WO2006112750A1

WO2006112750A1 - Method for recording a local spatio-temporal irregularity of the universe physical characteristics and a system for carrying out said method

Info

Publication number: WO2006112750A1
Application number: PCT/RU2005/000453
Authority: WO
Inventors: Yury Alexeevich Baurov; Alexey Yurievich Baurov; Alexander Yurievich Baurov; Vladimir Alexandrovich Solodovnikov; Tristan Shaun Del; Sidney Sharp
Original assignee: Yury Alexeevich Baurov; Alexey Yurievich Baurov; Alexander Yurievich Baurov; Solodovnikov Vladimir Alexandr
Priority date: 2005-04-21
Filing date: 2005-09-06
Publication date: 2006-10-26
Also published as: RU2005111790A

Abstract

The invention relates to means for universe researches. The inventive method for recording a local spatio-temporal irregularity of the universe physical characteristics consists in simultaneously measuring a control parameter of at least two control signal sources, in measuring a current difference of the control parameter of said control signal sources, in determining the difference fluctuation of the control parameter of said sources, in recording the instants and actual co-ordinates of at least one control signal source in a selected frame of reference at the increased fluctuation of the control parameter difference when said fluctuation of the control parameter difference is greater than a statistic error caused by an error of measurement, wherein said actual co-ordinates define the spatial irregularity area of a physical space and a time interval between the beginning and the end of the increased fluctuation of the control parameter difference defines the time irregularity period thereof. The control signal sources are embodied in the form of stabilised high-frequency oscillation or impulse generators, gravitation field sensors or radioactive emission sources.

Description

METHOD FOR LOCAL SPATIAL REGISTRATION

AND TEMPORAL UNIFORMITY OF THE PHYSICAL CHARACTERISTICS OF THE UNIVERSE AND THE SYSTEM FOR ITS

IMPLEMENTATION

FIELD OF THE INVENTION The invention relates to research tools of the Universe.

BACKGROUND OF THE INVENTION

At present, it is considered proven that many processes on the Earth, in one way or another, are associated with the influence of cosmic factors on the Earth: the activity of the Sun, the relative positions of the planets of the Solar system, cosmic rays originating both within the Solar System and outside it, and t .d. Intensive research is underway to study gravitational fields and their influence on processes on Earth. These studies are related to the study of the impact on Earth of factors that fit into the well-known hypotheses of the development of the Universe.

Fundamentally, at the level of a qualitative model, most of the observations can be explained by the influence of known cosmic factors.

However, the conducted studies did not reveal an unambiguous connection between the known physical characteristics of the Universe and some processes taking place on Earth. A number of processes taking place on

The Earth can be explained, if we proceed from the assumption of the existence of spatial and temporal unevenness of the physical characteristics of the Universe. However, to date, no studies have been conducted to identify the structure of the spatial and temporal unevenness of the physical characteristics of the Universe, the physical nature of which is not known to us, but the existence of which can directly correlate with processes on Earth. The objective of the present invention is to develop a method and device for recording the local spatial and temporal unevenness of the physical characteristics of the Universe with the aim of studying the spatial and temporal scales of the unevenness of the physical characteristics of the Universe, using registration of changes in the characteristics of physical processes, the appearance of which is not related to the impact on the physical processes of known physical fields.

SUMMARY OF THE INVENTION The stated technical problem is solved by a method for recording the local spatial and temporal unevenness of the physical characteristics of the Universe, which consists, according to the invention, in that the control parameters measured by at least two sources of the control signal are measured at the same time, the current difference of the control parameters of the indicated sources of the control is measured signal, determine the fluctuation of the difference in the control parameters of these sources, record the moments in the belts and current coordinates of at least one control signal source in the selected coordinate system with increased fluctuation of the control parameter difference, when the fluctuation of the control parameter difference exceeds the statistical error associated with the measurement error, while the indicated current coordinates determine the area of spatial non-uniformity of physical space, and the time interval from the beginning to the end of the increased fluctuation of the difference in the control parameters determines the period of time vnomernosti physical space.

Preferably, at least two identical sensors of the control signal are used as control signal sources. Preferably, identical control sensors are placed in at least two spatially spaced local measurement zones.

Preferably, the zone of local unevenness is determined by the location of the sensor, which record the greatest fluctuation of the difference in the control parameters.

Preferably, when measuring increased fluctuations of the difference in the control parameters, the angular orientation of at least one of the sensors in the selected coordinate system is changed. In addition, the angular orientation of the sensor is additionally recorded at which the fluctuation of the difference in the control parameters is maximum.

In addition, at least in the area where one of the sensors is located, an inhomogeneous field of the magnetic field vector potential is additionally formed.

Preferably, the sensor in the area of the additional inhomogeneous field of the vector potential of the magnetic field is placed in the area with a minimum value of the magnetic field strength.

Preferably, stabilized generators of high-frequency electric pulses or oscillations, as well as gravitational field sensors, are used as sensors.

In addition, at least one pilot signal sensor and at least one mathematical model of the pilot signal sensor are used as sources of the control signal, and to determine the increased fluctuation of the control parameter, the current difference of the control parameter of the specified control sensor and control signal is measured parameter generated by the mathematical model of the sensor. Preferably, at least one radiation source and at least one mathematical model of the radiation source are used as a sensor.

In relation to the registration system of local spatial and temporal unevenness of the physical characteristics of the Universe, the problem is achieved by the fact that the claimed system contains at least two sources of the control signal, each of which produces its own value of the control parameter, a unit for comparing the current values of the control parameters, at least at least two sources of the control signal, which determines the current difference in the values of the control parameters, the computing unit determines the analysis and fluctuation of the current difference in the control parameters, providing the allocation of fluctuations in the current difference of the control parameters in excess of the statistical error associated with the measurement error, a unit for tracking the current temporal and spatial coordinates of the sources of the control signal and a unit for recording measurement results, which stores at least all measurement results with increased fluctuation of the current difference of the control parameters, while the sources of the control signal are connected to the input of the comparison of the current values of the control parameters, the comparator output current values of the control parameters and output unit monitoring current time and the spatial coordinates of the pilot signal sources are connected to the input of the computing unit, whose output is, in turn, is connected to block registration of measurement results.

Preferably, at least two identical sensors of the control signal are used as sources of the control signal, while identical sensors of the control signal are located, at least in two spatially separated local measurement zones.

It is also preferable to use stabilized generators of high-frequency electric pulses or oscillations as sensors.

It is preferable to additionally equip the recording system with at least one device for generating an inhomogeneous field of the vector potential of the magnetic field, while at least one of the sensors is located in the specified device in the region with the minimum value of the magnetic field strength.

It is preferable to additionally provide the registration system with a closed metal camera, while inside the camera there is a device for forming an inhomogeneous field of the vector potential of the magnetic field and at least two identical sensors, one of which is placed inside the device for forming the inhomogeneous field of the vector potential of the magnetic field.

In addition, gravity field sensors can be used as sensors.

Preferably, at least one pilot signal sensor and at least one mathematical model of the pilot signal sensor are used as sources of the control signal, while it is advisable to use at least one source of radioactive radiation and at least at least one mathematical model of a source of radioactive radiation. The basis of the invention is the assumption that the presence of

The universe of local temporal and spatial unevenness of its physical characteristics is reflected in the course of physical processes on Earth, leading to a deviation of the recorded experimental results from the calculated theoretical values, or causing mismatch measuring two sensors registering the same parameter. In accordance with this assumption, the control parameters recorded by at least two sources of the control signal are simultaneously measured, the current difference of the control parameters of the indicated sources of the control signal is measured, the fluctuation of the difference of the control parameters of the indicated sources is determined, the time instants and the current coordinates are recorded, at least one source of the control signal in the selected coordinate system with increased fluctuation of the difference in the control parameters when the fluctuation The difference in the control parameters exceeds the statistical error associated with the measurement error, while the indicated current coordinates determine the zone of spatial non-uniformity of the physical space, and the time interval from the beginning to the end of the increased fluctuation of the difference in the control parameters determines the period of temporary non-uniformity of the physical space. The presence of increased fluctuations in the difference in the control parameters of the two sensors, when the fluctuation in the difference in the control parameters exceeds the statistical error associated with the measurement error, indicates the actual presence of some other reason for the mismatch of the control parameters, and could potentially be associated with the presence of local spatial and temporal unevenness of physical characteristics The universe. The coordinates of the sensors determine the area of unevenness, and the time interval is the duration (registration period) of temporary unevenness. The intensity of the non-uniformity can be estimated by the level of fluctuation relative to its average value.

The use of at least two identical sensors of the control signal as sources of the control signal increases registration accuracy, since it eliminates errors associated with the features of the sensors themselves and allows you to fix the local spatial and temporal unevenness of the universe.

Placing identical control signal sensors in at least two spatially separated local measurement zones makes it possible to study the geometric scales of unevenness.

The zone of local non-uniformity is determined by the location of the sensor, for which the greatest fluctuation of the difference in the control parameters is recorded, since in the zone of this sensor there will be the greatest level of exposure to external cosmic factors.

Changing the angular orientation of at least one of the sensors in the selected coordinate system, which measure the increased fluctuation of the difference in the control parameters, makes it possible to study the anisotropy of the physical characteristics of the Universe in the direction and to relate the region of the occurrence of physical non-uniformity with a specific space object, for example, with the Sun, and possibly - and with other stars, in particular, registering the angular orientation of the sensor at which the fluctuation of the difference in the control parameters is maximum.

By forming, at least in the area where one of the sensors is located, the inhomogeneous field of the vector potential, additional data can be obtained on the physical foundations of the local spatial and temporal non-uniformity of the physical characteristics of the Universe, in particular, it is possible to study the anisotropy of the gradient field of the revealed non-uniformity. By placing the sensor in the zone of the additional inhomogeneous field of the vector potential in the region with the minimum magnetic field strength, the error associated with the effect of the magnetic field on the sensor is reduced, while maintaining a high level of the gradient of the vector potential field in the zone of the sensor. The use of stabilized generators of high-frequency electric pulses or oscillations as control signal sensors increases the accuracy of measurements, since the dependence of the characteristics of these generators on the external effects of known physical fields is well known.

The use of gravity field sensors as the control signal sensors provides increased measurement accuracy, since these sensors are one of the most high-precision devices for measuring the physical characteristics of the Universe. The method in which at least one pilot signal sensor and at least one mathematical model of the pilot signal sensor are used as sources of the control signal, wherein, to determine the increased fluctuation of the difference of the control parameters, the current difference of the control parameter of the specified control sensor is measured and the control parameter formed by the mathematical model of the sensor, makes it possible to study the temporal nature of the unevenness of physical characteristics in boundary region of the Universe, since the control signal generated by the mathematical model does not depend on any external influences. In this case, it is preferable to use at least one source of radioactive radiation as a sensor, since until now it was believed in physics that the half-life of a radioactive element does not depend on the known physical fields of the Earth and at least one mathematical model of the source of radiation describing the theoretical level of activity of a radiation source over time.

Accordingly, the elements of the claimed system for recording the local spatial and temporal unevenness of the physical characteristics of the Universe ensure the operations of the claimed method with solving specific elements of the system of the same technical problems as the corresponding operations of the method.

Equipping the system with a closed metal camera, while inside the camera there is a device for forming an inhomogeneous (magnetic) vector potential of the field and at least two identical sensors, one of which is placed inside the device for forming an inhomogeneous vector potential field in an area with a minimum magnetic field strength field, and the second - outside this device, but inside the camera, provides the creation of a local measurement zone in which the influence of the Earth’s magnetic field, electromagnetic field th, air convection, etc. it is practically absent and all fluctuations in the difference in the control parameters of the two sensors are associated only with cosmic factors, including the presence of physical fields freely penetrating the metal shell of the chamber. The technical result from the use of the invention is to expand the possibilities of studying the physical characteristics of the Universe by examining the qualitative picture of the causes that cause deviations in the operation of the recording sensors, which cannot be explained by known physical characteristics. BRIEF DESCRIPTION OF THE DRAWINGS

Figure l shows a general diagram of a system for recording the local spatial and temporal unevenness of the physical characteristics of the Universe; figure 2 presents a special case of the implementation of the claimed registration system using two stabilized generators of high-frequency oscillations; in Fig.Z - installation diagram with a shielding chamber; figure 4 presents the sensitive system of a quartz gravimeter used in another particular case of the implementation of the claimed registration system; 5 is a diagram of a registration system using a radiation sensor; 6 and 7 are examples experimental registration of increased fluctuations of the control parameter, confirming the presence of local spatial and temporal unevenness of the physical characteristics of the Universe.

BEST MODE FOR CARRYING OUT THE INVENTION In general, a system for recording local spatial and temporal non-uniformity of physical characteristics of the Universe, operating in accordance with the claimed method, includes at least two sources of control signal 1 and 2, while signals from these two sources 1 and 2 are control parameters for recording the local spatial and temporal unevenness of the physical characteristics of the Universe. Sources 1 and 2 are connected to the unit 3 for comparing the current values of the control parameters, in which the current difference in the values of the control parameters is determined. Block 3 is connected to the computational unit 4 for determining and analyzing fluctuations in the current difference of the control parameters, providing the allocation of fluctuations in the current difference of the control parameter in excess of the statistical error associated with the measurement error. An additional unit 5 is connected to the computing unit 4 for tracking the current temporal and spatial coordinates of each of the sources of the control signal, for example, sources 1 and 2. The output of the computing unit is connected to the unit 6 for recording measurement results, which stores at least all measurement results from increased fluctuation of the current difference of the control parameter. The system may also have a display 7 for visually displaying measurement results. The figure shows two control signal sources that are necessary for the system to work, but the system can work with a large number of control signal sources. A qualified specialist in the art should be it is clear that blocks 3, 4, 5, 6 and 7 in the system described above can exist as independent blocks, but can also be components of a computer, for example, a personal computer of any type. The system operates as follows. All control signal sources, or at least two control signal sources operate simultaneously. Each of the sources of the control signal gives its own value of the control parameter. In this case, these are the values of two control parameters. The measured values of the control parameters are received in block 3, where the current difference in the values of the control parameters is determined. The measured current difference is transmitted to computing unit 4, in which the current difference in the values of the control parameters is compared with previous measurements, the fluctuations of the current difference in the control parameters are determined and analyzed, and the fluctuations of the current difference in the control parameters are selected that exceed the statistical error associated with the measurement error. Simultaneously with the data being transmitted to the computing unit 4 from the unit 3, information from the unit 5 for tracking the current temporal and spatial coordinates of the control signal sources is supplied to it, which allows localizing in space and time regions with increased fluctuation values of the difference of the control parameters in order to use this information in the future analysis. The measurement results processed in the computing unit are transmitted to the registration unit 6, which stores at least all measurement results with increased fluctuation of the current difference in the control parameters. Other data may be transferred to the registration unit. The display 7 serves to quickly display the information requested from the computing unit 4 or from the registration unit 6. Figure 2 shows a special case of the implementation of the registration system of local spatial and temporal unevenness of the physical characteristics of the Universe using two identical signal sensors, which are used as two identical crystal oscillators (CVGs) of 8 and 9 high-frequency oscillations, generating in the nominal mode two almost identical in frequency of the output signal, which are the control parameters. The stability characteristics of the crystal oscillators is provided by connecting them to a single stabilized power source 10. Each of the crystal oscillators through its own frequency divider (Tp) 1 1 and 12 is connected to a synchronous phase detector (SFD) 13, which determines the difference in the values of the two control parameters as the angle of the frequency shift of one crystal oscillator relative to the other crystal oscillator with the accumulation of the current difference to the specified control values, for example, until a phase angle of 360 ° is reached. The frequency dividers 11 and 12 and the synchronous phase detector 13 form a block 14 comparing the current values of the control parameters. For further processing of the output signal of the synchronous phase detector, a shaper (Ф) of 15 standard output pulses is used, generated at the time when the angle of the phase difference of the oscillations reaches 360 °, and a personal computer (PC) 16. Tracking unit for the current temporal and spatial coordinates of the sources of control the signal and the unit for recording measurement results, which stores at least all measurement results with increased fluctuation of the current difference of the control parameters, are included in leaving the system as fragments of a personal computer 16, but it is possible to incorporate the indicated blocks into the system.

For a specialist it is clear that the particular circuit considered with a single stabilized power source is not the only one a possible option, and for a system with quartz generators spaced a considerable distance, autonomous stabilized power supplies are needed. The principles of transmitting the values of the measured control parameters over long distances with the reduction of the transmitted data to a unified reference system of measurement time are also obvious.

FIG. 3 shows a third embodiment of the invention using an additional inhomogeneous vector potential field, in particular an inhomogeneous vector magnetic field, and quartz resonators similar to those discussed in the previous example.

The experimental setup includes a closed thick-walled metal chamber 17, inside which two quartz oscillators 18 and 19 and a computing unit 20 for primary data processing are installed. Inside the camera, a device for generating an inhomogeneous magnetic field of the vector potential is mounted, which is a magnetic system 21 having permanent magnets 22 creating a magnetic field B with a magnetic induction level of up to 3500 G (0.35 T). The circles with a dot and with a cross indicate the direction of the vector potential of the magnetic field (a circle with a dot - the vector is directed at us, a circle with a cross - from us). Inside the chamber there is a pedestal 23, on which the first quartz oscillator 18 is located. The quartz oscillator is located in the region with the minimum magnetic field (in the device B under consideration it is approximately 1 G), but with a large gradient of the change in the vector potential of the magnetic field. The second crystal oscillator 19 is located outside the magnetic system and is a reference sensor, with the readings of which the readings of the first crystal oscillator 18 are compared. The whole system is set relative to the horizon plane. Chamber 17 protects quartz generators 18 and 19 from exposure to external electromagnetic fields, and also serves as a kind of damper for any convection flows. Outside the camera is a personal computer 24, which records the results of the experiment. Figure 4 shows another example implementation of the invention using an additional inhomogeneous field of the vector potential, in particular the inhomogeneous vector potential of the magnetic field.

In this example, gravity field sensors were used as sensors, in particular, “Single” quartz gravimeters with a “mg” test platinum load suspended on quartz torsion threads. The sensitive system of the quartz gravimeter “Single” was supplemented with a permanent magnet 25, set so that its vector potential field in the location of the platinum load “mg” was directed along the sensitivity axis of the gravimeter, which is collinear to the line of gravity. The sensitive element of the gravimeter are quartz threads 26 and 27. The entire system for processing the results of the experiment completely coincides with that described in the previous examples. Figure 5 shows another example implementation of the invention using radiation sensors as sensors.

In the protected container 28 are two sources of radioactive radiation 29 - "Csi ₃₇ " and 30 - "Co ₆₀ ". The decay frequency is recorded by scintillation detectors 31 with photomultipliers 32. The measurement results are transmitted to a computer 33, which incorporates a mathematical model 34 that describes the decay of Cs ₁₃₇ , and a mathematical model 35 that describes the decay of Co _60, and a unit for determining and analyzing the current difference in the control parameters, in this case the current the difference between the recorded values of the number of decays with their theoretical values corresponding to their mathematical models The measurement results are displayed on the external registration unit 36. The coordinates of the measurements are linked in the same way as in the first embodiment of the invention.

The following are the measurement results using the systems described above.

The measurements were carried out simultaneously using two “Single” quartz gravimeters, one of which was equipped with a magnetic system, as shown in Fig. 4. The measurement results are presented in Fig.6, which simultaneously shows the graphs of the displacement of the platinum load of both gravimeters. As can be seen from the graphs, both gravimeters showed exactly the same general nature of the change in the gravitational field. At the same time, four events “a”, “b”, “c” and “d” were recorded on the upper graph (gravimeter with magnet), associated with increased oscillations of the sensitive system of the gravimeter. Three of them - “a”, “c” and “d” were also recorded by a gravimeter without a magnet, and the displacement of the platinum load of both gravimeters can be considered coincident or correlating with each other. Event “b” is recorded only by a gravimeter with a magnet (with a platinum load displacement much higher than the load displacement corresponding to the base time shift curve) and not recorded by a gravimeter without a magnet. The observed difference did not find its explanation in the framework of the usual physical concepts, which gives reason to believe that a signal of an unknown nature is recorded. Comparison of event "b" with events recorded on the Sun showed the following: event "b" occurred on 06.06.2000 at 12 o’clock. 01 min and preceded by a powerful flash on the Sun, the beginning of which It was registered at 12 o’clock. 06 minutes TOFO same day. In both cases, Greenwich Mean Time, i.e. UTC

Thus, the recorded signal "b", most likely, is not electromagnetic in nature and refers to signals of a new nature, which may be associated with previously unknown spatial changes in the physical parameters of matter in the Universe.

Such signals are recorded quite regularly, and some of them are associated with some kind of processes on the Sun, however, the physics of the appearance of signals of this type did not find an exact explanation. A similar picture was observed when studying signals from

The Sun using two spatially identical quartz oscillators (the system shown in Fig. 2) with the measurement of fluctuations in the oscillation frequency difference of quartz oscillators, and in studies at an experimental setup with a closed thick-walled metal chamber (Fig. 3). Studies using this camera showed that when one of the crystal oscillators is placed in an inhomogeneous field of the vector potential (inhomogeneous magnetic field), an increased fluctuation of the frequency difference of the oscillations of the crystal oscillators is observed. The results obtained also cannot be explained within the framework of familiar physical concepts.

In studies using radioactive sources, regularly observed periods of increased activity of the sources — for example, bursts “e” of the γ-ray flux in FIG. 7, relative to the basic decay curve “Co ₆₀ ” (mathematical model of a radioactive source), which cannot be explained within habitual physical representations.

INDUSTRIAL APPLICABILITY

Thus, the conducted experiments confirm the presence of local spatial and temporal unevenness of physical characteristics of the Universe and the possibility of recording this unevenness with the help of hardware used in modern physical research. Regular registration of local non-uniformity confirms that we are dealing not with random phenomena, but with regular processes in the Universe. The experimental results confirm that, using the proposed method and registration system, it is possible to study the local spatial and temporal unevenness of the physical characteristics of the Universe, which will allow collecting enough experimental data to refine the physical characteristics of the Universe and develop appropriate theoretical models.

Claims

CLAIM

1. A method for recording the local spatial and temporal unevenness of the physical characteristics of the Universe, which consists in simultaneously measuring the control parameters recorded by at least two sources of the control signal, measuring the current difference in the control parameters of these sources of the control signal, and determining the fluctuation of the difference in the control parameters of these sources, record time points and current coordinates of at least one control signal source at an early coordinate system with an increased fluctuation of the difference in the control parameters, when the fluctuation of the difference in the control parameters exceeds the statistical error associated with the measurement error, while the indicated current coordinates determine the zone of spatial non-uniformity of the physical space, and the time interval from the beginning to the end of the increased fluctuation of the difference in the control parameters determines the duration temporary unevenness of physical space.

2. The registration method according to claim 1, characterized in that at least two identical sensors of the control signal are used as sources of the control signal.

3. The registration method according to claim 2, characterized in that the identical control signal sensors are placed in at least two spatially separated local measurement zones.

4. The registration method according to claim 3, characterized in that the zone of local non-uniformity is determined by the location of the sensor, for which the greatest fluctuation of the difference in the control parameters is recorded.

5. The registration method according to claim 3, characterized in that when measuring increased fluctuations, the differences in the control parameters are changed angular orientation of at least one of the sensors in the selected coordinate system.

6. The registration method according to claim 5, characterized in that the angular orientation of the sensor is additionally recorded at which the fluctuation of the difference in the control parameters is maximum.

7. The registration method according to claim 2, characterized in that, at least in the area where one of the sensors is located, an inhomogeneous field of the vector potential of the magnetic field is additionally formed.

8. The registration method according to claim 7, characterized in that in the zone of an additional inhomogeneous field of the vector potential of the magnetic field, the sensor is placed in the region with a minimum value of the magnetic field strength.

9. The registration method according to any one of claims 2 to 8, characterized in that stabilized high-frequency electric pulse generators are used as sensors.

10. The registration method according to any one of claims 2 to 8, characterized in that gravity field sensors are used as sensors.

11. The registration method according to claim 1, characterized in that at least one control signal sensor and at least one mathematical model of the control signal sensor are used as sources of the control signal, in order to determine an increased fluctuation of the difference in the control parameters measure the current difference of the control parameter of the specified sensor control signal and the control parameter generated by the mathematical model of the sensor.

12. The registration method according to claim 1, characterized in that at least one source of radioactive radiation and at least one mathematical model of the source of radioactive radiation are used as a sensor.

13. A system for recording the local spatial and temporal unevenness of the physical characteristics of the Universe, containing at least two sources of the control signal, each of which produces its own value of the control parameter, a unit for comparing the current values of the control parameters of at least two sources of the control signal, which provides determination of the current difference in the values of the control parameters, a computing unit for determining and analyzing fluctuations of the current difference in the control parameters, printing selection of fluctuations of the current difference in control parameters that exceeds the statistical error associated with the measurement error, a unit for tracking the current temporal and spatial coordinates of the sources of the control signal and a unit for recording measurement results, which stores all the measurement results of the current difference in the control parameters, while the sources of the control signal are connected to the input of the unit for comparing the current values of the control parameters, the output of the unit for comparing the current values of the control of parameters and the output, the tracking unit of the current temporal and spatial coordinates of the control signal sources is connected to the input of the computing unit, the output of which, in turn, is connected to the measurement results recording unit.

14. The system according to item 13, wherein at least two identical sensors of the control signal are used as sources of the control signal.

15. The system according to 14, characterized in that the identical control signal sensors are located in at least two spaced-apart local measurement zones.

16. The system of clause 15, wherein stabilized generators of high-frequency electrical pulses are used as said sensors.

17. The system according to clause 16, characterized in that it is additionally equipped with at least one device for generating an inhomogeneous field of vector potential, while at least one of the sensors is located in the specified device in the region with a minimum magnetic field strength fields.

18. The system according to 17, characterized in that it is additionally equipped with a closed metal camera, while inside the camera there is a device for forming an inhomogeneous field of vector potential and at least two identical sensors, one of which is placed inside the device for forming an inhomogeneous fields of vector potential.

19. The system of clause 15, wherein the sensors used are gravity field sensors.

20. The system according to p. 13, characterized in that at least one control signal sensor and at least one mathematical model of the control signal sensor are used as control signal sources.

21. The system according to claim 20, characterized in that at least one source of radioactive radiation and at least one mathematical model of the source of radioactive radiation are used as a sensor.