EA017369B1 - Method for detecting and testing subprocesses in complex wavefield of an object - Google Patents

Abstract

The invention relates to the equipment for analysis, primarily biological and medical analysis. The method of detecting subprocesses on conformity with sample models after passive recording of a signal comprises the realization of a number of recordings, which results in increase of the accuracy of the conformity assessment, as well as associated with this method the following methods of active testing of subprocesses identified, such as: 1) testing the identified hyperergic subprocess in the compensation mode; 2) testing the identified hyperergic subprocess in the resonance mode; 3) testing the influence of the identified hyperergic subprocess on other subprocesses via recording the signal of an object against the wave compensation of a selected subprocess; 4) testing the influence of the identified hypoergic subprocess on other subprocesses by recording the signal of an object against the resonance activation of an identified subprocess; 5) combining testing modes 3 and 4 and/or 4 and 7. Said testing methods provide higher accuracy of the analysis of the complex wavefield of an object.

Description

The invention relates to technical systems intended for applied research, mainly biological and medical, and reflects the research processes of material objects.

The closest analogue of the proposed method is the patent of Ukraine (IL 34389 A) A method for the diagnosis and correction of wave characteristics of the studied objects and a device for its implementation (S.M. Zakirov, I.V. Orzhelsky, bull. No. 1, 02/15/2001). This method consists in taking a signal that contains the wave characteristics of the object, and comparing them with the standards and differs in that the captured signal is digitized and a special mathematical apparatus is used for comparison with the standards. The main disadvantages of this method are the use of a one-time signal recording standard and a quasi-ordinal correspondence measurement scale for assessing compliance with a standard.

A method is proposed that includes a method for passively detecting spectrally dynamic (SD) subprocesses of the wave electromagnetic field of an object recorded through a passive electrode, carried out according to the SD correspondence to a previously recorded standard and is characterized in that a series of records is made with the aim of increasing the accuracy of conformity assessment with subsequent special the procedure for averaging results over a series, as well as several methods for actively testing the properties of detected subprocesses.

The essence of the proposed method consists, firstly, in the implementation of a series of CD-records of the wave signal of the object in order to increase the accuracy and scientific adequacy of assessments of compliance with the standard in the passive mode of identifying subprocesses and, secondly, in the additional use of several options for active testing to clarify the properties of the studied wave subprocesses of the object.

The scientific adequacy of assessment means the possibility of using mathematical and statistical methods for analyzing the data obtained. This feature is achieved in two stages. The first stage is associated with the transition from the quasi-ordinal to the ordinal scale of conformity assessment in each individual record of the signal. The second stage consists in the implementation of a series of signal records and the use of a special method of averaging over a series with subsequent normalization to 100%. The result is a quantitative assessment of compliance with higher accuracy and a simple interpretation of compliance (in percent compliance). The key action is the implementation of a series of records, which allows you to transfer the assessment of compliance with the standard from qualitative to quantitative and at the same time improve the accuracy of the assessment.

In addition to the task of identifying subprocesses corresponding to the standards in a complex wave field, it is fundamentally important to test the stability (stability) of the detected subprocesses, as well as to test their influence on other detected wave subprocesses. Testing as an active study of an object is a direct development of the passive identification of subprocesses, since it is performed on the basis of the latter. The totality of the method for identifying wave subprocesses and several methods for testing them solves the single task of analyzing complex wave fields and allows you to get a single technical result, which is to increase the efficiency of the research process (for example, diagnostic) of material objects.

The first test method is to determine the stability of the identified hyperergic (with relatively high energy) wave process, which reflects the corresponding material process (for example, inflammatory).

To do this, the dynamic spectrum of the standard is emitted through the active electrode to the test object in compensation mode, that is, using an inverted spectral-dynamic signal, and the feedback time to the parallel-recorded wave signal from the object records the compensation duration to a certain conditional level (for example, 10 times , i.e. up to 10% of the value of the original signal). The compensation duration recorded in this way reflects the level of stability of the test process. It is also possible to fix a relative decrease in signal at a fixed test duration.

The second testing method is to determine the stability of the detected hypoergic (with relatively low energy) wave process, which displays the corresponding material process (for example, degenerative).

To do this, the dynamic spectrum of the standard is emitted through the active electrode to the test object in resonance mode, that is, using a direct (non-inverted) spectral-dynamic signal, and the feedback from the object in parallel is recorded to record the duration of the resonant response when it decreases to a certain conditional level (for example, 10 times, that is, up to 10% of the value of the initial resonant response). It is also possible to fix a relative decrease in the resonance signal at a fixed test duration.

The third testing method is to determine the effect of the identified hyperergic wave subprocess on other wave subprocesses that are of interest in the context of object research (for example, diagnostic research).

For this, the dynamic spectrum of the corresponding standard is emitted through the active electrode to the test object in the compensation mode, and at the same time, the di

- 1 017369 namic spectrum of the tested object. In other words, passive recording of the wave signal from the object is carried out against the background of the compensatory testing signal from the selected standard. Then the result of passive recording of the wave signal of the object is analyzed according to claim 1 and find out which of the subprocesses of interest to the researcher and how the compensatory suppression of the tested subprocess affects.

The fourth testing method is to determine the effect of the identified hypoergic wave subprocess on other wave subprocesses of interest in the context of object research (for example, diagnostic research).

For this, the dynamic spectrum of the corresponding standard is emitted through the active electrode to the test object in resonance mode and at the same time the dynamic spectrum of the test object is recorded through the passive electrode. In other words, passive recording of the wave signal from the object is carried out against the background of the resonant testing signal from the selected standard. Then the result of passive recording of the wave signal of the object is analyzed according to claim 1 and find out which of the subprocesses are of interest to the researcher and how resonant activation of the tested subprocess affects.

The fifth method of testing is to simultaneously conduct testing according to paragraphs 3 and 6. This can significantly save time spent on research, and greatly simplifies the research procedure.

The sixth testing method is to simultaneously test according to paragraphs 4 and 7. This also leads to a significant reduction in study time and a significant simplification of the research procedure.

To implement the proposed method for all points of the invention, the Medical Spectral-Dynamic Complex (KMIS) is used according to the patent of the Russian Federation for utility model No. 6321 and a device for recording and compensating for spectral-dynamic processes and VI 88932 I1 A device for recording and correction of wave biological objects. Information about the KMDS is contained on the manufacturers' websites (\ ν \ ν \ ν.1 <ιη5θν and those ^^. Кткй.ки). KMSD is intended for spectral-dynamic studies in medicine, veterinary medicine and other fields.

Claims (9)

CLAIM 1. A method for identifying spectral-dynamic (SD) subprocesses of a wave electromagnetic field of biological objects, including recording the dynamic spectrum of an object through a passive electrode, establishing high-quality SD-correspondence to a pre-recorded standard, characterized in that a series of records is made for which the levels of CD-matching are recorded , translate the result into a quantitative form and carry out conformity assessment. 2. The method of testing the stability revealed by the method according to claim 1 of the SD subprocess, including radiation through the active electrode of the dynamic spectrum of the corresponding standard to the object, characterized in that the feedback time from the passive electrode determines the time of the return signal to reach a given level. 3. The method of testing the stability revealed by the method according to claim 1 of the SD subprocess, including radiation through the active electrode of the dynamic spectrum of the corresponding standard to the object, characterized in that the feedback from the passive electrode determines the relative change in the signal value at a fixed test time. 4. The method according to claim 2 or 3, characterized in that for testing the detected hyperergic SD-subprocess during radiation use the compensation mode. 5. The method according to claim 2 or 3, characterized in that the resonance mode is used to test the detected hypoergic SDsubprocess during radiation. 6. A method for testing the influence of the detected CD subprocess on other CD subprocesses, including radiation through the active electrode of the dynamic spectrum of the corresponding standard, simultaneous test recording through the passive electrode of the dynamic spectrum of the object, detection by the method according to claim 1 of CD subprocesses in the test recording and comparison with SD subprocesses identified by the method according to claim 1 for the initial recording of the dynamic spectrum of the object. 7. The method according to claim 6, characterized in that for testing the detected hyperergic SDsubprocess during radiation use the compensation mode. 8. The method according to claim 6, characterized in that for testing the detected hypoergic SDsubprocess during radiation using the resonance mode. 9. The method according to claim 1, characterized in that it includes the implementation of the testing methods according to claim 2 or 3 in combination with the methods according to claim 7 or 8. Eurasian Patent Organization, EAPO Russia, 109012, Moscow, Maly Cherkassky per., 2