RU2340913C2 - Remote substance detection method - Google Patents

Abstract

FIELD: physics; measurements.

SUBSTANCE: present invention pertains to physical measurements, which use magnetic resonance for searching for and detecting mainly narcotic drugs and explosive substances. A generated ultrabroadband signal is used to irradiate the presumed place where the narcotic drugs are hidden. The reflected signal is received, and gradually stored. The antenna assembly is moved parallel the investigated surface at a fixed distance. At each observation point, at least two successive measurements of the reflected pulses are taken. The pulse, corresponding to the previous measurement, is held until it is compared with the next pulse. Their difference is determined, and the differential signal is integrated. The differential signal is divided by the integrated differential signal. The normal signal is compared to the threshold value of the signal. A narcotic substance is present if the threshold value is exceeded.

EFFECT: wider functional capabilities of the method by way of searching for and detecting narcotic drugs, packed in non-metallic covers and inside concealment environments.

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Description

The proposed method relates to physical measurements, namely to radio engineering tools using magnetic resonance to search and detect mainly drugs and explosives in the composition of substances presented for research, as well as ultra-wideband radar sounding to search and detect drugs packed in a non-metallic shell and located in covering environments, for example in the abdominal cavity of a person used to transport drugs, luggage, suitcases, deep Omata, bags and the like, and can be used at airports, customs terminals, checkpoints, parking, etc.

Known methods for remote detection of a substance (RF patents No. 2128832, 2148817, 2150105, 2161300, 2165104, 2179716, 2185614, 2226686, 2244942, 2249202; US patents No. 4756866, 5986455, 6194898, 6392408; UK patents No. 22549626, 2289344, 2293885; Grechishkin VD et al. Local NQR in solids. Uspekhi Fizicheskikh Nauk, 1993, v.163, No. 10, etc.).

Of the known methods closest to the proposed is the "Method for remote detection of substances" (RF patent No. 2244942, G01R 33/20, 2003), which is selected as a prototype.

The specified method is based on the remote detection of a substance using remote excitation by an electromagnetic wave of magnetic resonance in a substance and then measuring the response frequency, by the presence of which it is concluded that the substance is present, while the exciting electromagnetic signal is emitted at a frequency much higher than the magnetic resonance frequency to be detected substances, and modulate the emitted exciting electromagnetic signal by polarization at the magnetic resonance frequency, and the response to register at the modulation frequency.

However, the known method does not fully realize its potential capabilities, it can use ultra-wideband radar sensing to search for and find drugs packaged in a non-metallic shell and located in covering environments, for example, in the abdominal cavity of a person used to transport drugs, luggage, bags, suitcases, diplomats, etc.

An object of the invention is to expand the functionality of the method by searching and detecting drugs packaged in a non-metallic shell and located in covering environments, for example, in the abdominal cavity of a person used to transport drugs, luggage, bags, suitcases, diplomats, etc.

The problem is solved in that according to the method of remote detection of a substance using remote excitation by an electromagnetic wave of magnetic resonance in a substance and then measuring the response frequency, by the presence of which it is concluded that the substance is present, while the exciting electromagnetic signal is emitted at a frequency much higher magnetic resonance of the substance to be detected, and modulate the emitted exciting electromagnetic signal by polarization at a frequency of m resonance resonance, and the response is recorded at the modulation frequency, a sequence of radio pulses with a small number of periods of high-frequency oscillations in each of them is formed, up to one is irradiated with the probing ultra-wideband signal and the intended location of the substance is packed in a non-metallic shell and located in a covering medium, for example, the abdominal cavity of a person used to transport narcotic drugs, baggage, suitcase, bag, etc., take a reflected ultra-wide a clear signal, it is sequentially accumulated, the antenna unit is moved parallel to the surface being examined at a fixed distance, and at least two consecutive measurements of the indicated reflected pulses are made at each observation point, for this the pulse corresponding to the previous measurement is delayed until it is compared with the next pulse, determine their difference, integrate the difference signal, divide the difference signal into the integrated difference signal, compare the normalized the th signal with a threshold value of the signal, when the threshold level is exceeded, a decision is made about the presence of a narcotic substance in the covering medium and the signal is converted into digital form, then the detected substance is scanned by moving the antenna unit from the detection boundary to the loss boundary at a speed determined by the light bar on the screen liquid crystal indicator, form on the screen of the liquid crystal indicator a radar image of the detected substance, which is used to judge the shape and size the detected drug substance.

The structural diagram of a device that implements the proposed method is presented in the drawing.

The device comprises serially connected pulse generator 3, the control input of which is connected to the first output of the synchronizer 4, the transmitter 2, the control input of which is connected to the second output of the synchronizer 4, and the transmitting antenna 1, the receiving antenna 5, the receiver 6, the control input of which is connected to the third output of the synchronizer 4, the drive 7, the control input of which is connected to the third output of the synchronizer 4, the delay line 11, the subtraction unit 12, the second input of which is connected to the output will accumulate Yelaya 7, integrator 13, division unit 14, the second input of which is connected to the output of integrator 13, comparison unit 16, the second input of which is connected to the fourth output of synchronizer 4 through the unit 15 for generating the reference voltage, and the analog-to-digital converter 17, to the first and second the output of which is connected to an audible warning device 18 and a liquid crystal indicator 19, respectively.

The proposed method is implemented as follows.

A device that implements the proposed method can operate in two modes. The first mode is based on remote excitation by an electromagnetic wave of magnetic resonance in the test substance with subsequent measurement of the response frequency. The second mode is based on ultra-wideband radar sensing of the alleged bookmark of a narcotic substance packed in a non-metallic shell, followed by analysis of the reflected signal.

In the first mode, pulses with a filling frequency W ₁ and (W ₁ -W) generated in a pulse generator 3 controlled by a synchronizer 4 are transmitted to a transmitter 2 and emitted by a transmitting antenna 1 in the direction of the test substance 8. The latter can be located, for example, on the body man under his clothes. The transmitting 1 and receiving 5 antennas are made, for example, in the form of horn antennas, which are equipped with polarizers.

The signal to the transmitting antenna 1 comes from a circular waveguide, to which, in turn, from the transmitter 2 are supplied two orthogonal (polarized) components, one at a frequency of W ₁ and the other at a frequency of (W ₁ -W), as a result of which the antenna emits 1 wave will be modulated by polarization with a magnetic resonance frequency W.

The test substance 8, irradiated by an electromagnetic wave containing a component at the magnetic resonance frequency W, is excited and, at the end of the irradiation pulse, emits a response signal at the same frequency. The response signal is received by the receiving antenna 5, containing four ferrite rods with a diameter of 8 mm and a length of 138 mm, while the rods are wound inductors containing 20 turns and connected in parallel. The operation of the device is controlled by the synchronizer 4.

The signal from the receiving antenna 5 is supplied to the receiver 6, which also receives the reference voltage from the output of the synchronizer 4, which locks the receiver 6 for the duration of the emission of pulses. From the output of the receiver 6, the signal enters the drive 7, where the signals are constantly accumulated, which allows to increase the distance from the receiving antenna 5 to the substance 8 by 2-3 times. The drive 7 also receives the reference voltage, providing synchronization of the accumulated pulses.

магнитного поля излучаемого электромагнитного сигнала содержит составляющую:In the case of modulation by polarization of the emitted signal with a frequency W equal to the frequency of the magnetic resonance of the substance, at a frequency of the emitted signal W ₁ >> W, the intensity vector

the magnetic field of the radiated electromagnetic signal contains a component:

на частоте W (Дудкин В.И., Пахомов Л.Н. Основы квантовой электроники. СПб-ГТУ, 2001). Поскольку частота W₁ может быть выбрана достаточно высокой W₁>>W, то в этом случае реализации передающая антенна 1 может быть осуществлена, например, с помощью техники антенн сверхвысоких частот (СВЧ), на которую модулированный по поляризации сигнал поступает из круглого волновода, на который в свою очередь поступают две линейно-поляризованные ортогональные волны

и

, частоты которых равны соответственно W₁ и (W₁-W).Test substance 8 will actively interact with the magnetic field

at frequency W (Dudkin V.I., Pakhomov L.N. Fundamentals of quantum electronics. St. Petersburg State Technical University, 2001). Since the frequency W ₁ can be selected sufficiently high W ₁ >> W, in this case, the implementation of the transmitting antenna 1 can be carried out, for example, using the technique of microwave antennas, to which the polarized modulated signal comes from a circular waveguide, which in turn receives two linearly polarized orthogonal waves

and

whose frequencies are equal respectively to W ₁ and (W ₁ -W).

The transition to the frequency of the exciting radiation in the microwave range allows you to provide a "far zone" for the emitted electromagnetic signal at a range of several tens of centimeters. As a result, at distances of the order of several meters from the emitter, the level of electromagnetic radiation is sufficient to excite resonance in the substance.

In the second mode, the role of the transmitter 2 is played by the shock excitation generator, which generates a probe pulsed ultra-wideband signal in the form of a single sinusoid period with an amplitude of 5 V and a duration of 1 ns, emitted by the transmitting antenna 1 in the direction of the proposed location of the narcotic substance 9, packed in a nonmetallic shell and located in a covering environment, for example, in the abdominal cavity of a person used to transport drugs, baggage, suitcase, diplomat, bag, etc.

In this case, the detection of narcotic substances in covering environments is carried out by the operator by moving the antenna unit 10, consisting of transmitting 1 and receiving 5 antennas and mounted on a rod, over the supposed place of laying the substance.

In this case, it is necessary to ensure that the antenna unit 10 moves parallel to the surface being examined at a fixed distance (no more than 10 cm from it) and that the entire area of the covering medium to be examined is examined.

An electromagnetic wave reflected from a subsurface narcotic substance acts on the receiving antenna 5. This antenna is also affected by the direct radiation of the transmitter 2 and the reflected signal from the air-covering medium interface. Moreover, large amplitudes will have a direct signal and a signal reflected from the interface between the air and the covering medium.

To eliminate the interfering radiation, the reference input of the receiver 6 is supplied with a reference voltage from the fourth output of the synchronizer 4. Moreover, the duration of the reference voltage can be made variable, which will lock the receiver 6 for a time determined by the duration of the reference voltage and eliminate the influence of direct radiation of the transmitting antenna 1 and signals, reflected from the boundary of the air - the covering medium and from layers of different depths, i.e. “vertical gating” is carried out (gating according to the depth of the narcotic substance in the covering medium). As a shelter, there can be a person’s abdominal cavity, luggage, container, suitcase, bag, diplomat, briefcase, etc.

"Vertical gating" provides a sequential view of the subsurface space from the interface between the air and the covering medium to layers of various depths.

“Horizontal gating” allows against the background of electromagnetic field variations not related to the electromagnetic wave reflected from the subsurface narcotic substance to reliably isolate subsurface narcotic substances in covering media. To exclude the influence of periodic and quasi-stationary variations of the Earth’s electromagnetic field, periodic measurements of the field strength and the operation of normalizing the difference signal of two successive measurements are carried out, i.e. integrate the difference signal, divide the difference signal into the integrated difference signal. The operation of comparing a normalized signal with a given threshold value allows you to decide on the presence or absence of a subsurface narcotic substance in a covering environment.

For this, the pulse generated in drive 7, which is the instantaneous value of the received periodic signal reflected from the subsurface narcotic substance, or the pulse due to variations in the electromagnetic field, is fed to the subtraction unit 12 directly and through the delay line 11. Moreover, at each observation point less than two consecutive measurements of these pulses. Then, the operation of subtracting two consecutive measurements is performed. For this, the pulse corresponding to the previous measurement is delayed by the delay line 11 until it is compared with the subsequent pulse in the subtraction unit 12. The operations of integrating the difference signal and dividing the difference signal by the integrated difference signal are performed in blocks 13 and 14. In block 16, the normalized signal is compared with the threshold value of the signal set by block 15. When the threshold level is exceeded, the signal is input to the analog-to-digital converter 17, where it is converted to digital form and fed to the audible annunciator 18 and a liquid crystal indicator 19. The frequency of vertical (lowercase) and horizontal (frame) scans can varied within certain limits. On the screen of the indicator 19 in real time, a flat luminance picture of subsurface targets is observed.

The appearance of an audio signal and a visual signal on the screen of the indicator 19 requires the operator to stop and indicates that an object is located in the detection area of the antenna unit 10, the origin of which should be established, and if necessary, its location and shape should be clarified.

To analyze the detected object, you should scan the object (moving the antenna unit 10 from the detection boundary to the loss boundary) at a speed determined by the light bar on the indicator screen 19. The Scan mode and the formation of a vertical cut of the covering medium with the object is carried out by switching from the Search mode by pressing the Scan button on the synchronizer 4. A few seconds after the signal is processed, the radar image of the object (narcotic substance) appears on the screen of the indicator 19, giving A statement on the shape and size of the object.

In some cases, an X-ray method and an appropriate stationary X-ray unit can be used to analyze the detected narcotic drug in a protective environment in detail.

Thus, the proposed method in comparison with the prototype and other technical solutions for a similar purpose provides not only remote search and detection of substances (drugs and explosives) using remote excitation by an electromagnetic wave of magnetic resonance in the substance with subsequent measurement of the response frequency, but also remote search and detection drugs packaged in a non-metallic membrane and located in covering environments, for example, in the abdominal cavity of a person used to transport the transportation of narcotic drugs, baggage, bags, suitcases, diplomats, etc., using ultra-wideband radar sensing of the alleged place of laying the narcotic substance. Thus, the functionality of the method is expanded.

Claims (1)

A method for remotely detecting a substance using remote excitation by an electromagnetic wave of magnetic resonance in a substance and then measuring a response frequency, by the presence of which it is concluded that the substance is present, while the exciting electromagnetic signal is emitted at a frequency much higher than the magnetic resonance frequency of the substance to be detected, and modulate the emitted exciting electromagnetic signal by polarization at the frequency of the magnetic resonance, and the response is recorded at the modulation frequency, characterized in that a sequence of radio pulses with a small number of periods of high-frequency oscillations in each of them is formed, up to one is irradiated with the probing ultra-wideband signal, the intended location of the narcotic substance packed in a nonmetallic shell and located in a covering medium, for example, in the abdominal cavity the person used to transport the narcotic drugs, baggage, suitcase, diplomat, bag, etc., take the reflected super wide a clear signal, it is sequentially accumulated, the antenna unit is moved parallel to the surface being examined at a fixed distance, and at least two consecutive measurements of the indicated reflected pulses are made at each observation point, for this the pulse corresponding to the previous measurement is delayed until it is compared with the next pulse , determine their difference, integrate the difference signal, divide the difference signal by the integrated difference signal, compare the normalized If the threshold value of the signal is exceeded, when the threshold level is exceeded, a decision is made about the presence of a narcotic substance in the covering medium and the signal is converted to digital form, then the detected substance is scanned by moving the antenna unit from the detection boundary to the loss boundary with the speed determined by the light bar on the screen liquid crystal indicator, form on the screen of the liquid crystal indicator a radar image of the detected narcotic substance, according to which t about the shape and size of the detected narcotic substance.