 2.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 3.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 4.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 5.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 6.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 7.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 8.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 9.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 9.9 kHz; the second oscillatory system 11.2 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 11.9 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 15.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 20.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 25.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 30.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 35.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 40.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 44.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 47.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 49.9 kHz; the third oscillatory system 11.3 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 52.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 58.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 62.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 68.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 72.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 78.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 82.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 88.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 92.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 98.9 kHz; the fourth oscillatory system 11.4 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 110.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 120.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 130.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 140.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 150.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 160.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 170.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 178.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 185.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 198.1 kHz; the fifth oscillatory system 11.5 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 210.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 230.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 250.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 270.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 290.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 310.1 kHz; the fourth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 330.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 350.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 370.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 390.1 kHz; the sixth oscillatory system 11.6 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 410.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 450.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 490.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 530.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 570.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 610.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 650.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 690.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 730.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 790.1 kHz; the seventh oscillatory system 11.7 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 810.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 830.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 850.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 880.1 kHz; the third bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 890.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 910.1 kHz; the fourth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 930.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 950.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 970.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 990.1 kHz; the eighth oscillatory system 11.8 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 1100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 1900.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 2900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 3900.1 kHz; the third bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 4900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 5900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 6900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 7900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 8900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 9900.1 kHz; the ninth oscillatory system 11.9 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 10100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 10900.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 12900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 13900.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 14900.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 15900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 16900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 17900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 18900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 19900.1 kHz; the tenth oscillatory system 11.10 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 21100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 23100.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 25100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 27900.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 30100.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 32900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 35100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 37900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 38900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 39900.1 kHz;

On FIG. 36 resonance frequency justification indicator I.1-6 (any of ten from I.1-6 to I.10-6) containing five switches, transformer Tr.1 with one secondary winding and five primary windings, each of the five primary windings transformer Tr.1 consists of two identical sections separated by the middle terminal, while the first input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a1" of the first 1 primary winding of the transformer Tr.1, the second input of the resonance frequency justification indicator AND .1-6 is connected to the terminal "a2" of the first 1 primary winding of the transformer TR.1, the third input of the resonance frequency justification indicator I.1-6 is connected to the first switch of the relay Vk.1, the first primary winding is connected to the grounded terminal "a3" by the middle terminal terminal "a4" when switching the first switch Vk.1 terminal "a5"; the fourth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a6" of the second 2 primary winding of the transformer TR.1, the fifth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a7" of the second 2 primary winding of the transformer TR. 1, the sixth input of the resonance frequency justification indicator I.1-6 is connected to the second switch of the relay Vk.2, the second primary winding is connected by the middle terminal "a8" to the grounded terminal "a9" when switched by the second switch Vk.2 terminal "a10"; the seventh input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a11" of the third 3 primary winding of the transformer TR.1, the eighth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a12" of the third 3 primary winding of the transformer TR. 1, the ninth input of the resonance frequency justification indicator I.1-6 is connected to the third switch of the relay Vk.3, the third primary winding is connected by the middle terminal "a13" to the grounded terminal "a14" when switched by the third switch Vk.3 terminal "a15"; the tenth input of the resonance frequency justification indicator I.1-6 is connected to terminal "a16" of the fourth 4 primary winding of the transformer TR.1, the eleventh input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a17" of the fourth 4 primary winding of the transformer TR. 1, the twelfth input of the resonance frequency justification indicator I.1-6 is connected to the fourth switch of the relay Vk.4, the fourth primary winding is connected by the middle terminal "a18" to the grounded terminal "a19" when switched by the fourth switch Vk.4 by the terminal "a20"; the thirteenth input of the resonance frequency justification indicator I.1-6 is connected to terminal "a21" of the fifth 5 primary winding of the transformer TR.1, the fourteenth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a22" of the fifth 5 primary winding of the transformer TR. 1, the fifteenth input of the resonance frequency justification indicator I.1-6 is connected to the fifth switch of the relay Vk.5, the fifth primary winding is connected by the middle terminal "a23" to the grounded terminal "a24" when switching the fifth switch Vk.5 to the terminal "a25"; the secondary winding of the transformer Tr.1 is grounded by the “d” terminal, and the “c” terminal is connected to the output 1.1 of the resonance frequency justification indicator I.1-6.

On FIG. 37 shows a block for studying the emission spectrum of nuclear quadrupole resonance signals 12, containing a frequency spectrum analyzer 12.1 and a ten-pin switch Vk.1 for ten switching positions and a transformer Tr.1, while ten inputs from the first 1 to the tenth 10 of the block for studying the radiation spectrum 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 12.1; in addition, the one-one input 1.1 of the nuclear quadrupole resonance radiation spectrum research unit 12 is connected to the terminal "a1" of the first primary winding of the transformer Tr.1, and the first primary winding of the transformer Tr.1 is grounded by terminal "d1"; input two-one 2.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a2" of the second primary winding of the transformer Tr.1, and the second primary winding of the transformer Tr.1 is grounded by terminal "d2"; the three-one input 3.1 of the nuclear quadrupole resonance radiation spectrum study block 12 is connected to terminal "a3" of the third primary winding of the transformer Tr.1, and the third primary winding of the transformer Tr.1 is grounded by terminal "d3"; four-one input 4.1 of the nuclear quadrupole resonance radiation spectrum study block 12 is connected to the terminal "a4" of the fourth primary winding of the transformer Tr.1, and the fourth primary winding of the transformer Tr.1 is grounded by terminal "d4"; the input five-one 5.1 of the block for studying the radiation spectrum of the signals of nuclear quadrupole resonance 12 is connected to the terminal "a5" of the fifth primary winding of the transformer Tr.1, and the terminal "d5" the fifth primary winding of the transformer Tr.1 is grounded; input six-one 6.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a6" of the sixth primary winding of the transformer Tr.1, and the sixth primary winding of the transformer Tr.1 is grounded by terminal "d6"; input seven-one 7.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a7" of the seventh primary winding of the transformer Tr.1, and the seventh primary winding of the transformer Tr.1 is grounded by terminal "d7"; the input eight-one 8.1 of the block for studying the radiation spectrum of the signals of nuclear quadrupole resonance 12 is connected to the terminal "a8" of the eighth primary winding of the transformer Tr.1, and the eighth primary winding of the transformer Tr.1 is grounded by terminal "d8"; input nine-one 9.1 of the block for studying the emission spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a9" of the ninth primary winding of the transformer Tr.1, and the terminal "d9" the ninth primary winding of the transformer Tr.1 is grounded; input ten-one 10.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a10" of the tenth primary winding of the transformer Tr.1, and the tenth primary winding of the transformer Tr.1 is grounded by terminal "d10"; the secondary winding of the transformer Tr.1 is grounded by the “k” terminal, and by the “c” terminal it is connected to the output of the block for studying the emission spectrum of nuclear quadrupole resonance signals 12.

On FIG. 38 shows an analytical block 13 of weak NQR signals, containing: a transformer Tr.1 with ten primary windings and one secondary winding, ten microprocessors from the first - 13.1 to the tenth - 13.10, ten valves from the first - D.1 to the tenth - D.10, ten high-resistance resistors with a nominal value of 100 kOhm from the first - R ₁ to the tenth - R ₁₀ , the first input contains ten inputs from the first to the tenth for connection with ten outputs of the filter unit 10 (Fig. 1), the second input contains ten inputs from the eleventh to the twentieth for connections with ten outputs of the ambient temperature control unit 14 (Fig. 1 and Fig. 39), while the first input 1 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the first switch Vk.1, through the first valve D ₁ , through the first terminal "c ₁ " with the first input 1 of the first microprocessor 13.1, in parallel, the terminal "c ₁ " through the first high-resistance resistor R ₁ is grounded, the eleventh input of the analytical unit 13 of weak NQR signals is connected to about the second input 2 of the first microprocessor 13.1; the output of the first microprocessor 13.1 is connected to the first primary winding of the transformer Tr.1 through the terminal "a1", and the terminal "d1" of the first primary winding of the transformer Tr.1 is grounded; the second input 2 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the second switch Vk.2, through the second valve D ₂ , through the second terminal "c ₂ " with the first input 1 of the second microprocessor 13.2, in parallel with the terminal "c ₂ "through the second high-resistance resistor R ₂ is grounded, the twelfth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the second microprocessor 13.2; the output of the second microprocessor 13.2 is connected to the second primary winding of the transformer Tr.1 through the terminal "a2", and the terminal "d2" of the second primary winding of the transformer Tr.1 is grounded; the third input 3 of the analytical block 13 of weak NQR signals is connected through the terminals "a" and "b" of the third switch Vk.3, through the third valve D ₃ , through the third terminal "c ₃ " with the first input 1 of the third microprocessor 13.3, in parallel with the terminal "c ₃ "through the third high-resistance resistor R ₃ is grounded, the thirteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the third microprocessor 13.3; the output of the third microprocessor 13.3 is connected to the third primary winding of the transformer Tr.1 through the terminal "a3", and the terminal "d3" of the third primary winding of the transformer Tr.1 is grounded; the fourth input 4 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the fourth switch Vk.4, through the fourth valve D ₄ , through the fourth terminal "c ₄ " with the first input 1 of the fourth microprocessor 13.4, in parallel with the terminal "c ₄ "through the fourth high-resistance resistor R ₄ is grounded, the fourteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the fourth microprocessor 13.4; the output of the fourth microprocessor 13.4 is connected to the fourth primary winding of the transformer Tr.1 through the terminal "a4", and the terminal "d4" of the fourth primary winding of the transformer Tr.1 is grounded; the fifth input 5 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the fifth switch Vk.5, through the fifth valve D ₅ , through the fifth terminal "c ₅ " with the first input 1 of the fifth microprocessor 13.5, in parallel with the terminal "c ₅ "through the fifth high-resistance resistor R ₅ is grounded, the fifteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the fifth microprocessor 13.5; the output of the fifth microprocessor 13.5 is connected to the fifth primary winding of the transformer Tr.1 through the terminal "a5", and the terminal "d5" of the fifth primary winding of the transformer Tr.1 is grounded; the sixth input 6 of the analytical block 13 of weak NQR signals is connected through the terminals "a" and "b" of the sixth switch Vk.6, through the sixth valve D ₆ , through the sixth terminal "c ₆ " with the first input 1 of the sixth microprocessor 13.6, in parallel with the terminal "c ₆ "through the sixth high-resistance resistor R ₆ is grounded, the sixteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the sixth microprocessor 13.6; the output of the sixth microprocessor 13.6 is connected to the sixth primary winding of the transformer Tr.1 through the terminal "a6", and the terminal "d6" of the sixth primary winding of the transformer Tr.1 is grounded; the seventh input 7 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the seventh switch Vk.7, through the seventh valve D ₇ , through the seventh terminal "c ₇ " with the first input 1 of the seventh microprocessor 13.7, in parallel with the terminal "c ₇ "through the seventh high-resistance resistor R ₇ is grounded, the seventeenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the seventh microprocessor 13.7; the output of the seventh microprocessor 13.7 is connected to the seventh primary winding of the transformer Tr.1 through the terminal "a7", and the terminal "d7" of the seventh primary winding of the transformer Tr.1 is grounded; the eighth input 8 of the analytical block 13 of weak NQR signals is connected through the terminals "a" and "b" of the eighth switch Vk.8, through the eighth valve D&, through the eighth terminal "c ₈ " with the first input 1 of the eighth microprocessor 13.8, in parallel with the terminal "c ₈ » through the eighth high-resistance resistor R ₈ is grounded, the eighteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the eighth microprocessor 13.8; the output of the eighth microprocessor 13.8 is connected to the eighth primary winding of the transformer Tr.1 through the terminal "a8", and the terminal "d8" of the eighth primary winding of the transformer Tr.1 is grounded; the ninth input 9 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the ninth switch Vk.9, through the ninth valve D ₉ , through the ninth terminal "c ₉ " with the first input 1 of the ninth microprocessor 13.9, in parallel with the terminal "c ₉ "through the ninth high-resistance resistor R.9 is grounded, the nineteenth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the ninth microprocessor 13.9; the output of the ninth microprocessor 13.9 is connected to the ninth primary winding of the transformer Tr.1 through the terminal "a9", and the terminal "d9" of the ninth primary winding of the transformer Tr.1 is grounded; the tenth input 10 of the analytical unit 13 of weak NQR signals is connected through the terminals "a" and "b" of the tenth switch Vk.10, through the tenth valve D ₁₀ , through the tenth terminal "c ₁₀ " with the first input 1 of the tenth microprocessor 13.10, in parallel with the terminal "c ₁₀ "through the tenth high-resistance resistor R ₁₀ is grounded, the twentieth input of the analytical unit 13 of weak NQR signals is connected to the second input 2 of the tenth microprocessor 13.10; the output of the tenth microprocessor 13.10 is connected to the tenth primary winding of the transformer Tr.1 through the terminal "a10", and the terminal "d10" of the tenth primary winding of the transformer Tr.1 is grounded; the secondary winding of the transformer Tr.1 is connected by terminal "c" to the output of the analytical unit 13 of weak NQR signals, and the secondary winding of the transformer Tr.1 is grounded by the terminal "k".

The work of the analytical block 13 of weak NQR signals is related to the temperature of the medium in which the NQR signals are studied. The ambient temperature control unit 14 provides a change in the operation of the amplifiers (microprocessors) in the analytical unit 13, which contributes to the reception of weak NQR signals.

On FIG. 39 shows an ambient temperature control unit 14 containing a temperature converter - electric potential 14.1 and a ten-pin switch Vk.14.2, while the output of the temperature converter - electric potential 14.1 is connected in parallel with the terminal "b" of each switch from the first switch 1 to the tenth switch 10 in a ten-pin switch Vk.14.2, terminal "a" of the first switch 1 is connected to the eleventh output of the ambient temperature control unit 14, terminal "a" of the second switch 2 is connected to the twelfth output of the ambient temperature control unit 14, terminal "a" of the third switch 3 is connected to the thirteenth output of the ambient temperature control unit 14, the terminal "a" of the fourth switch 4 is connected to the fourteenth output of the ambient temperature control unit 14, the terminal "a" of the fifth switch 5 is connected to the fifteenth output of the ambient temperature control unit 14, the terminal "a" of the sixth switch 6 is connected to the shest the tenth output of the ambient temperature control unit 14, the terminal "a" of the seventh switch 7 is connected to the seventeenth output of the ambient temperature control unit 14, the terminal "a" of the eighth switch 8 is connected to the eighteenth output of the ambient temperature control unit 14, the terminal "a" of the ninth switch 9 is connected to the nineteenth output of the ambient temperature control unit 14, terminal "a" of the tenth switch 10 is connected to the twentieth output of the ambient temperature control unit 14.

Thus, the goal set in the presented materials is achieved, the efficiency of the invention model is justified.

The authors are not aware of technical solutions from the field of electronics and radio engineering, containing signs equivalent to the distinctive features of the claimed device. The authors are not aware of technical solutions from other fields of technology that have 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 (29)

1. A device for detecting nuclear quadrupole resonance signals, containing a pumping frequency generator, a power amplifier and a matching device, a frequency pulse shaper, a temporary pulse shaper, a receiving system information shaper, a filter unit, a unit for studying the spectrum of nuclear quadrupole resonance radiation, an operating mode selection unit, multi-frequency an in-phase receiving antenna system with the reception of normally and parallel polarized electromagnetic waves, a multi-frequency in-phase transmitting antenna system with the emission of a normally polarized electromagnetic wave, characterized in that a control system has been additionally introduced for one-time and cyclic independent operation of frequency and time pulse formation units, a nuclear power spectrum analysis unit quadrupole resonance radiation with high weight and size characteristics, are made on the basis of microcircuits: capacitance gyrators G _C and inductance gyrators G _L , an analytical unit with weak NQR signals, an ambient temperature control unit, while the output of the sweeping frequency generator is connected to the first input of the operating mode selection unit through a frequency pulse shaper, through the first switch Vk.1, through its short-circuited terminals "c" and "g", as well as the output of the sweep frequency generator is connected in parallel with the second input of the operating mode selection unit through a temporary pulse generator, through the second switch Vk.2, through its short-circuited terminals "a" and "b"; the third input of the operating mode selection unit is connected through the third switch Vk.3, through its short-circuited terminals "d" and "e" with the output of the block for studying the emission spectrum of nuclear quadrupole resonance signals; the output of the operating mode selection unit through the input of the power amplifier is connected in parallel with the input of the matching device of the transmitting system and through the "n ₁ "input with the shaper information of the receiving system; "n" outputs of the matching device of the transmitting system are connected to each of the "n" emitters, in the system of emitters 7, through the terminal "g", starting from 7 ₁ to 7 _N ; "n" inputs of the information generator of the receiving system are connected to N in-phase lines 6, for example, "n" inputs of the information generator are connected to the first in-phase receiving line from the first antenna 6 ₁₁ to "n" 6 _1N ; the output of the information generator of the receiving system is connected to a block for studying the emission spectrum of nuclear quadrupole resonance signals, through a filter unit and through a block for analyzing the emission spectrum of nuclear quadrupole resonance signals; the output of the filter unit is connected in parallel with the first input of the analytical unit of weak NQR signals, and the second input of the analytical unit of weak NQR signals is connected to the output of the ambient temperature control unit, the output of the analytical unit is connected to the terminal "d" of the third switch Vk.3 of the third input of the mode selection unit work; the radiating part of the device for detecting emitters of nuclear quadrupole resonance radiation is placed between two shielding planes made in the form of truncated cylindrical planes. 2. The device according to claim 1, characterized in that each of the identical emitters from 7 ₁ to 7 _N for the transmitting in-phase antenna system, excites a normally polarized electromagnetic wave with vectors Eg and Hg near the air-surface interface of the medium under study, as with conventional ones, and with magnetic properties, it contains two cylindrical ferrite cores F1 and F2, located horizontally and forming a single emitter of a normally polarized wave, two loop transmitting antennas K1 and K2 with uniform frequency properties of the input impedance in the frequency range from 10 kHz to 10 MHz, placed on ferrite cores F1 and F2, and exciting the magnetic flux in the ferrite; matching transformer Tr.1 with one primary 1 and two secondary windings 2.1 and 2.2, matching device of the transmission system 5, while the matching transformer Tr.1 is connected by the primary winding to one of the outputs of the matching device of the transmission system, and the secondary winding of the transformer Tr.1 is two-section : the first section 2.1 is connected by terminal "a" to the terminal "g1" of the first loop transmitting antenna K1, and by terminal "b" the first section 2.1 is connected to the terminal "g2" of the first loop transmitting antenna K1; the second section 2.2 of the transformer Tr.1 is connected by terminal "g" to the terminal "g3" of the second loop transmitting antenna K2, and by terminal "c" the second section 2.2 is connected to the terminal "g4" of the second loop transmitting antenna K2. 3. The device according to claim 2, characterized in that the structure of the emitter F1 (F2), as one of the elements in each of the N emitters, contains three ferrite cores, each with a diameter of d=4 mm, made using the technology of a three-component structure with a magnetic permeability μ=1000, μ=100 and μ=10; on top of three ferrite cores, coils of conductors of three windings Ob.1, Ob.2 and Ob.3 of the loop antenna are placed, with a conductor cross section of 0.5 mm, 35 turns are located on each core with a length of l \u003d 3 cm, and all three loop antennas are connected in series and form a single circuit with a current, spatially unidirectional i, flowing between the terminals "g1" and "g2"; moreover, all three loop antennas with ferrite cores form a single radiator, represented as F1 or F2. 4. The device according to claim 3, characterized in that the receiving antenna element contains three loop antennas with ferrite cores, and all three loop antennas are connected in series and form a single circuit with an induced current in them, spatially unidirectional i, flowing between the terminals "P1" and "P2"; three ferrite cores, each with a diameter of d=4 mm, made according to the technology of a three-component structure with magnetic permeability μ=1000, μ=100 and μ=10; on top of three ferrite cores, coils of conductors of three windings of a loop antenna are placed, with a conductor cross section of 0.5 mm, 35 turns are located on each core with a length of l \u003d 3 cm, and all three loop antennas are connected in series and placed in a vertical plane with a separation angle of 60 ° between loop antennas with ferrite cores. 5. The device according to claim. 4, characterized in that the receiving antenna of circular polarization 6 ₁₁ contains two elements of the receiving antenna 6 ₁₁ .1 and 6 ₁₁ .2 as elements of a system consisting of N receiving antennas in each line from the first 6 ₁₁ to 6 _1N and N lines in the system from the first 6 _1N to 6 _nn , while each element, for example 6 ₁₁ .1, has three loop antennas with ferrite cores, and three loop antennas A1, A2 and A3 are connected in series and form a single circuit with induced current in them, spatially unidirectional i, flowing between the terminals "P1" and "P2", and in element 6 ₁₁ .2 three loop antennas A4, A5 and A6 are connected in series and form a single circuit with an induced current in them, spatially unidirectional i , flowing between the terminals "P3" and "P4"; six loop antennas with ferrite cores A1, A2, A3, A4, A5 and A6 are located in a vertical plane and form a circular polarization reception, including the reception of both a normally polarized wave on the loop antennas A2 and A5, and a parallel polarized wave on the loop antennas A1, A3, A4 and A6; and radio reception is carried out simultaneously by elements 6 ₁₁ .1 and 6 ₁₁ .2 based on the operation of the summing transformer Tr.1, containing one primary winding 1 and two secondary windings, while the primary winding is connected to the input terminals of the information generator of the receiving system 9, at the same time the first secondary winding 2 ₁ transformer Tr.1 terminal "a" is connected to the terminal "P1", and terminal "b" to the terminal "P2" element 6 _11.1 , the second secondary winding 2 g of the transformer Tr.1 terminal "c" is connected to the terminal " P4”, and terminal “e” with terminal “P3” of element 6 ₁₁ .2. 6. The device according to claim 5, characterized in that the transceiver antenna system, where 6 are elements of the receiving antenna system, consists of N receiving antennas in each line from the first 6 ₁₁ to 6 _1n and N lines in the system from the first 6 _1N to 6 _nn ; in addition, 7 - elements of the transmitting antenna system containing N emitters from the first 7 ₁ to 7 _N . 7. The device according to claim 6, characterized in that the frequency pulse shaper contains the first shaper of groups of one-millisecond frequency pulses, the second shaper of groups of two-millisecond frequency pulses, the third shaper of groups of three-millisecond frequency pulses, the fourth shaper of groups of four-millisecond frequency pulses, the generator of one-millisecond pulses, four four-pin switch: Vk.1, Vk.2, Vk.3 and Vk.4; four elements of AND: the first 2.6, the second 2.7, the third 2.8 and the fourth 2.9; four buttons for a one-time start of the operation of four formers; Book 1, Book 2, Book 3 and Book 4; at the same time, the output of the one-millisecond pulse generator is connected in parallel directly to the first input of the first element And and to the second input of the first element And through the first button Kn. the first output of the first generator of groups of one-millisecond frequency pulses is connected to the output of the generator of frequency impulses through the terminals "c" and "e" of the first four-pin switch Vk.1, the second output of the first generator of groups of one-millisecond frequency impulses is connected to the second input of the first element And through the terminals "a" and "b" of the first four-contact switch Vk.1 for cyclic operation of the first shaper; the output of the one-millisecond pulse generator is connected in parallel directly to the first input of the second element AND and to the second input of the second element AND through the second button Kn. of the second generator of groups of two-millisecond frequency pulses is connected to the output of the generator of frequency impulses through the terminals "c" and "d" of the second four-pin switch Vk.2, the second output of the second generator of groups of two-millisecond frequency impulses is connected to the second input of the second element And through the terminals "a" and " b" of the second four-contact switch Vk.2 for cyclic operation of the second shaper; the output of the one-millisecond pulse generator is connected in parallel directly to the first input of the third element AND and to the second input of the third element AND through the third button Kn. the third generator of groups of three-millisecond frequency impulses is connected to the output of the generator of frequency impulses through the terminals "c" and "d" of the third four-pin switch Vk.3, the second output of the third generator of groups of three-millisecond frequency impulses is connected to the second input of the third element And through the terminals "a" and " b» the third four-contact switch Vk.3 for cyclic operation of the third shaper of groups of three-millisecond frequency pulses; the output of the one-millisecond pulse generator is connected in parallel directly to the first input of the fourth element AND and to the second input of the fourth element AND through the fourth button Kn. of the fourth generator of groups of four-millisecond frequency impulses is connected to the output of the generator of frequency impulses through the terminals "c" and "e" of the fourth four-pin switch Vk.4, the second output of the fourth generator of groups of four-millisecond frequency impulses is connected to the second input of the fourth element And through the terminals "a" and " b" fourth four-contact switch Vk.4 for cyclic operation of the fourth generator of groups of four-millisecond frequency pulses; the input of the frequency pulse shaper is connected in parallel with the second input of the first shaper of groups of one-millisecond frequency pulses, with the second input of the second shaper of groups of two-millisecond frequency pulses, with the second input of the third shaper of groups of three-millisecond frequency pulses, and with the second input of the fourth shaper of groups of four-millisecond frequency pulses. 8. The device according to claim 7, characterized in that the first generator of groups of one-millisecond frequency pulses contains the first gate B.1, the second gate B.2, the third gate B.3, the fourth gate B.4, the fifth gate B.5, the sixth gate B.6, seventh gate B.7, eighth gate B.8, ninth gate B.9, tenth gate B.10, first delay line for 2 ms, second delay line for 2 ms, third delay line for 4 ms, the fourth delay line for 2 ms, the fifth delay line for 4 ms, the one-millisecond trigger, the sixth delay line for 8 ms, the seventh delay line for 10 ms, the first element And, the second element And, the frequency multiplier by two, while the first button is Kn. 1, to start the one-millisecond trigger, for a short time, the generator of one-millisecond pulses of the frequency pulse shaper is connected to the first input of the first shaper of groups of one-millisecond frequency pulses, the first input is connected to the input of the one-millisecond trigger; the output of the one-millisecond trigger is connected in parallel with the input of the sixth delay line for 8 ms, and through the first gate B.1 and through the first delay line for 2 ms with the second input of the first element AND, also through the second gate B.2 with the second input of the first element AND; the output of the sixth delay line for 8 ms is connected in parallel with the input of the seventh delay line for 10 ms, and through the third gate B.3 and through the second delay line for 2 ms with the second input of the second element AND, also through the fourth gate B.4 and through the third delay line for 4 ms with the second input of the first element AND, as well as through the fifth gate B.5 with the second input of the first element AND; the output of the seventh delay line for 10 ms is connected in parallel through the sixth gate B.6 through the fourth delay line for 2 ms with the second input of the first element AND, and through the seventh gate B.7 and through the fifth delay line for 4 ms in parallel: through the ninth gate B .9 with the second input of the second element AND, and through the tenth gate B.10 with the second output of the first generator of groups of one-millisecond frequency pulses, in addition, the output of the seventh delay line for 10 ms is connected through the eighth gate B.8 with the second input of the second element AND; the output of the second element And connected to the first output of the first shaper groups of one-millisecond frequency pulses; the second input of the first generator of groups of one-millisecond frequency pulses is connected in parallel with the first input of the first element And and through a frequency multiplier by two with the first input of the second element And; the output of the first element And connected to the first output of the first shaper groups of one-millisecond frequency pulses; the duration of all pulses generated by the first group shaper of one-millisecond pulses with frequency filling of pulses corresponds to τ=1 ms, and the first group shaper of one-millisecond pulses with frequency filling forms three groups of pulses: the first group is two pulses, the second is three and the third is three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency ƒ ₁ , a sweep frequency generator in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with a doubled frequency 2ƒ ₁ . 9. The device according to claim 8, characterized in that the second generator of groups of two-millisecond frequency pulses contains the eleventh gate B.11, the twelfth gate B.12, the thirteenth gate B.13, the fourteenth gate B.14, the fifteenth gate B.15, the sixteenth gate B.16, seventeenth gate B.17, eighteenth gate B.18, nineteenth gate 19, twentieth gate B.20, first delay line for 3 ms, second delay line for 3 ms, third delay line for 6 ms, fourth line delay by 3 ms, the fifth delay line by 6 ms, a two-millisecond trigger, the sixth delay line by 10 ms, the seventh delay line by 13 ms, the first element And, the second element And, a frequency multiplier by two, while the second button Kn.2 for triggering a two-millisecond trigger for a short time, the generator of one-millisecond pulses of the frequency pulse shaper is connected to the first input of the second shaper of groups of two-millisecond frequency pulses, the first input of the second shaper of groups of two-millisecond millisecond frequency pulses connected to the input of a two-millisecond trigger; the output of the two-millisecond trigger is connected in parallel through the eleventh gate B.11 and through the first delay line for 3 ms with the second input of the first element AND, also the output of the two-millisecond trigger is connected through the twelfth gate B.12 with the second input of the first element AND; the output of the two-millisecond trigger is connected to the input of the sixth delay line for 10 ms; the output of the sixth delay line for 10 ms is connected in parallel with the input of the seventh delay line for 13 ms, and through the thirteenth gate B.13 and through the second delay line for 3 ms with the second input of the second element And; also, the output of the sixth delay line for 10 ms is connected through the fourteenth gate B.14 and through the third delay line for 6 ms with the second input of the first element AND, and the output of the sixth delay line for 10 ms is connected through the fifteenth gate B.15 with the second input of the first element And; the output of the seventh delay line for 13 ms is connected in parallel through the sixteenth gate B.16 and through the fourth delay line for 3 ms with the second input of the first element AND, also the output of the seventh delay line for 13 ms through the eighteenth gate B.18 is connected to the second input of the second element And, and the output of the seventh delay line for 13 ms is connected through the seventeenth gate B.17 and through the fifth delay line for 6 ms in parallel: through the nineteenth gate B.19 with the second input of the second element And, and through the twentieth gate 20 with the second output of the second shaper groups of two millisecond frequency pulses; the output of the second element And connected to the first output of the second shaper groups of two millisecond frequency pulses; the second input of the second shaper of groups of two-millisecond frequency pulses is connected in parallel with the first input of the first element And and also through a frequency multiplier by two with the first input of the second element And; the output of the first element And connected to the first output of the second shaper groups of two millisecond frequency pulses; the duration of all pulses generated by the second group former are two milliseconds with frequency filling of the pulses, i.e. corresponds to τ=2 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable operating frequency f ₁ of the sweep frequency generator 1 in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ . 10. The device according to claim 9, characterized in that the third generator of groups of three-millisecond frequency pulses contains the twenty-first gate B.21, the twenty-second gate B.22, the twenty-third gate B.23, the twenty-fourth gate B.24, the twenty-fifth gate B.25, twenty-sixth gate B.26, twenty-seventh gate B.27, twenty-eighth gate B.28, twenty-ninth gate B.29, thirtieth gate 30, first delay line for 4 ms, second delay line for 4 ms , third delay line for 8 ms, fourth delay line for 4 ms, fifth delay line for 8 ms, sixth delay line for 12 ms, seventh delay line for 16 ms, three-millisecond trigger, first AND element, second AND element, frequency multiplier by two, the third button Kn.3 triggers a three-millisecond trigger in the third shaper of groups of three-millisecond frequency pulses for a short time, the generator of the shaper of frequency pulses is connected to the first input of the third shaper of groups of three-millisecond frequency hundred pulses, the first input of the third shaper of groups of three-millisecond frequency pulses is connected to the input of a three-millisecond trigger; the output of the three-millisecond trigger is connected in parallel with the input of the sixth delay line for 12 ms, and through the twenty-first gate B.21 and through the first delay line for 4 ms with the second input of the first element And; in parallel, the output of the three-millisecond trigger is connected through the twenty-second gate B.22 with the second input of the first element And; the output of the sixth delay line for 12 ms is connected in parallel with the input of the seventh delay line for 16 ms, in parallel the output of the sixth delay line for 12 ms through the twenty-third gate B.23 and through the second delay line for 4 ms is connected to the second input of the second element AND, also the output of the sixth delay line for 12 ms is connected through the twenty-fourth gate B.24 and through the third delay line for 8 ms with the second input of the first element AND, and the output of the sixth delay line for 12 ms is connected through the twenty-fifth gate B.25 with the second input the first element And; the output of the seventh delay line for 16 ms is connected in parallel through the twenty-sixth gate B.26 and through the fourth delay line for 4 ms with the second input of the first element AND, and the output of the seventh delay line for 16 ms is connected through the twenty-seventh gate B.27, through the fifth a delay line for 8 ms in parallel: through the twenty-ninth gate B.29 with the second input of the second element And, and through the thirtieth gate B.30 with the second output of the third shaper of groups of three-millisecond frequency pulses; in addition, the output of the seventh delay line for 16 ms is connected through the twenty-eighth gate B.28 with the second input of the second element And; the output of the second element And connected to the first output of the third shaper groups of three-millisecond frequency pulses; the second input of the third generator of groups of three-millisecond frequency pulses is connected in parallel with the first input of the first element And and also through a frequency multiplier by two with the first input of the second element And; the output of the first element And connected to the first output of the third shaper groups of three-millisecond frequency pulses; the duration of all pulses generated by the third group former are three milliseconds with frequency filling of the pulses, i.e. corresponds to τ=3 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 in the frequency range from 10 kHz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ . 11. The device according to claim 10, characterized in that the fourth four-millisecond frequency pulse group generator contains the thirty-first gate B.31, the thirty-second gate B.32, the thirty-third gate B.33, the thirty-fourth gate B.34, the thirty-fifth gate B.35, thirty-sixth gate B.36, thirty-seventh gate B.37, thirty-eighth gate B.38, thirty-ninth gate B.39, fortieth gate B.40 first delay line for 5 ms, second delay line for 5 ms , the third delay line for 10 ms, the fourth delay line for 5 ms, the fifth delay line for 10 ms, the four-millisecond trigger, the sixth delay line for 14 ms, the seventh delay line for 19 ms, the first AND element, the second AND element, the frequency multiplier by two, with the fourth button Kn.4 triggering a four-millisecond trigger for a short time, the generator of one-millisecond pulses of the frequency pulse shaper is connected to the first input of the fourth shaper of the groups of four-millisecond frequency and mpulses, the first input of the fourth generator of groups of four-millisecond frequency pulses is connected to the input of a four-millisecond trigger; the output of the four-millisecond trigger is connected in parallel with the input of the sixth delay line for 14 ms, and through the thirty-first gate B.31 and through the first delay line for 5 ms with the second input of the first element AND, also the output of the four-millisecond trigger is connected through the thirty-second gate B.32 with the second input of the first element AND; the output of the sixth delay line for 14 ms is connected in parallel with the input of the seventh delay line for 19 ms, and the output of the sixth delay line for 14 ms through the thirty-third gate B.33 and through the second delay line for 5 ms is connected to the second input of the second element And; also, the output of the sixth delay line for 14 ms is connected through the thirty-fourth gate B.34 and through the third delay line for 10 ms with the second input of the first element And; and also the output of the sixth delay line for 14 ms is connected through the thirty-fifth gate B.35 with the second input of the first element And; the output of the seventh delay line for 19 ms is connected in parallel through the thirty-sixth gate B.36 and through the fourth delay line for 5 ms with the second input of the first element AND, and the output of the seventh delay line for 19 ms is connected through the thirty-seventh gate B.37 and through the fourth a delay line for 10 ms in parallel: through the thirty-ninth gate B.39 with the second output of the second element And, and through the fortieth gate B.40 with the second output of the fourth generator of groups of four-millisecond frequency pulses; in addition, the output of the seventh delay line for 19 ms is connected through the thirty-eighth gate B.38 with the second input of the second element And; the output of the second element And connected to the output of the fourth generator groups of four-millisecond frequency pulses; the second input of the fourth shaper of groups of four-millisecond frequency pulses is connected in parallel with the first input of the first element And and also through a frequency multiplier by two with the first input of the second element And; the output of the first element And connected to the first output of the fourth generator groups of four-millisecond frequency pulses; the duration of all pulses generated by the third group former are four milliseconds with frequency filling of pulses, i.e. corresponds to τ=4 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable operating frequency f ₁ of the sweep frequency generator 1 in the frequency range from 10 Hz to 10 MHz; moreover, the second pulse in the second group, as well as the first and third pulses in the third group, are filled with the doubled frequency 2f ₁ . 12. The device according to claim 11, characterized in that the temporal pulse shaper contains the first shaper of groups of one- and two-millisecond pulses, the second shaper of groups of two- and four-millisecond pulses, the third shaper of groups of three- and six-millisecond pulses, the fourth shaper of groups of four- and eight-millisecond pulses, one-millisecond pulse generator, four four-contact switches: Vk.1, Vk.2, Vk.3 and Vk.4; four elements of AND: first, second, third and fourth; four buttons for a one-time start of the work of four shapers: Kn.1, Kn.2, Kn.3 and Kn.4; at the same time, the output of the one-millisecond pulse generator is connected to the first input of the first generator of groups of one- and two-millisecond pulses through the first input of the first element And, in parallel, the output of the one-millisecond pulse generator is connected to the second input of the first element And through the first button Kn.1 for a one-time start of the first generator, the first output of the first shaper of groups of one- and two-millisecond pulses is connected to the output of the shaper of temporary pulses through the terminals "c" and "d" of the first four-pin switch Vk.1, and the second output of the first shaper of groups of one- and two-millisecond pulses is connected to the second input of the first element AND through terminals "a" and "b" of the first four-contact switch Vk.1 for cyclic operation of the first generator of groups of one- and two-millisecond pulses; the output of the one-millisecond pulse generator is connected to the first input of the second generator of groups of two- and four-millisecond pulses through the first input of the second element AND, and in parallel the output of the one-millisecond pulse generator is connected to the second input of the second element AND through the second button Kn.2 for a one-time start of the second generator, the first output of the second generator of groups of two- and four-millisecond pulses is connected to the output of the generator of temporary impulses through the terminals "c" and "d" of the second four-contact switch Vk.2, and the second output of the second generator of groups of two- and four-millisecond pulses is connected to the second input of the second element AND through terminals "a" and "b" of the second four-contact switch Vk.2 for cyclic operation of the second generator of groups of two- and four-millisecond pulses; the output of the one-millisecond pulse generator is connected to the first input of the third shaper of groups of three- and six-millisecond pulses through the first input of the third element AND, in parallel the output of the one-millisecond pulse generator is connected to the second input of the third element AND through the third button Kn. the shaper of groups of three- and six-millisecond pulses is connected to the output of the shaper of temporary pulses through the terminals "c" and "d" of the third four-contact switch Vk.3, and the second output of the third shaper of groups of three- and six-millisecond pulses is connected to the second input of the third element And through the terminals " a” and “b” of the third four-contact switch Vk.3 for cyclic operation of the third shaper of groups of three- and six-millisecond pulses; the output of the one-millisecond pulse generator is connected to the first input of the fourth generator of groups of four- and eight-millisecond pulses through the first input of the fourth element AND, in parallel the output of the one-millisecond pulse generator is connected to the second input of the fourth element AND through the fourth button Kn.4 for a one-time start of the fourth generator, the first output of the fourth generator of groups of four- and eight-millisecond pulses is connected to the output of the generator of temporary impulses through the terminals "c" and "e" of the fourth four-contact switch Vk.4, and the second output of the fourth generator of groups of four- and eight-millisecond pulses is connected to the second input of the fourth element And through the terminals "a" and "b" of the fourth four-contact switch Vk.4 for cyclic operation of the fourth generator of groups of four- and eight-millisecond pulses; the input of the temporary pulse shaper is connected in parallel with the second input of the first shaper of groups of one- and two-millisecond pulses, with the second input of the second shaper of groups of two- and four-millisecond pulses, with the second input of the third shaper of groups of three- and six-millisecond pulses and with the second input of the fourth shaper of groups of four- and eight millisecond pulses. 13. The device according to claim 12, characterized in that the first generator of groups of one- and two-millisecond pulses contains the first gate B.41, the second gate B.42, the third gate B.43, the fourth gate B.44, the fifth gate B.45 , sixth gate B.46, seventh gate B.47, eighth gate B.48, ninth gate B.49, first delay line for 2 ms, second delay line for 8 ms, third delay line for 13 ms, fourth delay line for 22 ms, fifth delay line at 10 ms, sixth delay line at 19 ms, seventh delay line at 10 ms, first trigger at 1 ms, second trigger at 2 ms, AND element; with the first button Kn.1 to start the first trigger of one-millisecond 1 ms for a short time, the one-millisecond pulse generator of the temporary pulse shaper is connected to the first input of the first shaper of groups of one- and two-millisecond pulses; the first input of the first shaper of groups of one- and two-millisecond pulses is connected to the input of the first trigger of one-millisecond 1 ms; the output of the first trigger of one millisecond 1 ms is connected in parallel along five lines with the second input of the AND element: along the first line - through the first gate B.41; on the second line - through the first delay line for 2 ms and through the second gate B.42; on the third line - through the seventh delay line for 10 ms and through the third gate B.43; on the fourth line through the seventh delay line for 10 ms, the second delay line for 8 ms and through the fourth gate B.44; on the fifth line - through the seventh delay line for 10 ms, through the third delay line for 13 ms and through the fifth gate 45; the output of the seventh delay line for 10 ms is connected to the second trigger for 2 ms; the output of the second trigger for 2 ms is connected in three lines with the second input of the AND element: on the first line - through the fourth delay line for 22 ms and through the sixth gate B.46; on the second line - through the fifth delay line for 10 ms and through the seventh gate B.47; on the third line - through the sixth delay line for 19 ms, through the eighth gate B.48 and through the ninth gate B.49; at the same time, the output of the eighth valve B.48 is connected to the second output of the first generator of groups of one- and two-millisecond pulses; the second input of the first generator of groups of one- and two-millisecond pulses is connected to the first input of the AND element; the output of the AND element is connected to the first output of the first generator of groups of one- and two-millisecond pulses; the duration of the pulses generated by the first shaper of groups of one- and two-millisecond pulses with the same frequency filling of the pulses, i.e. corresponds to τ=1 ms, and τ=2 ms, and formed three groups of pulses: the first group of two pulses, the second - three and the third - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable, operating frequency f ₁ of the sweep frequency generator 1 in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 1 ms; two pulses - the first and third of the second group - with a duration of 1 ms, and the second pulse in the group 2 ms; in the third group, the first and third pulses are 2 ms each, and the second pulse is 1 ms. 14. The device according to claim 13, characterized in that the second generator of groups of two- and four-millisecond pulses contains the first gate B.50, the second gate B.51, the third gate B.52, the fourth gate B.53, the fifth gate B.54 , sixth gate B.55, seventh gate B.56, eighth gate B.57, ninth gate B.58, first delay line for 3 ms, second delay line for 10 ms, third delay line for 18 ms, fourth delay line for 30 ms, the fifth delay line for 13 ms, the sixth delay line for 25 ms, the seventh delay line for 10 ms, the first trigger for 2 ms, the second trigger for 4 ms, the AND element, while the second button Kn.2 to start the first trigger two-millisecond 2 ms for a short time, the generator of one-millisecond pulses of the temporary pulse shaper is connected to the first input of the second shaper of groups of two- and four-millisecond pulses; the first input of the second shaper of groups of two and four millisecond pulses is connected to the input of the first trigger for 2 ms; the output of the first trigger for 2 ms is connected in parallel along five lines with the second input of the AND element: along the first line - through the first gate B.50; on the second line - through the first delay line for 3 ms and through the second gate B.51; on the third line - through the seventh delay line for 10 ms and through the third gate B.52; on the fourth line - through the seventh delay line for 10 ms, through the second delay line for 10 ms and through the fourth gate B.53; on the fifth line - through the seventh delay line for 10 ms, through the third delay line for 18 ms and through the fifth gate B.54; in addition, the output of the first trigger for 2 ms is connected to the input of the second trigger for 4 ms through the seventh delay line for 10 ms; the output of the second trigger for 4 ms is connected in three lines with the second input of the AND element: on the first line - through the fourth delay line for 30 ms and through the sixth gate B.55; on the second line - through the fifth delay line for 13 ms and through the seventh gate B.56; on the third line - through the sixth delay line for 25 ms, through the eighth gate B.57 and through the ninth gate B.58; at the same time, the output of the eighth gate B.58 is connected to the second output of the second generator of groups of two- and four-millisecond pulses 3.2; the second input of the second shaper of groups of two and four millisecond pulses is connected to the first input of the AND element; the output of the AND element is connected to the first output of the second generator of groups of two- and four-millisecond pulses; the duration of the pulses created by the second shaper of groups of two- and four-millisecond pulses with the same frequency filling of the pulses, i.e. corresponds to τ=2 ms, and τ=4 ms, and three groups of pulses are formed: the first group - two pulses, the second group - three, and the third group - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable operating frequency f ₁ of the sweep frequency generator 1 in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 2 ms; two pulses - the first and third - of the second group with a duration of 2 ms, and the second pulse in the second group of 4 ms; in the third group, the first and third pulses are 4 ms each, and the second pulse is 2 ms. 15. The device according to claim 14, characterized in that the third generator of groups of three- and six-millisecond pulses contains the first gate B.59, the second gate B.60, the third gate B.61, the fourth gate B.62, the fifth gate B.63 , sixth gate B.64, seventh gate B.65, eighth gate B.66, ninth gate B.67, first delay line for 4 ms, second delay line for 23 ms, third delay line for 37 ms, fourth delay line for 15 ms, the fifth delay line for 11 ms, the sixth delay line for 4 ms, the seventh delay line for 12 ms, the first trigger for 3 ms, the second trigger for 6 ms, the AND element, while the third button Kn.3 to start the first trigger three-millisecond 3 ms for a short time, the generator of one-millisecond pulses of the temporary pulse shaper is connected to the first input of the third shaper of groups of three- and six-millisecond pulses; the first input of the third shaper of groups of three- and six-millisecond pulses is connected to the input of the first trigger for 3 ms; the output of the first trigger for 3 ms is connected in parallel along five lines with the second input of the AND element: along the first line - through the first gate B.59; on the second line - through the first delay line for 4 ms and through the second gate B.60; on the third line - through the seventh delay line for 12 ms and through the third gate B.61; on the fourth line - through the seventh delay line for 12 ms, through the second delay line for 23 ms and through the fourth gate B.62; on the fifth line - through the seventh delay line for 12 ms, through the third delay line for 37 ms and through the fifth gate B.63; in addition, the output of the seventh delay line for 12 ms is connected to the input of the second trigger for 6 ms; the output of the second trigger for 6 ms is connected in three lines with the second input of the AND element: on the first line - through the fourth delay line for 15 ms and through the sixth gate B.64; on the second line - through the fifth delay line for 11 ms and through the seventh gate B.65; on the third line - through the seventh delay line for 4 ms, through the eighth gate B.66 and through the ninth gate B.67; at the same time, the output of the eighth valve B.66 is connected to the second output of the third shaper of groups of three- and six-millisecond pulses; the second input of the third shaper groups of three - and six-millisecond pulses is connected to the first input of the element And; the output of the AND element is connected to the first output of the third shaper of groups of three- and six-millisecond pulses; the duration of the pulses generated by the third group shaper, three- and six-millisecond pulses with the same frequency filling of the pulses, i.e. corresponds to τ=3 ms, and τ=6 ms; moreover, three groups of pulses are formed: the first group is two pulses, the second group is three and the third group is three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable operating frequency f ₁ of the sweep frequency generator 1 in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 3 ms; two pulses - the first and third - of the second group with a duration of 3 ms, and the second pulse in the second group is 6 ms; in the third group, the first and third pulses are 6 ms each, and the second pulse is 3 ms. 16. The device according to claim 15, characterized in that the fourth generator of groups of four- and eight-millisecond pulses contains the first gate B.68, the second gate B.69, the third gate B.70, the fourth gate B.71, the fifth gate B.72 , sixth gate B.73, seventh gate B.74, eighth gate B.75, ninth gate B.76, first delay line for 5 ms, second delay line for 14 ms, third delay line for 32 ms, fourth delay line for 5 ms, the fifth delay line for 23 ms, the sixth delay line for 37 ms, the seventh delay line for 14 ms, the first trigger for 4 ms, the second trigger for 8 ms, the AND element, while the fourth button Kn.4 to start the first trigger four-millisecond 4 ms for a short time, the generator of one-millisecond pulses of the temporary pulse shaper is connected to the first input of the fourth shaper of groups of four- and eight-millisecond pulses; the first input of the fourth shaper of groups of four and eight millisecond pulses is connected to the input of the first trigger for 4 ms; the output of the first trigger for 4 ms is connected in parallel along five lines with the second input of the element And 92: along the first line - through the first valve B.68; on the second line - through the first delay line for 5 ms and through the second gate B.69; on the third line - through the seventh delay line for 14 ms and through the third gate B.70; on the fourth line - through the seventh delay line for 14 ms, through the second delay line for 14 ms and through the fourth gate B.71; on the fifth line - through the seventh delay line for 14 ms, through the third delay line for 32 ms and through the fifth gate B.72; in addition, the output of the seventh delay line for 14 ms is connected to the input of the second trigger for 8 ms; the output of the second trigger for 8 ms is connected in three lines with the second input of the AND element: on the first line - through the fourth delay line for 5 ms and through the sixth gate B.73; on the second line - through the fifth delay line for 23 ms and through the seventh gate B.74; on the third line - through the sixth delay line for 37 ms, through the eighth gate B.75 and through the ninth gate B.76; at the same time, the output of the eighth valve B.75 is connected in parallel with the second output of the fourth generator of groups of four and eight millisecond pulses; the second input of the fourth generator groups of four - and eight-millisecond pulses is connected to the first input of the element And; the output of the AND element is connected to the first output of the fourth generator of groups of four and eight millisecond pulses; the duration of the pulses generated by the fourth group shaper, four- and eight-millisecond pulses with the same frequency filling of the pulses, i.e. corresponds to τ=4 ms, and τ=8 ms, and three groups of pulses are formed: the first group - two pulses, the second group - three and the third group - three; the distance between pulses in each group is 1 ms and the distance between groups is 5 ms; filling (modulation) of pulses with a reasonable operating frequency f ₁ of the sweep frequency generator 1 in the frequency range from 10 kHz to 10 MHz; moreover, the duration of the first group of two pulses is the same and equal to 4 ms; two pulses - the first and third - of the second group with a duration of 4 ms, and the second pulse in the second group 8 ms, in the third group the first and third with a duration of 8 ms, and the second pulse 4 ms. 17. The device according to claim 16, characterized in that the operating mode selection unit contains a transformer Tr.1 with three primary windings and one secondary winding, while the first input of the operation mode selection unit is connected to the terminal "b ₁ " of the first primary winding of the transformer Tr .1, and the first primary winding of the transformer Tr.1 is grounded by terminal "a ₁ "; the second input of the operating mode selection unit is connected to the terminal "b ₂ " of the second primary winding of the transformer Tr.1, and the terminal "a ₂ " the second primary winding of the transformer Tr.1 is grounded; the third input of the operating mode selection block is connected to the terminal "b ₃ " of the third primary winding of the transformer Tr.1, and the terminal "a ₃ " the third primary winding of the transformer Tr.1 is grounded; the secondary winding of the transformer Tr.1 is connected by terminal "e" to the output of the operating mode selection unit, and the secondary winding of the transformer Tr.1 is grounded by terminal "c". 18. The device according to claim 17, characterized in that the matching device of the transmission system contains a transformer Tr.1 with one primary winding and N secondary windings, while the input of the matching device of the transmission system is connected to the terminal "C" of the primary winding of the transformer Tr.1, terminal "D" of this primary winding of the transformer Tr.1 is grounded; output 7 ₁ of the matching device of the transmission system is connected to the terminal "a ₁ " of the first secondary winding of the transformer Tr.1, and the terminal "in ₁ " of this first secondary winding is grounded; the output 7 ₂ of the matching device of the transmission system is connected to the terminal "a ₂ " of the second secondary winding of the transformer Tr.1, and the terminal "in ₂ " of this second secondary winding is grounded; output 7 ₃ of the matching device of the transmission system is connected to the terminal "a ₃ " of the third secondary winding of the transformer Tr.1, and the terminal "in ₃ " of this third secondary winding is grounded; output 7 _N-1 of the matching device of the transmission system is connected to the terminal "a _N-1 " N-1 of the secondary winding of the transformer Tr.1, and the terminal "in _N-1 " of this N-1 secondary winding is grounded; the output 7 _N of the matching device of the transmission system is connected to the terminal “a _N ” N of the secondary winding of the transformer Tr.1, and the terminal “in _N ” of this N secondary winding is grounded. 19. The device according to p. 18, characterized in that the information generator of the receiving system contains a matching device of the first in-phase receiving antenna line, including information from the first line from 6 ₁₁ to N antenna 6 _1N ; matching device of the second in-phase receiving antenna line, including information from the second antenna line from 6 ₂₁ to N antenna 6 _2N ; matching device of the third in-phase receiving antenna line, including information from the third antenna line from 6 ₃₁ to N antenna 6 _3N ; matching device N-1 in-phase receiving antenna line, including information from N-1 antenna line from 6 _N-1.N to N antenna 6 _N-1.N ; matching device N in-phase receiving antenna line, including information from the N antenna line from 6 _N1 to N antenna 6 _NN ; an amplifier in each of the N receiver lines; matching device of the receiving antenna system; the first input of the information generator of the receiving system is connected through the first input of the matching device of the first in-phase receiving antenna line, through the amplifier with the first output of the matching device of the receiving antenna system; the second input of the information generator of the receiving system is connected through the first input of the matching device of the second in-phase receiving antenna line, through the amplifier with the second input of the matching device of the receiving antenna system; the third input of the information generator of the receiving system is connected through the first input of the matching device of the third in-phase receiving antenna line, through the amplifier with the third input of the matching device of the receiving antenna system; n-1 input of the information generator of the receiving system is connected through the first input of the matching device N-1 of the in-phase receiving antenna line, through the amplifier with the n-1 input of the matching device of the receiving antenna system; n the input of the information generator of the receiving system is connected through the first input of the matching device N of the in-phase receiving antenna line, through the amplifier with the n input of the matching device of the receiving antenna system; m the input of the information generator of the receiving system is connected in parallel with the second input of the matching device of the first in-phase receiving antenna line, with the second input of the matching device of the second in-phase receiving antenna line, with the second input of the matching device of the third in-phase receiving antenna line, with the second input of the matching device N-1 of the in-phase receiving antenna line, with the second input of the matching device N in-phase receiving antenna line; the output of the matching device of the receiving antenna system is connected to the output of the information generator of the receiving system. 20. The device according to claim 19, characterized in that the matching device for the antennas of the first in-phase receiving antenna line, for the second; third; …; N-1 and N, contains a switching unit, a transformer Tr.1 with one secondary winding and N primary windings, while the input of one-one matching device, as the output of the first antenna 6 ₁₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , connected through the first input of the switching unit with the terminal "and ₁ " of the first primary winding of the transformer Tr.1, and the terminal "in ₁ " of the first primary winding is grounded; the input of one or two matching devices, as the output of the second antenna 6 ₂₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit to the terminal "a ₂ " of the second primary winding of the transformer Tr.1, and the terminal "in ₂ » the second primary winding is grounded; the input of one or three matching devices, as the output of the third antenna 6 ₃₁ from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit to the terminal "a ₃ " of the third primary winding of the transformer Tr.1, terminal " in ₃ " the third primary winding is grounded; input one -n-1 of the matching device, as the output of N-1 antenna 6 _N-1.1 from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit to the terminal "a _N-1 " N-1 of the primary winding transformer Tr.1, and the terminal "in _N-1 " N-1 of the primary winding is grounded; the input of one-n matching device, as the output N of the receiving antenna 6 _N.1 from the first in-phase receiving antenna line 6 ₁₁ -6 _1N , is connected through the first input of the switching unit to the terminal "a _N " N of the primary winding of the transformer Tr.1, and the terminal "in _N " N primary winding is grounded; the second input of the matching device is connected in parallel with the second inputs of all N switching units; the terminal "K" of the secondary winding of the transformer Tr.1 is connected to the output of the matching device, and the terminal "M" of the secondary winding of the transformer Tr.1 is grounded. 21. The device according to claim 20, characterized in that the switching unit contains an AND element and a NOT element, wherein the first input of the switching unit is connected to the first input of the AND element, and the second input of the switching unit through the NOT element is connected to the second input of the AND element; the output of the AND element is connected to the output of the switching unit. 22. The device according to claim 21, characterized in that the matching device of the receiving antenna system contains a transformer Tr.1 with "n" primary windings and one secondary winding, while the first input of the matching device of the receiving antenna system, as the output of the first in-phase receiving antenna line 6 ₁₁ -6 _1N , connected by the terminal "a ₁ " of the first primary winding of the transformer Tr.1, and the terminal "in ₁ " of the first primary winding of the transformer Tr.1 is grounded; the second input of the matching device of the receiving antenna system, as the output of the second in-phase receiving antenna line 6 ₂₁ -6 _2N , is connected to the terminal "a ₂ " of the second primary winding of the transformer Tr.1, and the terminal "in ₂ " of the second primary winding of the transformer Tr.1 is grounded ; the third input of the matching device of the receiving antenna system, as the output of the third in-phase receiving antenna line 6 ₃₁ -6 _3N , is connected to the terminal "a ₃ " of the third primary winding of the transformer Tr.1, and the terminal "in ₃ " of the third primary winding of the transformer Tr.1 is grounded ; "n-1" input of the matching device of the receiving antenna system, as the output N-1 of the in-phase receiving antenna line 6 _(N-1)1 -6 _(N-1)N , is connected to the terminal "a _N-1 " N-1 of the primary windings of the transformer Tr.1, and the terminal "in _N-1 " N-1 of the primary winding of the transformer Tr.1 is grounded; "n" the input of the matching device of the receiving antenna system, as the output N of the in-phase receiving antenna line 6 _N1 -6 _nn , is connected to the terminal "a _N " N of the primary winding of the transformer Tr.1, and the terminal "in _N " N of the primary winding of the transformer Tr. 1 grounded; the terminal "C" of the secondary winding of the transformer Tr.1 is connected to the output of the matching device of the receiving antenna system, and the terminal "D" of the secondary winding of the transformer Tr.1 is grounded. 23. The device according to claim 22, characterized in that the filter unit for ten channels contains the first bandpass filter for frequencies of 1-10 kHz, the second bandpass filter for frequencies of 10-50 kHz, the third bandpass filter for frequencies of 50-100 kHz, the fourth bandpass filter filter for frequencies 100-200 kHz, fifth band-pass filter for frequencies 200-400 kHz, sixth band-pass filter for frequencies 400-800 kHz, seventh band-pass filter for frequencies 800-1000 kHz, eighth band-pass filter for frequencies 1-10 MHz, ninth band-pass filter for frequencies 10-20 MHz, the tenth band-pass filter for frequencies 20-40 MHz, the first narrow-band amplifier for the frequency band 1-10 kHz., the second narrow-band amplifier for the frequency band 10-50 kHz, the third narrow-band amplifier for the frequency band 50-100 kHz, the fourth narrow-band amplifier for the frequency band 100-200 kHz, the fifth narrow-band amplifier for the frequency band 200-400 kHz, the sixth narrow-band amplifier for the frequency band 400-800 kHz, the seventh narrow-band amplifier for the frequency band 800-1000 kHz, the eighth narrow-band the 1st amplifier for the frequency band 1-10 MHz, the ninth narrow-band amplifier for the frequency band 10-20 MHz, the tenth narrow-band amplifier for the frequency band 20-40 MHz; each of the ten band-pass filters, from the first 10.1 to the tenth 10.10, contains two resistors R ₁ and R ₂ and two capacitive gyrators G _C1 and G _s2 , while the input of the filter unit for ten channels is connected in parallel with ten inputs of ten band-pass filters from the first to tenth, the outputs of ten bandpass filters through ten narrowband amplifiers form ten filter bank outputs for ten channels; the input of the filter unit for ten channels through the output of the first band-pass filter with a bandwidth of 1 kHz to 10 kHz is connected to the first output of the filter unit through the first narrow-band amplifier; the input of the filter unit for ten channels through the output of the second band-pass filter with a bandwidth of 10 kHz to 50 kHz is connected to the second output of the filter unit through the second narrow-band amplifier; the input of the filter unit for ten channels through the output of the third band-pass filter with a bandwidth of 50 kHz to 100 kHz is connected to the third output of the filter unit through the third narrow-band amplifier; the input of the filter unit for ten channels through the output of the fourth bandpass filter with a bandwidth of 100 kHz to 200 kHz is connected to the fourth output of the filter unit through the fourth narrow-band amplifier; the input of the filter unit for ten channels through the output of the fifth band-pass filter with a bandwidth of 200 kHz to 400 kHz is connected to the fifth output of the filter unit through the fifth narrow-band amplifier; the input of the filter unit for ten channels through the output of the sixth bandpass filter with a bandwidth of 400 kHz to 800 kHz is connected to the sixth output of the filter unit through the sixth narrow-band amplifier; the input of the filter unit for ten channels through the output of the seventh bandpass filter with a bandwidth of 800 kHz to 1000 kHz is connected to the seventh output of the filter unit through the seventh narrow-band amplifier; the input of the filter unit for ten channels through the output of the eighth band-pass filter with a bandwidth of 1.0 to 10 MHz is connected to the eighth output of the filter unit through the eighth narrow-band amplifier; the input of the filter unit for ten channels through the output of the ninth band-pass filter with a bandwidth of 10 to 20 MHz is connected to the ninth output of the filter unit through the ninth narrow-band amplifier; the input of the filter unit for ten channels through the output of the tenth bandpass filter with a bandwidth of 20 to 40 MHz is connected to the tenth output of the filter unit through the tenth narrow-band amplifier; the input of each of the ten band-pass filters, from the first 10.1 to the tenth 10.10, is connected through the terminal "c" to the terminal "d", the terminal "d" is connected through the first capacitive gyrator G _C1 and through the first resistor R ₁ with the output of the band-pass filter, and through the second resistor R ₂ terminal "d" is grounded, while the terminal "c" is grounded through the second capacitive gyrator G _c2 . 24. The device according to p. 23, characterized in that the block for analyzing the spectrum of nuclear quadrupole resonance radiation contains ten oscillatory systems from the first 11.1 to the tenth 11.10 and ten groups of five indicators in each group or fifty indicators, LEDs, from I.1-1 up to I.10-5, five indicators for each oscillatory system, as well as ten groups of five resonance clamps in each group or fifty resonance clamps 1, in addition, ten indicators of justifying the resonance frequency from the first indicator I.1-6 to the tenth I.10-6; the first input of the nuclear quadrupole resonance spectrum analysis unit is connected to the input of the first oscillatory system 11.1 at frequencies of 1-10 kHz, the first output of the first oscillatory system 11.1 is connected to the first inputs of the first group of five indicators from I.1-1 to I.1- 5, and the second output of the first oscillatory system 11.1 is connected to the second inputs of the first group of five indicators from I.1-1 to I.1-5, the third output of the first oscillatory system is connected to the first output of the nuclear quadrupole resonance spectrum analysis unit 11, the fourth output the first oscillatory system 11.1 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the first frequency justification indicator I.1-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the first group I.1-1 is connected to the third input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the first group I.1-2 is connected to the sixth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the first group I.1-3 is connected to the ninth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the first group I.1-4 is connected to the twelfth input of the first indicator of the resonance frequency justification I.1-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the first group I.1-5 is connected to the fifteenth input of the first indicator of the resonance frequency justification I.1-6; the output of the first frequency justification indicator I.1-6 is connected to the first conditional output 1.1 of the nuclear quadrupole resonance spectrum analysis block 11; the second input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the second oscillatory system 11.2 at frequencies of 10-50 kHz, the first output of the second oscillatory system 11.2 is connected to the first inputs of the second group of five indicators from I.2-1 to I.2-5, and the second output of the second oscillatory system 11.2 is connected to the second inputs of the second group of five indicators from I.2-1 to I.2-5, the third output of the second oscillatory system 11.2 is connected to the second output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the second oscillatory system 11.2 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the second frequency justification indicator I.2-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the second group I.2-1 is connected to the third input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the second group I.2-2 is connected to the sixth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the second group I.2-3 is connected to the ninth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the second group I.2-4 is connected to the twelfth input of the second indicator of the resonance frequency justification I.2-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the second group I.2-5 is connected to the fifteenth input of the second indicator of the resonance frequency justification I.2-6; the output of the second frequency justification indicator I.2-6 is connected to the second conditional output 2.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the third input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the third oscillatory system 11.3 at frequencies of 50-100 kHz, the first output of the third oscillatory system 11.3 is connected to the first inputs of the third group of five indicators from I.3-1 to I.3-5, and the second output of the third oscillatory system 11.3 is connected to the second inputs of the third group of five indicators from I.3-1 to I.3-5, the third output of the third oscillatory system 11.3 is connected to the third output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the third oscillatory system 11.3 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the third frequency justification indicator I.3-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the third group I.3-1 is connected to the third input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the third group I.3-2 is connected to the sixth input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the third group I.3-3 is connected to the ninth input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the third group I.3-4 is connected to the twelfth input of the third indicator of the resonance frequency justification I.3-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the third group I.3-5 is connected to the fifteenth input of the third indicator of the resonance frequency justification I.3-6; the output of the third indicator justifying the frequency I.3-6 is connected to the third conditional output 3.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the fourth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the fourth oscillatory system 11.4 at frequencies of 100-200 kHz, the first output of the fourth oscillatory system 11.4 is connected to the first inputs of the fourth group of five indicators from I.4-1 to I.4-5, and the second output of the fourth oscillatory system 11.4 is connected to the second inputs of the fourth group of five indicators from I.4-1 to I.4-5, the third output of the fourth oscillatory system 11.4 is connected to the fourth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the fourth oscillatory system 11.4 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the fourth frequency justification indicator I.4-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the fourth group I.4-1 is connected to the third input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the fourth group I.4-2 is connected to the sixth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the fourth group I.4-3 is connected to the ninth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the fourth group I.4-4 is connected to the twelfth input of the fourth indicator of the resonance frequency justification I.4-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the fourth group I.4-5 is connected to the fifteenth input of the fourth indicator of the justification of the frequency of the resonance I.4-6; the output of the fourth frequency justification indicator I.4-6 is connected to the fourth conditional output 4.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the fifth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the fifth oscillatory system 11.5 at frequencies of 200-400 kHz, the first output of the fifth oscillatory system 11.5 is connected to the first inputs of the fifth group of five indicators from I.5-1 to I.5-5, and the second output of the fifth oscillatory system 11.5 is connected to the second inputs of the fifth group of five indicators from I.5-1 to I.5-5, the third output of the fifth oscillatory system 11.5 is connected to the fifth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the fifth oscillatory system 11.5 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the fifth frequency justification indicator I.5-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the fifth group I.5-1 is connected to the third input of the fifth indicator of the justification of the frequency of the resonance I.5-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the fifth group I.5-2 is connected to the sixth input of the fifth indicator of the justification of the frequency of the resonance I.5-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the fifth group I.5-3 is connected to the ninth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the fifth group I.5-4 is connected to the twelfth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the fifth group I.5-5 is connected to the fifteenth input of the fifth indicator of the justification of the resonance frequency I.5-6; the output of the fifth indicator justifying the frequency I.5-6 is connected to the fifth conditional output 5.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the sixth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the sixth oscillatory system 11.6 at frequencies of 400-800 kHz, the first output of the sixth oscillatory system 11.6 is connected to the first inputs of the sixth group of five indicators from I.6-1 to I.6-5, and the second output of the sixth oscillatory system is connected to the second inputs of the sixth group of five indicators from I.6-1 to I.6-5, the third output of the sixth oscillatory system 11.6 is connected to the sixth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the sixth oscillatory system 11.6 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the sixth frequency justification indicator I.6-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the sixth group I.6-1 is connected to the third input of the sixth indicator of the justification of the frequency of the resonance I.6-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the sixth group I.6-2 is connected to the sixth input of the sixth indicator of the justification of the frequency of the resonance I.6-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the sixth group I.6-3 is connected to the ninth input of the sixth indicator of the justification of the frequency of the resonance I.6-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the sixth group I.6-4 is connected to the twelfth input of the sixth indicator of the justification of the frequency of the resonance I.6-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the sixth group I.6-5 is connected to the fifteenth input of the sixth indicator of the justification of the frequency of the resonance I.6-6; the output of the sixth frequency justification indicator I.6-6 is connected to the sixth conditional output 6.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the seventh input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the seventh oscillatory system 11.7 at frequencies of 800-1000 kHz, the first output of the seventh oscillatory system 11.7 is connected to the first inputs of the seventh group of five indicators from I.7-1 to I.7-5, and the second output of the seventh oscillatory system 11.7 is connected to the second inputs of the seventh group of five indicators from I.7-1 to I.7-5, the third output of the seventh oscillatory system 11.7 is connected to the seventh output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the seventh oscillatory system 11.7 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth, and fourteenth inputs of the seventh frequency justification indicator I.7-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the seventh group I.7-1 is connected to the third input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the seventh group I.7-2 is connected to the sixth input of the seventh indicator of the justification of the frequency of the resonance I.7-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the seventh group I.7-3 is connected to the ninth input of the seventh indicator of the justification of the resonance frequency I.7-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the seventh group I.7-4 is connected to the twelfth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the seventh group I.7-5 is connected to the fifteenth input of the seventh indicator of the resonance frequency justification I.7-6; the output of the seventh frequency justification indicator I.7-6 is connected to the seventh conditional output 7.1 of the nuclear quadrupole resonance spectrum analysis unit 11; the eighth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the eighth oscillatory system 11.8 at frequencies of 1-10 MHz, the first output of the eighth oscillatory system 11.8 is connected to the first inputs of the eighth group of five indicators from I.8-1 to I.8-5, and the second output of the eighth oscillatory system 11.8 is connected to the second inputs of the eighth group of five indicators from I.8-1 to I.8-5, the third output of the eighth oscillatory system 11.8 is connected to the eighth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the eighth oscillatory system 11.8 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the eighth frequency justification indicator I.8-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the eighth group I.8-1 is connected to the third input of the eighth indicator of the resonance frequency justification I.8-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the eighth group I.8-2 is connected to the sixth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the eighth group I.8-3 is connected to the ninth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the eighth group I.8-4 is connected to the twelfth input of the eighth resonance frequency justification indicator I.8-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the eighth group I.8-5 is connected to the fifteenth input of the eighth resonance frequency justification indicator I.8-6; the output of the eighth frequency justification indicator I.8-6 is connected to the eighth conditional output 8.1 of the nuclear quadrupole resonance spectrum analysis block 11; the ninth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the ninth oscillatory system at frequencies of 10-20 MHz, the first output of the ninth oscillatory system 11.9 is connected to the first inputs of the ninth group of five indicators from I.9-1 to I.9-5, and the second output of the ninth oscillatory system 11.9 is connected to the second inputs of the ninth group of five indicators from I.9-1 to I.9-5, the third output of the ninth oscillatory system 11.9 is connected to the ninth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the ninth oscillatory system 11.9 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the ninth frequency justification indicator I.9-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the ninth group I.9-1 is connected to the third input of the ninth indicator of the justification of the frequency of the resonance I.9-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the ninth group I.9-2 is connected to the sixth input of the ninth indicator of the justification of the frequency of the resonance I.9-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the ninth group I.9-3 is connected to the ninth input of the ninth indicator of the justification of the frequency of the resonance I.9-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the ninth group I.9-4 is connected to the twelfth input of the ninth indicator of the justification of the frequency of the resonance I.9-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the ninth group I.9-5 is connected to the fifteenth input of the ninth indicator of the justification of the frequency of the resonance I.9-6; the output of the ninth indicator of frequency justification I.9-6 is connected to the ninth conditional output 9.1 of the block for analyzing the spectrum of nuclear quadrupole resonance radiation 11; the tenth input of the nuclear quadrupole resonance analysis unit 11 is connected to the input of the tenth oscillatory system 11.10 at frequencies of 20-40 MHz, the first output of the tenth oscillatory system 11.10 is connected to the first inputs of the tenth group of five indicators from I.10-1 to I.10-5, and the second output of the tenth oscillatory system 11.10 is connected to the second inputs of the tenth group of five indicators from I.10-1 to I.10-5, the third output of the tenth oscillatory system 11.10 is connected to the tenth output of the nuclear quadrupole resonance spectrum analysis unit 11; the fourth output of the tenth oscillatory system 11.10 is connected in parallel with the first, second, fourth, fifth, seventh, eighth, tenth, eleventh, thirteenth and fourteenth inputs of the tenth frequency justification indicator I.10-6; the output of the resonance latch 1 of the first indicator, determined by the LED, in the tenth group I.10-1 is connected to the third input of the tenth indicator of the justification of the frequency of the resonance I.10-6; the output of the resonance latch 1 of the second indicator, determined by the LED, in the tenth group I.10-2 is connected to the sixth input of the tenth indicator of the justification of the frequency of the resonance I.10-6; the output of the resonance latch 1 of the third indicator, determined by the LED, in the tenth group I.10-3 is connected to the ninth input of the tenth indicator of the justification of the frequency of the resonance I.10-6; the output of the resonance latch 1 of the fourth indicator, determined by the LED, in the tenth group I.10-4 is connected to the twelfth input of the tenth indicator of the justification of the frequency of the resonance I.10-6; the output of the resonance latch 1 of the fifth indicator, determined by the LED, in the tenth group I.10-5 is connected to the fifteenth input of the tenth indicator of the justification of the frequency of the resonance I.10-6; the output of the tenth frequency justification indicator I.10-6 is connected to the tenth conditional output 10.1 of the nuclear quadrupole resonance spectrum analysis unit 11. 25. The device according to item 24, characterized in that the oscillatory system, any of the ten 11.1; 11.2; 11.3; …; 11.10, contains five oscillatory bridges: from the first 1 to the fifth 5; each bridge contains a high-resistance R, four parallel oscillatory circuits made on the basis of microcircuits - capacitive gyrators Gs and inductive gyrators GL: two oscillatory circuits with parameters gyrator GL1 as inductance L ₁ and gyrator Gs1 as capacitance C ₁ , as well as two oscillatory circuits with parameters GL2 as inductance L ₂ and Gc2 as capacitance C ₂ ; to control the resonance of oscillatory systems, two voltage dividers are connected in parallel, made of two high-resistance resistors connected in series, connected in parallel to two parallel oscillatory circuits; while the input of the oscillatory system 11.1 is connected in parallel with the five inputs of the five bridges and with the third output of the oscillatory system 11.1, the first outputs of the five bridges from the first 1 to the fifth 5 form the first output, the second outputs of the five bridges from the first 1 to the fifth 5 form the second output; the input of each bridge is connected through the terminal "c" to the terminal "g" and through the second parallel oscillatory circuit with the parameters GL2 and Gc2 to the terminal "m" and then through the terminal "a" with the first output of the bridge, and in parallel the terminal "c" is connected to terminal "n" and through the first parallel oscillatory circuit with parameters GL1 and Gc1 with terminal "k" and then through terminal "b" with the second output of the bridge; terminal "a" is connected in parallel through high-resistance R with terminal "b" and in parallel terminal "a" is connected through terminal "l", through the first oscillatory circuit with parameters GL1 and Gc1 through terminal "n" with terminal "d", terminal " d” is grounded; in addition, the terminal "b" is connected through the terminal "h", through the second parallel oscillatory circuit with the parameters GL2 and Gc2 through the terminal "x" with the grounded terminal "d"; terminal "n" of the first oscillatory circuit with parameters GL1 and Gc1 is connected through terminal "t" through high-resistance R1, through terminal "h", through high-resistance R2, through terminal "w" with terminal "k" of the first oscillating circuit with parameters GL1 and Гс1, while the terminal "h" is connected to the third output in each of the five oscillatory bridges from the first 1 to the fifth 5; the “h” terminal of the second oscillatory circuit with the parameters GL2 and Gc2 is connected through the “i” terminal through the high-resistance R3, through the “p” terminal, through the high-resistance R4, through the “o” terminal with the “x” terminal of the second oscillatory circuit with the GL2 parameters and Гс2, while the terminal "p" is connected to the fourth output in each of the five oscillatory bridges from the first 1 to the fifth 5; moreover, the third and fourth outputs in each of the five oscillatory bridges from the first to the fifth form a parallel fourth output 4 in any of the ten oscillatory systems from the first 11.1 to the tenth 11.10, while the third output of the first oscillatory bridge is connected to the fourth output of the oscillatory system through its first input , and the fourth output of the first oscillatory bridge is connected to the fourth output of the oscillatory system through its second input; further, the third output of the second oscillatory bridge is connected to the fourth output of the oscillatory system through its fourth input, and the fourth output of the second oscillatory bridge is connected to the fourth output of the oscillatory system through its fifth input; further, the third output of the third oscillatory bridge is connected to the fourth output of the oscillatory system through its seventh input, and the fourth output of the third oscillatory bridge is connected to the fourth output of the oscillatory system through its eighth input; further, the third output of the fourth oscillatory bridge is connected to the fourth output of the oscillatory system through its tenth input, and the fourth output of the fourth oscillatory bridge is connected to the fourth output of the oscillatory system through its eleventh input; further, the third output of the fifth oscillatory bridge is connected to the fourth output of the oscillatory system through its thirteenth input, and the fourth output of the fifth oscillatory bridge is connected to the fourth output of the oscillatory system through its fourteenth input; the first oscillatory system 11.1 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 1.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 2.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 3.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 4.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 5.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 6.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 7.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 8.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 9.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 9.9 kHz; the second oscillatory system 11.2 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 11.9 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 15.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 20.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 25.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 30.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 35.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 40.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 44.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 47.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 49.9 kHz; the third oscillatory system 11.3 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 52.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 58.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 62.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 68.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 72.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 78.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 82.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 88.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 92.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 98.9 kHz; the fourth oscillatory system 11.4 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 110.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 120.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 130.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 140.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 150.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 160.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 170.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 178.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 185.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 198.1 kHz; the fifth oscillatory system 11.5 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 210.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 230.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 250.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 270.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 290.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 310.1 kHz; the fourth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 330.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 350.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 370.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 390.1 kHz; the sixth oscillatory system 11.6 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 410.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 450.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 490.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 530.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 570.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 610.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 650.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 690.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 730.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 790.1 kHz; the seventh oscillatory system 11.7 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 810.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 830.1 kHz; the second bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 850.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 880.1 kHz; the third bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 890.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 910.1 kHz; the fourth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 930.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 950.1 kHz; the fifth bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 970.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 990.1 kHz; the eighth oscillatory system 11.8 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 1100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 1900.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 2900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 3900.1 kHz; the third bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 4900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 5900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 6900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 7900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 8900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 9900.1 kHz; the ninth oscillatory system 11.9 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 10100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 10900.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 12900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 13900.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 14900.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 15900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 16900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 17900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 18900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 19900.1 kHz; the tenth oscillatory system 11.10 contains five bridges: the first bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 21100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 23100.1 kHz; the second bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 25100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 27900.1 kHz; the third bridge with the first parallel oscillatory circuit with the parameters GL1 and Gc1 is tuned to a frequency of 30100.1 kHz, and the second oscillatory circuit with the parameters GL2 and Gc2 is tuned to a frequency of 32900.1 kHz; the fourth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 35100.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 37900.1 kHz; the fifth bridge with the first parallel oscillatory circuit with parameters GL1 and Gc1 is tuned to a frequency of 38900.1 kHz, and the second oscillatory circuit with parameters GL2 and Gc2 is tuned to a frequency of 39900.1 kHz. 26. The device according to claim 25, characterized in that the indicator of justification of the resonance frequency of any of the ten from I.1-6 to I.10-6, containing five switches, transformer Tr.1 with one secondary winding and five primary windings, and each of the five primary windings of the transformer Tr.1 consists of two sections of the same parameters, separated by a middle terminal, while the first input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a1" of the first 1 primary winding of the transformer Tr.1, the second the input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a2" of the first 1 primary winding of the transformer TR.1, the third input of the resonance frequency justification indicator I.1-6 is connected to the first switch of the relay Vk.1, the first primary winding is connected to the middle terminal "a3" is connected to the grounded terminal "a4" when switching the first switch Vk.1 terminal "a5"; the fourth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a6" of the second 2 primary winding of the transformer TR.1, the fifth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a7" of the second 2 primary winding of the transformer TR. 1, the sixth input of the resonance frequency justification indicator I.1-6 is connected to the second switch of the relay Vk.2, the second primary winding is connected by the middle terminal "a8" to the grounded terminal "a9" when switched by the second switch Vk.2 terminal "a10"; the seventh input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a11" of the third 3 primary winding of the transformer TR.1, the eighth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a12" of the third 3 primary winding of the transformer TR. 1, the ninth input of the resonance frequency justification indicator I.1-6 is connected to the third switch of the relay Vk.3, the third primary winding is connected by the middle terminal "a13" to the grounded terminal "a14" when switched by the third switch Vk.3 terminal "a15"; the tenth input of the resonance frequency justification indicator I.1-6 is connected to terminal "a16" of the fourth 4 primary winding of the transformer TR.1, the eleventh input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a17" of the fourth 4 primary winding of the transformer TR. 1, the twelfth input of the resonance frequency justification indicator I.1-6 is connected to the fourth switch of the relay Vk.4, the fourth primary winding is connected by the middle terminal "a18" to the grounded terminal "a19" when switched by the fourth switch Vk.4 by the terminal "a20"; the thirteenth input of the resonance frequency justification indicator I.1-6 is connected to terminal "a21" of the fifth 5 primary winding of the transformer TR.1, the fourteenth input of the resonance frequency justification indicator I.1-6 is connected to the terminal "a22" of the fifth 5 primary winding of the transformer TR. 1, the fifteenth input of the resonance frequency justification indicator I.1-6 is connected to the fifth switch of the relay Vk.5, the fifth primary winding is connected by the middle terminal "a23" to the grounded terminal "a24" when switching the fifth switch Vk.5 to the terminal "a25"; the secondary winding of the transformer Tr.1 is grounded by the “d” terminal, and the “c” terminal is connected to the output 1.1 of the resonance frequency justification indicator I.1-6. 27. The device according to p. 26, characterized in that the block for studying the radiation spectrum of nuclear quadrupole resonance signals 12 contains a frequency spectrum analyzer 12.1 and a ten-pin switch Vk.1 for ten switching positions and a transformer Tr.1, with ten inputs from the first 1 to the tenth 10th radiation spectrum study block is 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 12.1; in addition, the one-one input 1.1 of the block for studying the emission spectrum of nuclear quadrupole resonance signals is connected to the terminal "al" of the first primary winding of the transformer Tr.1, and the first primary winding of the transformer Tr.1 is grounded by terminal "d1"; input two-one 2.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a2" of the second primary winding of the transformer Tr.1, and the second primary winding of the transformer Tr.1 is grounded by terminal "d2"; the three-one input 3.1 of the nuclear quadrupole resonance radiation spectrum study block 12 is connected to terminal "a3" of the third primary winding of the transformer Tr.1, and the third primary winding of the transformer Tr.1 is grounded by terminal "d3"; four-one input 4.1 of the nuclear quadrupole resonance radiation spectrum study block 12 is connected to the terminal "a4" of the fourth primary winding of the transformer Tr.1, and the fourth primary winding of the transformer Tr.1 is grounded by terminal "d4"; the input five-one 5.1 of the block for studying the radiation spectrum of the signals of nuclear quadrupole resonance 12 is connected to the terminal "a5" of the fifth primary winding of the transformer Tr.1, and the terminal "d5" the fifth primary winding of the transformer Tr.1 is grounded; input six-one 6.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a6" of the sixth primary winding of the transformer Tr.1, and the sixth primary winding of the transformer Tr.1 is grounded by terminal "d6"; input seven-one 7.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a7" of the seventh primary winding of the transformer Tr.1, and the seventh primary winding of the transformer Tr.1 is grounded by terminal "d7"; the input eight-one 8.1 of the block for studying the radiation spectrum of the signals of nuclear quadrupole resonance 12 is connected to the terminal "a8" of the eighth primary winding of the transformer Tr.1, and the eighth primary winding of the transformer Tr.1 is grounded by terminal "d8"; input nine-one 9.1 of the block for studying the emission spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a9" of the ninth primary winding of the transformer Tr.1, and the terminal "d9" the ninth primary winding of the transformer Tr.1 is grounded; input ten-one 10.1 of the block for studying the radiation spectrum of signals of nuclear quadrupole resonance 12 is connected to the terminal "a10" of the tenth primary winding of the transformer Tr.1, and the tenth primary winding of the transformer Tr.1 is grounded by terminal "d10"; the secondary winding of the transformer Tr.1 is grounded by the “k” terminal, and by the “c” terminal it is connected to the output of the block for studying the emission spectrum of nuclear quadrupole resonance signals 12. 28. The device according to claim 27, characterized in that the analytical unit 13 of weak NQR signals contains: transformer Tr.1 with ten primary windings and one secondary winding, ten microprocessors from the first 13.1 to the tenth 13.10, ten valves from the first D.1 to tenth D.10, ten high-resistance resistors with a nominal value of 100 kOhm from the first R ₁ to the tenth R ₁₀ , the first input contains ten inputs from the first to the tenth for connection with ten outputs of the filter unit 10, the second input contains ten inputs from the eleventh to the twentieth for connection with ten outputs of the ambient temperature control unit, while the first input of the analytical unit of weak NQR signals is connected through the terminals "a" and "b" of the first switch Vk.1, through the first valve D ₁ , through the first terminal "c ₁ " with the first input of the first microprocessor 13.1, in parallel, the terminal "c ₁ " through the first high-resistance resistor R ₁ is grounded, the eleventh input of the analytical block of weak NQR signals is connected to the second input of the first microprocessor 13.1; the output of the first microprocessor 13.1 is connected to the first primary winding of the transformer Tr.1 through the terminal "a1", and the terminal "d1" of the first primary winding of the transformer Tr.1 is grounded; the second input of the analytical block of weak NQR signals is connected through the terminals "a" and "b" of the second switch Vk.2, through the second valve D ₂ , through the second terminal "c ₂ " with the first input of the second microprocessor 13.2, in parallel with the terminal "c ₂ " through the second high-resistance resistor R ₂ is grounded, the twelfth input of the analytical block of weak NQR signals is connected to the second input of the second microprocessor 13.2; the output of the second microprocessor 13.2 is connected to the second primary winding of the transformer Tr.1 through the terminal "a2", and the terminal "d2" of the second primary winding of the transformer Tr.1 is grounded; the third input of the analytical block of weak NQR signals is connected through terminals "a" and "b" of the third switch Vk.3, through the third valve D ₃ , through the third terminal "c ₃ " with the first input of the third microprocessor 13.3, in parallel with the terminal "c ₃ " through the third high-resistance resistor R ₃ is grounded, the thirteenth input of the analytical block of weak NQR signals is connected to the second input of the third microprocessor 13.3; the output of the third microprocessor 13.3 is connected to the third primary winding of the transformer Tr.1 through the terminal "a3", and the terminal "d3" of the third primary winding of the transformer Tr.1 is grounded; the fourth input of the analytical block of weak NQR signals is connected through terminals "a" and "b" of the fourth switch Vk.4, through the fourth valve D ₄ , through the fourth terminal "c ₄ " with the first input of the fourth microprocessor 13.4, in parallel the terminal "c ₄ " through the fourth high-resistance resistor R ₄ is grounded, the fourteenth input of the analytical block of weak NQR signals is connected to the second input of the fourth microprocessor 13.4; the output of the fourth microprocessor 13.4 is connected to the fourth primary winding of the transformer Tr.1 through the terminal "a4", and the terminal "d4" of the fourth primary winding of the transformer Tr.1 is grounded; the fifth input of the analytical block of weak NQR signals is connected through the terminals "a" and "b" of the fifth switch Vk.5, through the fifth valve D ₅ , through the fifth terminal "c ₅ " with the first input of the fifth microprocessor 13.5, in parallel the terminal "c ₅ " through the fifth high-resistance resistor R ₅ is grounded, the fifteenth input of the analytical block of weak NQR signals is connected to the second input of the fifth microprocessor 13.5; the output of the fifth microprocessor 13.5 is connected to the fifth primary winding of the transformer Tr.1 through the terminal "a5", and the terminal "d5" of the fifth primary winding of the transformer Tr.1 is grounded; the sixth input of the analytical block of weak NQR signals is connected through the terminals "a" and "b" of the sixth switch Vk.6, through the sixth valve D ₆ , through the sixth terminal "c ₆ " with the first input of the sixth microprocessor 13.6, in parallel the terminal "c ₆ " through the sixth high-resistance resistor R ₆ is grounded, the sixteenth input of the analytical block of weak NQR signals is connected to the second input of the sixth microprocessor 13.6; the output of the sixth microprocessor 13.6 is connected to the sixth primary winding of the transformer Tr.1 through the terminal "a6", and the terminal "d6" of the sixth primary winding of the transformer Tr. 1 grounded; the seventh input of the analytical block of weak NQR signals is connected through the terminals "a" and "b" of the seventh switch Vk.7, through the seventh valve D ₇ , through the seventh terminal "c ₇ " with the first input of the seventh microprocessor 13.7, in parallel the terminal "c ₇ " through the seventh high-resistance resistor R ₇ is grounded, the seventeenth input of the analytical block of weak NQR signals is connected to the second input of the seventh microprocessor 13.7; the output of the seventh microprocessor 13.7 is connected to the seventh primary winding of the transformer Tr.1 through the terminal "a7", and the terminal "d7" of the seventh primary winding of the transformer Tr.1 is grounded; the eighth input of the analytical block of weak NQR signals is connected through the terminals "a" and "b" of the eighth switch Vk.8, through the eighth valve D ₈ , through the eighth terminal "c ₈ " with the first input of the eighth microprocessor 13.8, in parallel the terminal "c ₈ " through the eighth high-resistance resistor R ₈ is grounded, the eighteenth input of the analytical block of weak NQR signals is connected to the second input of the eighth microprocessor 13.8; the output of the eighth microprocessor 13.8 is connected to the eighth primary winding of the transformer Tr.1 through the terminal "a8", and the terminal "d8" of the eighth primary winding of the transformer Tr.1 is grounded; the ninth input of the analytical block of weak NQR signals is connected through the terminals "a" and "b" of the ninth switch Vk.9, through the ninth valve D ₉ , through the ninth terminal "c ₉ " with the first input of the ninth microprocessor 13.9, in parallel the terminal "c ₉ " through the ninth high-resistance resistor R ₉ is grounded, the nineteenth input of the analytical block of weak NQR signals is connected to the second input of the ninth microprocessor 13.9; the output of the ninth microprocessor 13.9 is connected to the ninth primary winding of the transformer Tr.1 through the terminal "a9", and the terminal "d9" of the ninth primary winding of the transformer Tr.1 is grounded; the tenth input of the analytical block of weak NQR signals is connected through the terminals "a" and "b" of the tenth switch Vk.10, through the tenth valve D ₁₀ , through the tenth terminal "c ₁₀ " with the first input of the tenth microprocessor 13.10, in parallel the terminal "c ₁₀ " through the tenth high-resistance resistor R ₁₀ is grounded, the twentieth input of the analytical block of weak NQR signals is connected to the second input of the tenth microprocessor 13.10; the output of the tenth microprocessor 13.10 is connected to the tenth primary winding of the transformer Tr.1 through the terminal "a10", and the terminal "d10" of the tenth primary winding of the transformer Tr.1 is grounded; the secondary winding of the transformer Tr.1 is connected by terminal "c" to the output of the analytical unit of weak NQR signals, and the secondary winding of the transformer Tr.1 is grounded by terminal "k". 29. The device according to claim 28, characterized in that the ambient temperature control unit contains a temperature converter - electric potential 14.1 and a ten-pin switch Vk.14.2, while the output of the temperature converter - electric potential is connected in parallel with the terminal "b" of each switch from the first switch 1 to the tenth switch 10 in the ten-contact switch Vk.14.2, terminal "a" of the first switch is connected to the eleventh output of the ambient temperature control unit, terminal "a" of the second switch is connected to the twelfth output of the ambient temperature control unit, terminal "a" of the third of the switch is connected to the thirteenth output of the ambient temperature control unit, the terminal "a" of the fourth switch is connected to the fourteenth output of the ambient temperature control unit, the terminal "a" of the fifth switch is connected to the fifteenth output of the ambient temperature control unit, the terminal "a" of the sixth switch is connected from sixteen th output of the ambient temperature control unit, terminal "a" of the seventh switch is connected to the seventeenth output of the ambient temperature control unit, terminal "a" of the eighth switch is connected to the eighteenth output of the ambient temperature control unit, terminal "a" of the ninth switch is connected to the nineteenth output of the ambient temperature control unit, terminal "a" of the tenth switch is connected to the twentieth output of the ambient temperature control unit.

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