RU2308734C1 - Method for remote detection of a substance - Google Patents

Abstract

FIELD: radio-technical tools which use magnetic resonance for finding and detecting primarily drugs and explosives, and also use polarization selection and phase analysis for finding and detecting drugs, packed in non-metallic cover.

SUBSTANCE: method for remote detection of a substance includes remote excitation of magnetic resonance in a substance by an electromagnetic wave and following measurement of response frequency, while exciting electromagnetic signal is emitted at frequency much greater compared to frequency of magnetic resonance of substance, and emitted excitation electromagnetic signal is modulated by polarization at frequency of magnetic resonance, and response is recorded at modulation frequency. Electromagnetic probing is performed by flat-polarized signal and signals are received with right and left circular polarization which are reflected from drug substance, while reflected signal with right circular polarization is gated on basis of time, proportional to depth of position of drug substance, and reflected signal with left circular polarization is transformed by frequency with usage of heterodyne voltage, voltage of intermediate frequency is selected, multiplied with reflected signal with right circular polarization, harmonic voltage is selected at stable frequency of heterodyne, phase shift is measured between reflected signals from right and left circular polarization at stable frequency of heterodyne, measured value of phase shift is compared to standard value and on basis of comparison result, decision is taken about presence of drug substance in hiding environment.

EFFECT: increased trustworthiness of detection and increased depth resolution when determining location of drugs.

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Description

The proposed method relates to physical measurements, namely to radio equipment using magnetic resonance to search and detect mainly drugs and explosives in the composition of the substances presented for research, as well as polarization selection and phase analysis 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 narcotic drugs, luggage, suitcases, diplomats, mkah and the like, and can be used at airports, customs terminals, checkpoints, parking, etc.

Known methods for remote detection of a substance (RF patents Nos. 2.128.832, 2.148.817, 2.150.105, 2.161.300, 2.165.104, 2.179.716, 2.185.614, 2.226.686, 2.244.942, 2.249.202; U.S. Patent Nos. 4,756.866, 5.986.455, 6.194.898, 6.392.408; UK Patents Nos. 2,159.626, 2.254.923, 2.289.344, 2.293.885; Grechishkin V.D. et al. Local NQR in solids, Uspekhi Fizicheskikh Nauk. 1993, v.163, No. 10, etc.).

Of the known methods closest to the proposed one is the "Method for the remote detection of substances" (RF patent No. 2.244.942, 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 polarization selection and phase analysis to search for and find drugs packaged in a nonmetallic 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, the presence of which makes a conclusion about the presence of this substance, 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 response, and the response is recorded at the modulation frequency, electromagnetic probing of the alleged site of the narcotic substance is carried out with a plane-polarized signal and reception of signals with right and left circular polarization reflected from the narcotic substance in the covering medium, while the reflected signal with right circular polarization is gated time, proportional to the depth of the narcotic substance, and the reflected signal with left circular polarization is often converted e using the local oscillator voltage, isolate the intermediate frequency voltage, multiply it with the reflected signal of the right circular polarization, isolate the harmonic voltage at the stable local oscillator frequency, measure the phase shift between the reflected signals with the right and left circular polarization at the stable local oscillator frequency, compare the measured value of the phase shift with the reference value and the result of the comparison, they decide on the presence of a narcotic substance in a shelter.

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 synthesizer 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 first receiving antenna 5, the first receiver 6, the control input of which is connected in series 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, and the registration unit 22, sequentially connected to the second receiving antenna at 13, a second receiver 14, the control input of which is connected to the third output of the synchronizer 4, a mixer 15, the second input of which is connected to the output of the local oscillator 16, an intermediate frequency amplifier 17, a multiplier 18, a narrow-band filter 19, a phase detector 20, the second input of which is connected to the output of the local oscillator 16, and the comparison unit 21, the output of which is connected to the second input of the registration unit 22, serially connected to the fourth output of the synchronizer 4, the time delay unit 11 and the key 12, the second input of which is connected to the output of the second receiver 6, and the output is connected to the second input of the multiplier 18.

The transmitting antenna 1, the receiving antennas 5 and 13 form the antenna unit 10. In addition, the device contains the test substance 8 and the narcotic substance 9, placed in a shelter. The transmitter 2, the receivers 6 and 14 are equipped with polarizers.

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 electromagnetic radar sensing by a plane-polarized wave of the alleged location of a drug substance packed in a nonmetallic shell and placed in a covering medium, with subsequent measurement of the phase shift between two reflected components, which generally have elliptical polarization with opposite directions of rotation of the electromagnetic field vector.

In the first mode, pulses with a filling frequency W ₁ and {W ₁ -W) generated in the pulse generator 3 are transmitted to the transmitter 2 and emitted by the transmitting antenna 1 in the direction of the test substance 8. The latter can be located, for example, on the human body under his clothes . Transmitting 1 and receiving 5, 13 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), resulting in an antenna emitted 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 gradually accumulate, which allows to increase the distance from the receiving antenna 5 to the test substance 8 in 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 test substance 8, when the frequency of the emitted signal is 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 chosen sufficiently high W ₁ ≫ W, in this case, the implementation of the transmitting antenna 1 can be implemented, for example, using the technique of microwave antennas, to which the modulated polarization 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 pulse generator 3 generates a probe signal

U ₁ (t) = V ₁ · Cos (W ₁ · t + φ ₁ ), 0≤t≤T ₁ ,

where V ₁ , W ₁ , φ ₁ , T ₁ - amplitude, carrier frequency, initial phase and signal (pulse) duration,

which goes to the input of the transmitter 2, where it acquires a flat polarization. The specified signal through the transmitting antenna 1 is emitted in the direction of the surface of the covering medium, under which the narcotic substance 9 can be.

Detection of narcotic substances in the environment is carried out by the operator by moving the antenna unit 10 above the proposed location of the narcotic substance 9. In this case, an electromagnetic field is created in the covering medium by electromagnetic sounding. When a probing signal reaches a narcotic substance, it partially reflects towards the surface of the covering medium.

When a plane-polarized electromagnetic wave is reflected from a narcotic substance 9, which is affected by the external magnetic field of the Earth, it is divided into two independent components, which in the general case have elliptical polarization with opposite directions of rotation of the electromagnetic field vector. At frequencies of the decimeter range, both components have circular polarization. Narcotic substance 9 has electrical parameters that are different from the covering medium (conductivity and permittivity).

Both waves are reflected and propagated at different speeds, as a result of which the phase relations between these waves change. This phenomenon is usually called the Faraday effect, due to which the reflected signal experiences the rotation of the plane of polarization. The angle of rotation of the plane of polarization, which is determined by different speeds of propagation and reflection of signals with right and left circular polarization from a narcotic substance, is found from the ratio:

δZ = 1/2 (φ _n -φ _l ),

where φ _p , φ _l are the phase delays of the reflected signals from the right (rotation of the plane of polarization clockwise) and left (rotation of the plane of polarization counterclockwise) circular polarization, respectively.

The reflected signal is captured by the receiving antennas 5 and 13. In this case, the receiving antenna 5 is susceptible only to the reflected signal with the right circular polarization, and the receiving antenna 13 is only sensitive to the reflected signal with the left circular polarization.

The output of the receivers 6 and 14 produces the following signals:

U _p (t) = V _p · Cos [(W ₁ ± ΔW) · t + φ _p ],

U _l (t) = V _l · Cos [(W ₁ ± ΔW) · t + φ _l ], 0≤t≤T ₁ ,

where the indices "p" and "l" refer respectively to signals with right and left circular polarization;

± ΔW - carrier frequency instability caused by incoherent reflection and other destabilizing factors.

The signal U _p (t) from the output of the receiver 6 through the key 12 is supplied to the first input of the multiplier 18. In order for the measured phase difference to correspond to the depth h of the narcotic substance 9, the multiplier 18 is time-gated using the key 12, to the control input of which gating pulses are received, formed by the block 11 time delay. The latter is controlled by the synchronizer 4. The time delay of the pulses is determined by the depth h of the occurrence of the narcotic substance 9 in the covering medium. When the depth changes, the delay time also changes.

The reflected signal U _l (t) from the output of the receiver 14 is fed to the first input of the mixer 15, the second input of which is the voltage of the local oscillator 16:

U _g (t) = V _g Cos (W _g t + φ _g ).

At the output of the mixer 15, voltages of combination frequencies are generated. Amplifier 17 is allocated voltage intermediate (differential) frequency:

U _pr (t) = V _pr · Cos [(W _ave ± ΔW) · t + φ _etc.] 0≤t≤T ₁

where V _CR = 1 / 2K ₁ · V _l · V _g ,

To ₁ - gear ratio of the mixer;

W _CR = W ₁ -W _g - intermediate frequency;

φ _ol = φ _l -φ _g ,

which is fed to the second input of the multiplier 18. At the output of the latter, a harmonic voltage is generated:

U ₂ (t) = V ₂ · Cos (W _g · t + φ _g + Δφ), 0≤t≤T ₁ ,

where V ₂ = 1 / 2K ₂ · V _p · V _ol ;

K ₂ - transfer coefficient of the multiplier;

Δφ = φ _p -f _l is the phase difference between the reflected signals with right and left circular polarization,

which is allocated by a narrow-band filter 19 and enters the first input of the phase detector 20, the second input of which is the local oscillator voltage U _g (t). The output of the latter forms a low-frequency voltage:

U _n (Δφ) = V _n CosΔφ,

where V _n = 1 / 2K ₃ · V ₂ · V _g ;

To ₃ - the transfer coefficient of the phase detector, proportional to the measured phase shift Δφ. This voltage is compared in block 21 of the comparison with the reference voltage.

U _e (Δφ _e ) = V _e CosΔφ _e ,

where Δφ _e is the unchanged phase shift obtained by probing the covering medium in the absence of narcotic substance 9.

The phase shift Δφ _e is determined by the frequency of the probing signal and the electrical parameters of the covering medium. This phase shift remains unchanged when probing the shelter in the absence of drugs.

If U _n (Δφ) ≈U _e (Δφ _e ), then in the block 21 of the comparison does not form a constant voltage.

When U _n (Δφ)> U _e (Δφ _e ), a constant voltage is generated in the comparison unit 21, which is supplied to the second input of the registration unit 22. Moreover, the fact of registration of this voltage indicates the presence of a narcotic substance in this covering environment.

Thus, the proposed method in comparison with the prototype and other technical solutions for a similar purpose provides the search and detection of narcotic substances 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, diplomats, bags, etc.

Moreover, the proposed method allows to increase the reliability of the search and detection and resolution in depth when determining the location of narcotic substances in covering environments. This is achieved through the use of polarization selection and the elimination of the ambiguity of phase measurements, which is ensured by the fact that phase measurements are carried out between the reflected signals with right and left circular polarization, and not between the probing and reflected signals. In this case, the phase shift between the reflected signals with right and left circular polarization is measured at a stable frequency W _{g of the} local oscillator. Therefore, the process of measuring the phase shift Δφ is invariant to instability of the carrier frequency of the reflected signal arising from incoherent reflection of the signal from the narcotic substance and other destabilizing factors, which improves the accuracy of measuring the phase shift Δφ and, consequently, the accuracy of determining the location of narcotic substances. Thus, the functionality of the method is expanded.

Claims (1)

A method for remote detection of 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, the exciting electromagnetic signal being 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 magnetic resonance frequency, and the response is recorded at the modulation rate, characterized in that the electromagnetic sounding of the alleged location of the narcotic substance by a plane-polarized signal and the reception of signals with right and left circular polarization reflected from the narcotic substance in the covering medium are carried out, while the reflected signal with right circular polarization is gated in time proportional to the depth of the narcotic substance, and the reflected signal with left circular polarization is converted in frequency using voltage heterodyne oscillations, isolate the intermediate frequency voltage, multiply it with the right circular polarization reflected signal, isolate the harmonic voltage at the stable local oscillator frequency, measure the phase shift between the right and left circular polarized reflected signals at the stable local oscillator frequency, compare the measured phase shift value with the reference value and based on the result of the comparison, they decide on the presence of a narcotic substance in a shelter.