RU2075060C1 - Process of detection of energy-informative action on tested object - Google Patents

Abstract

FIELD: study and analysis of materials by determination of their physical properties. SUBSTANCE: for authentic estimation of result of energy-informative action on tested object firstly energy-informative action is transferred from tested object to intermediate object (substance - information medium) present in liquid phase, then changes taking place in substance - information medium due to energy-informative action, namely, temperature behavior of spectral characteristics of absorption bands in infrared band of spectrum within range of temperature in which liquid phase of substance - information medium exists are studied. Presence of energy- informative action is established by disturbance of monotonous behavior of temperature dependence of spectral characteristics of absorption bands in infrared region of spectrum characteristic of object not subjected to energy-informative action. Information on state of substance - information medium and consequently on tested object was extracted from analysis of position of maximum of absorption band either by method of chords or by change of its half-width or peak intensity on specified frequency of absorption band of water. EFFECT: improved authenticity of estimation of result of energy-informative action on tested object. 5 cl, 5 dwg

Description

 The invention relates to the field of research and analysis of materials by determining their physical properties, for example using optical means using infrared rays, and can find application in any field of technology, medicine, biology, where it is necessary to detect energy-information effects on various objects.

 To date, a large amount of experimental material has been accumulated regarding the possibility of energy-information impact on various objects. The experimental results confirm the fact that between various biological objects an energy-informational exchange takes place, an essential role in which is played by water present in one form or another in living cells, blood, DNA molecules, protein, etc.

 It is also known that electromagnetic oscillations of low intensity have a significant effect on the vital activity of various organisms.

 Radiation directed to the area of human organs is used in the treatment of patients with various forms of diseases [1, 2, 3] In this case, the effect is carried out, in particular, by the hand of an operator emitting energy, which includes infrared radiation in the range of 8-14 microns, microwave radiation in the range of 8-30 cm and an alternating electric field with a frequency of up to 10 Hz.

 There are known facts of susceptibility to the energy-informational effects of alcohols, waxes, amber and even metals.

 The problem is that today there are no known methods that can reliably evaluate the results of energy-informational impact on various objects. Numerous unsuccessful attempts to register by physical methods the influence of information coding on objects, in particular water, indicate that the effects that are emerging are small and require precise and thorough measurements.

 A well-known technique that can be interpreted as a manifestation of the "memory" of water and ice when exposed to an alternating magnetic field [4] The method is based on measuring the dielectric loss tangent after treating water and ice with alternating fields of different frequencies and intensities.

 However, this method cannot be used for the purpose of establishing the energy-information impact, since it is focused only on the effect of a magnetic field. The method is limited by the range of objects of study (ice and water).

 A known method [5] of fixing the electromagnetic wave characteristics of the tested objects, according to which, as a result of the interaction of the tested object and the information carrier, the electromagnetic wave characteristics are transferred from the tested object to the carrier substance.

 The method is as follows.

 A substance, the information carrier about the wave characteristics of the test object, is poured into a metal container, it is mounted on a metal plate on which the test object, the wave characteristics of which must be removed, is placed. In the process of solidification, the information carrier under the influence of the electromagnetic field of the test object captures the specificity of its wave characteristics. Recording wave characteristics is carried out until the solidification of the substance of the information carrier. As the substance of the information carrier, chemically purified wax is used. The method was used during the etiological diagnosis of diseases.

 However, this method does not make it possible to reliably establish whether there was an energy-informational effect or not.

 Another method known [6], which is closest to the invention, is a method of preparing a substance that normalizes the body’s homeostasis.

 The methodology inherent in this method allows you to use it, if necessary, and to determine the energy-informational effect on the tested objects by using a microresonance circuit that contains spectral wave information of a known substance, in particular a drug, and then comparing the wave characteristics of the known substance as a reference and substances that received energy-informational effects regardless of the microresonance circuit.

 However, the known method is not sufficiently reliable, because and the result of selecting a microresonance circuit corresponding to drugs that are bioenergetically adequate to the identified pathology, and transferring the spectral wave information contained in the microresonance circuit to a substance that is chemically intact for the body, are analyzed based on the results of clinical studies in the treatment of diseases obtained in this way with a biologically active liquid, which It does not allow to clearly differentiate the result of the actual energy-informational impact.

 In addition, the method is limited to the range of tested objects, because It is used only for a substance subjected to pre-destructive treatment, distilled or boiled water.

 The aim of the invention is to develop a method that can reliably determine the presence of energy-informational impact on the tested objects, that is, objectively and differentially evaluate the changes that occur in objects due to energy-informational impact.

 In addition, the aim of the invention is to expand the range of tested objects by ensuring the possibility of its use not only for objects in a liquid state, but also in a solid state.

 This goal is achieved by the fact that in the method of detecting energy-informational effects on a test object by measuring its physical parameters and then evaluating them, the energy-informational effects are first transferred from the test object to a substance - a storage medium in the liquid phase, and then the substance is exposed to infrared radiation, in the absorption spectrum register the absorption band characteristic of the substance of the information carrier and determine the The spectral parameter of the absorption band for each temperature value that varies with an arbitrary interval in the range of existence of the liquid phase of the information carrier substance. The obtained temperature dependence is analyzed and in the event of a deviation of this dependence from the monotonic one, the presence of energy-informational influence is established.

 As the spectral parameter, the position of the maximum of the absorption band by the chord method can be determined.

 The half-width of the absorption band can also be determined as a spectral parameter.

 In addition, the peak intensity at a given frequency of the water absorption band can be determined as a spectral parameter.

 Water can be used as the substance of the information carrier.

 The implementation of this method was made possible as a result of numerous experiments conducted by the authors, which made it possible to establish that when the information coding of an object occurs, there is a violation of the monotonic behavior of the temperature dependence of the spectral characteristics of the absorption bands of objects in the infrared region of the spectrum. These nonmonotonic changes are absent in objects that are not subjected to coding. These changes significantly differ from each other with different coding, and also depend on the encoding object itself.

 In this invention, the energy-informational effect on the test object was recorded indirectly through an intermediate object - a substance onto which information about the tested object was transferred. In this case, the temperature behavior of the spectral characteristics of the absorption bands of the information carrier substance in the infrared region of the spectrum was studied and analyzed.

To carry out the transfer of information about the state of the test object to the substance of the information carrier can be in various ways, including the method [5]
The developed method guarantees a sufficiently high reliability of the result, because it is based on objectively obtained experimental data that determine the revealed pattern.

 The method can be used both for liquid objects (although in this case it is possible to conduct studies using the method described in the application for the invention "Method for identifying energy-informational effects on a liquid" by the same authors) and for objects in a solid state.

 In the study of water, the authors put forward the following working hypothesis.

 The observed low-frequency shift of the infrared bands with the participation of stretching vibration indicates the stabilization of the structure of water and the strengthening of the interaction between water molecules. The broadening of the water absorption band accompanying the low-frequency shift is associated with the resonant interaction of water molecules. According to the hypothesis, during energetic informational action, due to resonant action, the population of rotational and vibrational energy levels of water molecules changes, which leads to an increase in the degree of coherence of collective motion. The changes in the vibrational interaction taking place with the collective excitations of water, depending on temperature, determine the structure-forming and regulating role of water. For other fluids, similar hypotheses may be put forward.

In FIG. 1 shows the temperature dependence of the shift of the maximum absorption band ν ₂ + ν _{OH OH of} water,
and not subjected to energy-information impact,
b subjected to energy-informational exposure medorrinumom 50 ^x ;
in FIG. 2 shows the temperature dependence of the peak intensity at a frequency ν = 5160 cm ^-1 absorption bands ν ₂ + ν _{OH of} water,
and not subjected to energy-information impact,
b subjected to energy-informational exposure medorrinumom 50 ^x ;
in FIG. 3 shows the temperature dependence of the shift of the maximum absorption band ν ₂ + ν _{OH OH of} water,
and not subjected to energy information exposure;
b subjected to energy-informational exposure to an aqueous solution of an antibiotic;
in FIG. Figure 4 shows the temperature dependence of the change in the half-width of the absorption band ν ₂ + ν _{OH of} water,
and not subjected to energy-information impact,
b subjected to energy-informational exposure to an aqueous solution of an antibiotic;
in FIG. Figure 5 shows the temperature dependence of the peak intensity at a frequency ν = 5160 cm ⁻¹ of the absorption band of ν ₂ + ν _{OH OH of} water subjected to the energy-informational effect of an aqueous antibiotic solution.

 The method is as follows.

 The transfer of energy-informational effects from the test object to the carrier substance was carried out in two ways. In the first, a test tube with a test object was placed next to a test tube filled with a storage medium. The second used a method called by the authors "test tube in vitro". Two tubes of different diameters are placed one into the other. A test object is placed in a test tube of smaller diameter. A large-diameter test tube is filled with a substance as an information carrier.

In studies whose results are presented in FIG. 1 and FIG. 2, a solid ball of homeopathic substance, medorrinum 50 ^{x was} lowered into a tube, which was immersed in a larger tube filled with water. After 1 h, water from an external tube was placed in a cuvette of a spectral instrument. In studies whose results are presented in FIG. 3.4, 5, an antibiotic aqueous solution was poured into a 5 ml tube, which was placed next to a tube filled with water. After 1 h, water from a tube near the antibiotic was placed in a cuvette of a spectral instrument. Then the substance - the information carrier, on which the energy-informational effect is transferred, is additionally exposed to infrared radiation and its absorption spectrum is recorded. For a selected absorption band, the spectral characteristic value is determined at a given temperature value. Spectra were recorded on a diffraction instrument based on a monochromator SD-2 manufactured by the NIIF of St. Petersburg State University. The resolution of the device in the region of 1.9 μm is 0.5 cm ^-1 . The light source is a film projection lamp, and the receiver is an uncooled PbS-based photoresistance. Then, using the thermostat, the temperature of the object is successively increased at any arbitrarily set interval (the specific value of the interval is determined only by the required accuracy of the result) and the spectral characteristic of the absorption band is again determined with each new temperature value.

As a spectral parameter informing about the state of a substance
information carrier, you can determine the position of the maximum absorption band by the method of chords. Moreover, since the observed low-frequency shift of the absorption band of the substance of the information carrier is of interest, the decisive factor is the accuracy of determining the change in the position of the maximum, and not the accuracy of determining the absolute value of the frequency of the maximum. In this case, the systematic error of determination is removable and does not matter much, and it is the random error that is important. The magnitude of the random error in the experiments when finding the maximum absorption band does not exceed 2-3 cm ^-1 .

 As the spectral parameter, one can also determine the half-width of the absorption band or the peak intensity at a given frequency of the water absorption band. In the latter case, the frequency is selected from the considerations of the most pronounced manifestation of the effect of the energy-information effect and is selected experimentally. In the case of using aqueous solutions as a carrier material, measurements should also be taken on the absorption band of the ode. Spectral parameters are recorded in the temperature range at which the substance of the information carrier is in a liquid state. In this case, it is not necessary to study the entire temperature range: the effect can manifest itself in a rather narrow temperature range. In case of violation of the monotonous behavior of the obtained temperature dependence, they conclude that there is an energy-informational effect on the substance of the information carrier, and therefore on the test object.

Studies were carried out on the 5180 cm ^-1 water absorption band, which is the sum of the stretching and deformation vibrations of water molecules. The strip has a somewhat asymmetric smooth contour, which allows a fairly unambiguous interpretation of changes in the strip parameters. During testing, standard collapsible quartz cuvettes were used. The thickness of the water layer was 60 μm. Studies were carried out in the temperature range from 10 to 90 ^o With an interval of 3 ^o C.

 The presented results show a sharp violation of the monotonic behavior of the dependence in the studied temperature range in the case of energy-information exposure and the preservation of the monotonic nature of the dependence in the absence of exposure.

This is clearly seen from FIG. 1b, FIG. 2b changes in the spectral parameters of the absorption band ν ₂ + ν _{OH of} water subjected to energoinformational action with a 50 ^x modorrinum, as well as those shown in FIG. 3b, FIG. 4b, FIG. 5 changes in the spectral parameters of the absorption band of ν ₂ + ν _{OH OH of} water subjected to the energy-informational effect of an aqueous antibiotic solution. An ampicillin trihydrate aqueous solution was chosen as the test object.

Claims (5)

 1. A method for identifying energy-informational effects on a test object by measuring its physical parameters and then evaluating them, characterized in that they first transfer energy-informational effects from the test object to a substance - a storage medium in the liquid phase, then the substance is subjected to infrared radiation , the absorption band characteristic of the substance of the information carrier is recorded in the absorption spectrum, the spectral parameter is determined p absorption band for each temperature value, a variable with an arbitrary interval in the range of existence of the liquid phase substance information carrier, and a deviation obtained by monotonic temperature dependence establish the presence of energy exposure.  2. The method according to claim 1, characterized in that the position of the maximum absorption band according to the chord method is determined as the spectral parameter.  3. The method according to claim 1, characterized in that the half-width of the absorption band is determined as the spectral parameter.  4. The method according to p. 1, characterized in that the peak intensity at a given frequency of the absorption band of water is determined as the spectral parameter.  5. The method according to claim 1, characterized in that water is used as the substance of the information carrier.

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