RU2732545C1 - Method of geological survey of minerals - Google Patents

Abstract

FIELD: geology; remote probing of underlying surface.

SUBSTANCE: upward low-frequency radiation of quartz rocks is surveyed by a multichannel receiver mounted on an aerocopter with reference of measurement tracing on coordinates from on-board equipment of GLONASS consumers, each channel of which contains a specialized antenna circuit, self-oscillator in frequency-tightening mode, operational amplifier, electronic sampling key of measured value in time, frequency detector, analogue-to-digital converter, memory. Identification of the rock by the corresponding mineral is carried out by calculating functions of cross-correlation of the current signal with reference signals of the type of rocks from the pre-established database of standards. Synthesized measurement matrices are formed from discrete readings on the planned measurement paths. Contour on the images – bed boundaries of rock type – is selected using a software method.

EFFECT: efficiency, accessibility of inaccessible areas, high reliability.

1 cl, 5 dwg

Description

The invention relates to the field of remote monitoring of the underlying surface by aerospace means.

There are known geopathogenic zones of the Earth, the so-called places of power [see. Internet, Wikipedia, Anomalous Zones], in which unexplained phenomena occur.

There are many methods and means of monitoring objects by means of their remote sensing to receive their own radiation of objects or reflected from them electromagnetic field (solar flux).

Information signs of the natural radiation of the underlying surface, such as the power of upward radiation, its polarization, frequency range, are associated with mechanical stresses in the earth's crust and other anomalies: changes in soil resistivity, telluric current density, magnetic intensity. It is known [cf. Physical encyclopedic dictionary, ed. A.M. Prokhorov, ed. "Sov. Encyclopedia ”, Moscow, 1983, p. 827] that under mechanical stresses the medium becomes anisotropic, the value of anisotropy is proportional to mechanical stress.

Known "Method for detecting earthquake foci", Patent RU No. 2181495, 2002 - analog. In the analogous method, the self-radiation of the underlying surface is recorded, the recorded function of the electrical signal is converted into digital matrices | m × n | the counts of the dependence of the amplitude I (x, y) on the spatial coordinates are distinguished, using the methods of spatial differentiation, the contours in the image, characterized in that the intrinsic radiation is recorded in two mutually orthogonal planes in polarization, the resulting image matrix is formed from the pixel-by-pixel ratios of the signal amplitudes in two, mutually orthogonal in polarization, reception channels, the contours on the resulting image are selected, the function of the fractal dimension inside the selected contours is calculated, the earthquake source is recorded when the fractal dimension of the current contour section coincides with the reference one, or with deviations by no more than the threshold value.

The disadvantages of the analog are:

- the penetration depth of microwave radiation (analog) in the range of soil resistivity does not exceed 1 m, while for mineral exploration, the penetration depth must be several kilometers;

- for the reliability of the detection of minerals, it is necessary to record the ascending radiation that has passed through the entire thickness of the soil.

The closest analogue to the claimed technical solution is "Correlator of signals - earthquake precursors", Patent RU No. 2272306, 2006, G01V 9/00.

The device of the closest analogue contains two parallel measurement channels, spaced apart on a base, including an electrostatic field sensor installed in the first measurement channel, and a hydrogen concentration sensor in the air atmosphere, as a sensitive element of the second measurement channel, an optical radiation generator, a photodetector, an analog a digital converter, a storage buffer, a programmable measurement sampling circuit that synchronizes the operation of an analog-to-digital converter and a storage buffer connected to a computer, and the precursor signals are converted at the output of the measuring channels as a function of the dependence of the average current on time, and the degree of similarity of the two processes are estimated by the cross-correlation function, according to the dynamics of the envelope of which the parameters of the earthquake are predicted.

The disadvantages of the closest analogue are:

- impossibility of direct use due to the physical difference of the measured values;

- parameters are measured in an air atmosphere, while in the stated solution, the measured signal must pass through the rock mass containing minerals.

The problem solved by the claimed method is to explore the spectrum of signals of upward low-frequency radiation of quartz rocks and identify accompanying minerals by calculating the function of cross-correlation of the explored signal with a reference signal of a known rock.

The problem is solved by the fact that the method of geological prospecting for minerals includes measuring the ascending low-frequency radiation of quartz rocks containing accompanying minerals with a meter installed on the aircraft along the planned flight paths with reference to the registration registers of measurements by coordinates from the onboard equipment of the GLONASS system consumers, determining the frequency and spectrum of the received radiation by a multichannel radio receiver with several channels spaced across subbands by the interval ΔF of locking the frequency of the oscillator in the pull-in mode, each of which contains a specialized antenna circuit, an oscillator, an operational amplifier, an electronic key for sampling the measured value in time, a frequency detector, an analog-to-digital converter, a memory device, identification of the signal type for the corresponding mineral by calculating the cross-correlation function of the recorded signal with the corresponding reference signal from the rock type, f Formation of the resulting matrix of measurements of the explored signal from discrete samples, highlighting the contours of the boundaries of occurrence of the type of rocks on the synthesized image.

The invention is illustrated by drawings, where:

fig. 1 - discrete readings of the ascending low-frequency radiation of the type of rocks a) vein quartz, b) aggregates of granular quartz;

fig. 2 - interval of the channel subband (ΔF) corresponding to the capture band of the oscillator;

fig. 3 - functions of cross-correlation of the explored signal with the reference signals of the type of rocks c) vein quartz, d) aggregates of granular quartz, e) fine-grained quartz of a solid mass;

fig. 4 - contour map of the explored field;

fig. 5 is a functional diagram of a device that implements the method.

The technical essence of the claimed technical solution is as follows.

One of the most common rock-forming minerals is quartz (SiO ₃ ) and its modification - granite (translated from Italian - granular) [see, for example, the Soviet Encyclopedic Dictionary, ed. AM Prokhorov, p. 570 Quartz, p. 338 Granite, ed. Sov. Encyclopedia, 1989] Quartz exists in several structural forms: grains, granular crystals, aggregates, vein quartz, veins and solid masses. Vein quartz is in the greatest geological relationship with almost all minerals, especially with gold (quartz sands), silica contains olivine, pyrope, platinum, iridium, titanium ores, as well as diamonds (kimberlite pipes), rubies, etc. are often found in placers.

From an electrical point of view, quartz is a piezoelectric, with mechanical stresses on its opposite faces, charges of the opposite sign appear, the magnitude of which is proportional to the mechanical stresses [see, for example, Handbook of Electronics, Volume 2, ed. A.A. Kulikovsky, ed. Energia, M., 1968, p. 43, Quartz resonators]

In anomalous zones of tectonic stresses, the density of electric charges changes due to seismic background waves and tidal waves. The quartz veins become emitters of low frequency upward radiation.

The greater the mechanical stress, the greater the anisotropy of the rocks [see, A.M. Prokhorov, Physical Encyclopedic Dictionary, ed. Sov. Encyclopedia, 1983, p. 227]. The anisotropy of rocks is proportional to the power and polarization of the upward low-frequency radiation. The radiation frequency depends on the thickness of the formation and the structure of the quartz grains. Abnormal changes in the electrical parameters of the lithosphere, such as the density of telluric currents, the specific electrical conductivity of rocks, affect the parameters of their own ascending radiation. In accordance with the approximate Leontovich boundary conditions, the penetration depth (δ) of the electromagnetic field into the substance is determined from the relation:

ƒ - frequency of the electromagnetic field, Hz;

μ is the magnetic permeability of the rock;

g - rock conductivity Ohm⋅m ³

Based on the principle of reciprocity [cf. Drabkin A.L., Zuzenko V.L. "Antenna-feeder devices", M., Owls. radio, 1964, pp. 136 ... 137, Principle of reciprocity] the characteristics of the electric circuit during emission (transmission) are identical to the characteristics of the circuit during reception. From the principle of reciprocity, the depth of the radiating rock stratum can be calculated. The depth of the rocks (kimberlite pipes) is of the order of several km, the specific conductivity (marble, granite, quartz g ≈ 5⋅10 ¹² Ohm⋅m ³ ). The calculated frequency of natural radiation, depending on the structural conglomerates of quartz, is in the range from hundreds of Hz to several kHz.

где L, C - индуктивность и емкость контура. При килогерцовой частоте восходящего излучения, параметры контура должны соответствовать

Максимальная емкость конденсатора на основе сегнетоэлектриков (BaTiO₃) достигает ≈10^-4 (Ф). Индуктивность соленоида L(Гн) рассчитывают из соотношения

где μ - магнитная проницаемость сердечника (типа пермаллой) может достигать ~10⁴,

- длина сердечника, S - площадь сечения сердечника, n - количество витков. При количестве витков несколько сотен, длина - несколько см и сечении 0,1 м², требуемые параметры антенного контура могут быть реализованы на существующей технической базе.Radio intelligence of signals is carried out by means of a multichannel receiver [see, for example, S.A. Vakin, L.N. Shustov “Fundamentals of radio countermeasures and electronic intelligence, ed. Sov. radio, M., 1968, p. 410, fig. 10.21]. The entire range of the surveyed frequencies is divided into several subbands (reception channels) with a tracking band ΔF in each equal to the capture band of the i-th oscillator, as illustrated in Fig. 2. Instead of a local oscillator in an analogue, an auto-oscillator is used in a realized receiver, the frequency of which is synchronized by an external EMF induced in the antenna circuit. As a result of this mode, the oscillator signal, modulated by the upstream spectrum, turns out to be frequency modulated. The modulating function of the upward radiation is isolated by a frequency detector. The next problem is the creation of an antenna circuit for receiving low-frequency upward radiation. It is known [see, for example, A.L. Drabkin, V.L. Zuzenko "Antenna-feeder devices", Owls. radio, M., 1964, pp. 142-143, 256-258, 268], that for effective reception (radiation), the geometric length of the antenna should be commensurate with the wavelength (about λ2… λ / 6). The natural resonance frequency of the antenna circuit is determined by the ratio

where L, C - inductance and capacitance of the circuit. At the kilohertz frequency of the upward radiation, the parameters of the circuit must correspond

The maximum capacity of a capacitor based on ferroelectrics (BaTiO ₃ ) reaches ≈10 ^-4 (F). The solenoid inductance L (H) is calculated from the ratio

where μ is the magnetic permeability of the core (such as permalloy) can reach ~ 10 ⁴ ,

is the length of the core, S is the cross-sectional area of the core, n is the number of turns. If the number of turns is several hundred, the length is several cm and the cross-section is 0.1 m ² , the required parameters of the antenna circuit can be implemented on the existing technical base.

In addition to exploring the spectrum of signals, the meter allows you to identify the type of rock. The main method for identifying objects is comparison with a standard. The mathematical procedure for comparing the similarity of two functions is the calculation of the cross-correlation of their signals [see, for example, VM Zaezdny, "Fundamentals of calculations in statistical radio engineering", Svyaz-izdat, Moscow, 1969, pp. 92-95].

With the modern development of computer technology, the methods of correlation analysis are easily implemented by special mathematical programs for personal computers. Recorded signals are pre-converted from analog to digital by means of an ADC. The text of the program for calculating the cross-correlation function.

The calculation result is illustrated by the graphs (c, d, e) of Fig. 3. The selectable parameter of the cross-correlation function B (ƒ ₁ , ƒ ₂ ) is the correlation interval (width of the function) at the level of 0.1 of its maximum value. For a rapidly fluctuating process, the function has a sharp shape. Therefore, the graph of FIG. 3c) can be identified as a vein quartz signal, the correlation interval Δτ is of the order of μs. The graph in Fig. 3d) has a correlation interval of the order of tens of μs and can be identified as a section of granular quartz aggregates. The graph in Fig. 3 e) with a correlation interval of the order of a fraction of a second, can be identified as a section of fine-grained quartz of a solid mass.

An example of the implementation of the method.

The claimed method can be implemented as shown in FIG. 5. The functional diagram contains an aerocopter 1 (an unmanned aerial vehicle with an upward low-frequency radiation meter 2 installed on board). Trace frame-by-frame shooting of the planned reconnaissance section is carried out from the onboard control complex (BCC) 3 via the command control radio line 4 of the ground control complex 5 with simultaneous binding of the measurement registers by coordinates from the onboard equipment of consumers 6 of the GLONASS global space positioning system.

Meter 2 is made according to the scheme of a multichannel reconnaissance radio receiver, each of the N channels of which is spaced across the range by the band ΔF of signal capture by the corresponding autogenerator and is a series-connected elements: a specialized antenna circuit 7, an autogenerator 8, an operational amplifier 9, an electronic switch 10, a frequency detector 11 , analog-to-digital converter 12, buffer memory 13. Synchronization of the operation of the elements of the meter 2 is carried out by means of a programmable sample of measurements 14, into which the telecommunication program from the BKU 3 is inserted. Frame-by-frame sampling of measurements in time in each channel is realized by means of an electronic key 10, made according to the scheme [cm. "Handbook of radio electronic devices" ed. A.A. Kulikovsky, ed. Energy, M., 1978, p. 33, Electronic keys].

After the landing of the carrier 1, the measurement arrays are pumped to the data storage server 15 and, through the input device 16, are transferred to the thematic processing center 17. The processing of the registered information arrays is carried out on the means of the automated center 17.

The identification of the explored rock areas is carried out by calculating the correlation functions of the explored (current) signal with the reference signal of the type of rocks previously placed in the database 18 by means of the correlator 19. The results obtained are displayed on the display 20.

Then, the explored territories are visualized with the binding of the regions to geographic coordinates. Preliminarily, programs of the specialized software MATH CAD are written into the random access memory of the center processor. Then, frames of synthesized matrices are formed from pixel-by-pixel values of discrete samples in the memory of each channel for the corresponding coordinate points [see, for example, Vectorization of matrix elements. "Specialized software MATH CAD 7.0" PLVS ed. 4th stereotyped, M ,, Inform. Ed. "Owl" 2000, pp. 50-68]. The contours on the field of the synthesized matrices are separated by software processing, as illustrated by the figure in Fig. 4.

The method can be implemented on the existing technical basis. The effectiveness of the method is characterized by documentation, in the form of contour maps of explored areas, the spatial reach of hard-to-reach territories, maximum reliability of exploration due to the correlation analysis of signals.

Claims (1)

A method for geological prospecting for minerals, including measuring the ascending low-frequency radiation of quartz rocks containing accompanying minerals, with a meter installed on the aerocopter along the planned flight paths with reference to the measurement registries by coordinates from the onboard equipment of the GLONASS system consumers; determination of the frequency and spectrum of the received radiation by a multichannel radio receiver with several channels spaced across subbands by the interval ΔF of locking the frequency of the oscillator in the pull-in mode, each of which contains a specialized antenna circuit, an oscillator, an operational amplifier, an electronic key for sampling the measured value in time, a frequency detector, analog-to-digital converter, storage device; identifying the signal type for the corresponding mineral by calculating the cross-correlation function of the recorded signal with the corresponding reference signal from the rock type; formation of the resulting measurement matrix of the explored signal from discrete samples; highlighting the contours of the boundaries of the rock type on the synthesized image.

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