RU2153844C2 - Method and device for examination of state of bioobject - Google Patents

Abstract

FIELD: biophysics, experimental and clinical medicine, applicable for diagnosis and correction of organism pathologic states. SUBSTANCE: method consists in detection of non-heat conducting field and comparison of it with a standard one in detection use is made of its natural coherent oscillations characterizing the endogenous and exogenetic processes occurring in the biological system in the "norm" and "pathology" in the all levels of organization of the biological medium in the continuous range of resonance frequencies generated at the respective levels of organization with a subsequent creation of static and dynamic images of the object, both on the whole and in layers ay the respective level of biological organization in spatial and time conditions; and genetic background of the "norm" and relation of the background of the "functional" and "pathologic" significant anomalies with it are determined; after that the level of biological organization, at which the anomaly being examined is developing, is fixed referring to the scale for taking the decisions. The device for examination of state of the bioobject has a sensor unit consisting of sensors, signal generator, information pick-off control device, second-level computer, upper-level computer network, АРМ and medical specialists and АРМ of maintenance and diagnosis; the sensor unit is made in the form of a cylindrical chamber with additionally introduced arranged in layers and series-connected analog memory elements, amplification and analog-to-digital conversion elements with an intellectual system of preliminary processing of signals, digital memory elements, primary- level supercomputer, commutators with formation of primary parallel information channels connected to the respective sensors organized in a two-dimensional matrix continuously in a cylindrical shape, in addition it has АРМ for receiving experimental data, АРМ for data processing and compression and АРМ of data base administrator connected in the respective way. EFFECT: enhanced quality of estimate of state of bioobject under examination and expanded functional capabilities, enhanced reliability. 4 cl, 9 dwg

Description

 The invention relates to the field of biophysics, experimental and clinical medicine and can be used in the diagnosis and correction of pathological conditions of the body.

 A medical system for studying the state of a biological object, both of the type of topographic analysis device and of the method of working with it, is known, containing a radiation source, a matrix of sensors for receiving radiation after it passes through the studied area, an information collection device, a matrix processor for processing "n" -bit digital values and a device for displaying information processed by the processor in the image memory [1].

 This device cannot provide the simultaneous reception of information from a variety of sensors that record the changes in the electromagnetic field of the body under study.

 The aim of the invention is to improve the qualitative assessments of the state of the biological research object and expand the functionality of the method by registering in a passive manner, i.e. without distorting the impact on the object, the electromagnetic field emitted-absorbed from all levels of the biological organization, as well as the creation of a device that implements the inventive method of research within the framework of optimal technical and metrological characteristics, allowing to provide a sufficient level of information and reliability for a reliable analytical process.

 This goal is achieved by the fact that in the method of studying the state of a bioobject, including recording a non-thermal field and comparing it with a reference field of a bioobject, the object is represented as a multilayer closed sphere such as an electromagnetic "nested doll", where each layer is identified with the corresponding level of organization of the biological system and internal its state according to the type of resonant interaction, and which in the “norm” is represented as the state of the electromagnetic field of broadband and amplitude-stationary, about bounded by a frequency above, and in a “functional” state and in a “pathology” - in the form of a narrow-band amplitude-nonstationary type of radiation-absorption, in which a non-thermal coherent energy interaction takes place between the layers in the form of bioenergy information exchange, and its own coherent electromagnetic oscillations characterizing endogenous and exogenous processes, simultaneously competing and occurring in the biological system in the “normal” and “pathology” at all levels organization of the biological system in a continuous range of resonant frequencies generated at the appropriate levels of organization, with the subsequent formation of a static and dynamic image of the object as a whole, and in layers at the appropriate level of biological organization in spatial and temporal mode by means of multi-channel parallel processing of the information flow, and determine genetically determined background of the "norm" and the correlation with it of the background of "functional" and "pathological" significant anomalies, and after comparing Nia with the reference field is fixed at what level of biological organization develops investigated anomaly.

 In the device for studying the state of a biological object, which contains a sensor unit consisting of sensors, a signal generator and a device for controlling information retrieval, a second-level computer and a top-level computer network with an expert system, automated workstations (AWS) of medical specialists and an automated workstation (AWS) maintenance and diagnostics, the first input / output of the second-level computer is connected to the first input / output of the upper-level computer network, the second input / output of which is connected to the input through the trunk m / outputs of the workstation of medical specialists, the input / output of the workstation of maintenance and diagnostics through the highway is connected to the second input / output of a second-level computer, the sensor unit is made in the form of a cylindrical chamber, the dimensions of which are not less than the dimensions of the bioobject, into which layer-wise arranged and sequential interconnected elements of analog memory, amplifiers and analog-to-digital converters with an intelligent signal preprocessing system, elements of digital memory, primary supercomputers level, switches, the corresponding inputs / outputs of which are connected to the first and second input / output of the information management device, the third input / output of which is connected to the third input / output of a second-level computer, the fourth input-output of which is connected to one of the switches with their formation parallel information channels, which are connected to the corresponding sensors and organized into a two-dimensional matrix, rolled up continuously into a cylindrical shape, and the device additionally contains an automated workstation for obtaining an experiment data, workstation for processing and compressing information connected via a highway to the second input / output of a second-level computer, and a database administrator's workstation connected by input / output through a highway to the second input / output of a top-level computer network, the rows in the two-dimensional matrix of the sensor block consist from sequentially interconnected elements of analog memory, amplifiers, ADCs with an intelligent signal pre-processing system, elements of digital memory, primary level supercomputers and form information a channel, while the first inputs of the analog memory elements are connected to the corresponding sensors, the supercomputer outputs are connected to the first switch through the first keys, and the columns consist of a layer-by-layer serial connection of the indicated elements of the information channel, the second inputs of which are connected to the outputs of the corresponding second keys, which have their inputs / the outputs are connected to the second switch, an additional spherical prefix to the camera of the sensor unit is also made, made of similar circuit elements and lowered like a main cylindrical chamber, closing it from the head.

 According to the information available to the authors, the set of essential features characterizing the essence of the claimed invention is unknown from the prior art, a comparative analysis with the prototype showed that the claimed method and device are distinguished by the presence of a new set of actions, the order of their execution in time and the presence of new elements in conjunction, which allows to conclude that the invention meets the criterion of "Novelty."

 According to the authors, the essence of the claimed method and device does not follow explicitly from a known level (technique) of knowledge for a specialist, since the above effect on the obtained technical result is not revealed from it (level) - a new property of the object, a set of features that distinguish the claimed invention from prototype, which allows us to conclude that it meets the criterion of "Inventive step".

 The set of essential features characterizing the essence of the invention, in principle, can be repeatedly used in organizing studies of the state of the human body during clinical and dispensary examinations to obtain an answer about the presence of deviations and determine the level of development of the studied anomaly (pathology), which determine the achievement of the goal in the form to improve the quality of assessing the state of the investigated biological object and expand the functionality of the method with the reproduction of a single mennoy picture of the state of all organs and functional systems without distortion by eliminating interference on the intrinsic radiation of biological systems that can be concluded according to the invention, the criterion of "industrial applicability".

 The proposed method for studying the state of a bioobject includes registering a non-thermal field of the patient and comparing the obtained data with the reference ones, while the studied object is presented in the form of a multilayer closed sphere such as an electromagnetic "nested doll", each layer of which can be identified with the corresponding level of the entire biological system and / or one of of its states according to the type of resonant interaction, each of the layers in the “normal” state is represented as a fairly broadband amplitude-stationary state I, limited by the resonant frequency from above, and in the functional state and in the pathology, in the form of a rather narrow-band amplitude-nonstationary type of radiation-absorption, in which coherent non-thermal energy interaction takes place between the layers in the form of bioenergy information exchange, using its own coherent endogenous and exogenous electromagnetic field (KEEEMP), characterizing the processes occurring with the biological system at all levels of its organization, in continuous Range of resonance frequencies generated at the respective levels of the organization on the basis of a multichannel parallel processing which creates static and dynamic images to a computer (display object) on the whole layers of levels of biological organization. In accordance with the selected research levels, a genetically determined background of the norm and, in relation to it, the background of functional and pathologically significant anomalies are determined at a specific level of biological organization in spatial and temporal modes, after which the level of development of the anomaly is recorded on a decision scale.

 In FIG. 1 presents diagnostic parametric functions in terms of the proposed method.

 In FIG. 2 presents a decision scale for the research method.

 In FIG. 3 presents an example of a specific medical manipulation for the operational control of therapeutic effects on equipment that implements the method.

 In FIG. 4 depicts examples of CEEEMP of isographic representations of lesions.

 In FIG. 5 shows a device for studying a biological object.

 In FIG. 6 shows an embodiment of a scanning unit.

 In FIG. 7 is a functional diagram of a scan unit 1.

 In FIG. 8 shows an example implementation of the AWP block diagram.

 In FIG. 9 is a diagram of a device for managing information retrieval.

A device for studying the state of a bioobject contains a sensor unit 1, consisting of layer A of sensors 4 of an electromagnetic field, a signal generator 2 and a device 3 for controlling information readout, second-level computers 11, a top-level computer network 15 with an expert system, automated workstations 16 (AWS) medical specialists, an automated workstation 12 maintenance and diagnostics, the fourth input / output of the first computer 11 is connected to the first input / output of the network 15 of the upper level computer, the second input / output of which is connected Through the highway 19 to the inputs / outputs of the AWP 16 of medical specialists, the sensor unit 1 is made in the form of a cylindrical chamber, the dimensions of which are not less than the dimensions of the biological object as a whole in the spatial field of study, into which layer B of analogue memory elements 5 are additionally inserted, layer C of amplification and analog-to-digital conversion elements 6 with an intelligent signal preprocessing system, layer D of digital memory elements 7, a layer of supercomputers 8 of the primary level, two Xx switches 9 and a layer th K Y-y switches 10, elements connected in series with each other with the formation of primary parallel information channels connected to sensors 4 and organized in a two-dimensional matrix, rolled up continuously into a cylindrical shape, it contains AWP 13 for obtaining experimental data, AWP 14 for processing and compression images, automated workplace 17 of the database administrator, control inputs / outputs of the switches 9 through keys K _x connected to the second inputs of the sensors 4 and elements 5, 6, 7, 8 of the information channel, channel inputs / outputs of the switch 10 are connected to the inputs / outputs of the keys K _y , the inputs of which are connected to the outputs of the supercomputer 8 of the primary level, the second inputs / outputs of the switches 9 and 10 are connected to the first and third inputs of the information collection control devices 3, the second inputs / outputs of which are connected to the third input / output of a second-level computer 11, the first and second inputs / outputs of which are connected to the third inputs / outputs of the switches 10, the fourth input / output of a second-level computer 11 is connected to the first input / output of a higher-level computer network 15 with an expert system, the second input / output which through the highway 19 is connected to the inputs / outputs of the automated workplace 17 of the database administrator, the fifth input / output of the second-level computer 11 through the highway 18 is connected to the inputs / outputs of the automated workplace 13 for receiving experimental data and the automated workstation 14 for image processing and compression. The device comprises an additional spherical camera 20 of the sensor unit 1, consisting of structurally and schematically connected elements similar to the elements and connections of the main cylindrical camera.

 The method is as follows. The studies are carried out on a special device, where the patient is placed in a prone position, and after contactless and remote interaction using a variety of sensors, they simultaneously take the necessary characteristics of the biological system. The data obtained are preliminarily compressed, processed and recorded in the form of a multitude of parametric photoprojections and accumulated in super-large memory in the form of animations. Since the technology for studying the state of a biological object provides for taking readings simultaneously from all signal sensors, the totality of such signals, reflecting an instant cut of field values in the space occupied by a human object, can be called a “frame”. The signals that form the “frame” through the switch and second-tier computers are quickly dumped into the external computer network with an expert system; during this process, they can be visualized and perceived as a visible image that can be represented by signals of different color intensities. The totality of “frames” shot sequentially in time forms a “film”. Viewing a visualized "movie" allows the operator to observe the dynamics of changes in the CEEM of the human field.

 Diagnostic informativeness of KZEEMPO graphic representations can be illustrated by curves (Fig. 1a, 1b, 1c) representing diagnostic parametric functions in terms of the SEEEM effect (coherent endogenous exogenous electromagnetic field).

The inventive method (Fig. 2) is characterized by coherent radiation-absorption of electromagnetic fields by biological systems (BS), including humans, in a wide frequency range from 0.001 to 10 ¹² - 10 ¹⁵ Hz.

 The performed frequency identification by the levels of organization of the BS (table 1) provides the ability to assess changes in the BS, respectively, at the subcellular, cellular, tissue, as well as at the level of functional subsystems and the organism as a whole.

 Using the state identification scale (Fig. 2) of the biological system, it is possible to evaluate the ratio of signals A from the pathology zone to signals (F) (background signal) from the normal zones, assess at what level of the biological organization the formation of the pathology focus occurs, and thereby uniquely identify state of the bioobject. This scale is intended for use as a scale for making diagnostic and therapeutic decisions.

 The scale has two regions, one of them region H characterizes the state of the BS in which there is a process of coherent radiation of the electromagnetic field in the foci of pathology, the second region characterizes the state of the BS in which there is a process of coherent absorption of the electromagnetic field in the focus of the pathology.

 Considering the human body in its entirety as a set of interconnected properties (CEEMP), manifested in the form of signs (Fig. 4) on the CEEMP, the researcher should determine the state of the organism as a result of their perception, i.e. establish the presence of CEEEMographic signs that distinguish the patient’s condition from a healthy one, and then decide what pathological processes this change is associated with. Changes (Fig. 1) KEEEMPograms are analyzed to detect their deviation from the norm of activity of organs and functional subsystems. Comparing the two CEEEMograms, it is necessary first of all to find out whether the parameters of the source as an electromagnetic oscillation generator change, that is, the question of whether the difference between them is reduced to the difference in the measurement conditions. Thus, the analysis of KEEEMPograms is carried out by comparing sets of synchronously recorded characteristics, considering each of them as a whole in interconnected component, taking into account the biophysical features of KEEEMPograms, as a manifestation of the electromagnetic activity of the corresponding organization levels.

 The research method is based on the existence of a relationship between KEEMP-physiology and the functional as well as clinical and anatomical state of a person.

 Pathological and functional disorders that cause changes in the electromagnetic activity of the elements of functional subsystems and biological systems, which are reflected in KEEEMPograms, can be diagnosed by the methods of the described method for studying a biological object. In turn, in the absence of pathological and functional changes, the KEEEMF generator is also unchanged.

One of the examples of a specific medical manipulation for the operational control of the therapeutic effect (Fig. 3) on equipment that realizes the KEEEMF effect, where curve 1 is a characteristic of the integrated radiation power in the pain center of the spine, curve 2 characterizes the power of the KEEEMP radiation in other healthy parts of the spine, curve 3 shows the activity in the area of the pain focus after the first session of exposure, curve 4 characterizes the intensity of the pain after the fifth session with etnymi clinical signs of pain intensity. Examples of CEEEMP-isographic representations of foci of organ damage are presented in FIG. 4, where during CEEEMP of isographic diagnosis the following were recorded: 4a - anterior septal infarction, background 200 ^-6 cm, pathology 5 ^-4 cm; 4b - appendicitis, background 300 ⁺⁶ cm, pathology 2 ⁺⁶ cm, 4c - radiculitis, background 150 ^-5 cm, pathology 1 ^-6 cm; 4 - left-sided pneumonia, background 90 ^-6 cm, pathology 9 ^-6 cm, total cancer infiltrate.

 The technology of working with a system that implements the inventive method is as follows. Initially, the operator, using the test mode, checks the operability of the systems, making sure that it is operational, he puts it into operation and, according to the planned program, carries out an experiment to obtain objective data on the state of the electromagnetic field of a person.

 After completing this process, the operator-researcher solves a set of tasks for visualizing the electromagnetic field of a person and preparing images for a view that is convenient for perception and evaluation by medical experts.

The digital signal system (Fig. 5) has a megamatrix structure and each matrix has MxN elements: where M is the number of rows in the matrix (the number of sensors at one cylinder height);
N is the number of columns in the matrix (the number of sensors on one generatrix of the cylinder);
M _i xN _j is the number of matrices in the hypermatrix (the number of packets in M _i , samples in the time dimension, which must be stored in memory);
T 'is the technological time of adaptation of the system to the subject;
τ is the time of analysis of the state of the subject;
T = T ′ + τ is the interaction time.

A _i , j (s), D _i , j (s) - respectively max. the value and dynamic range of the measurement of the input signal of the systems with coordinates in the matrix (i, j) during the interaction time T.

 Block 5 of the analog memory (Fig. 7) stores the analog signals from the output of the sensors 4 with their subsequent transmission to the elements 6 of the amplification and analog digital conversion with a given accuracy, while the frequency of the ADC F = 1 / Δt is chosen large enough, for example 300, 400 , 500, 1000 samples for the selected animation.

 The signals of the human electromagnetic field, presented in digital form, are recorded and stored in the memory elements 7, then they are pre-processed in the supercomputer 8 primary processing. Such processing performs channel scaling when taking information for measuring the signal in each channel with a given accuracy and calculates a number of signal characteristics that allow, on the one hand, to correct the signals recorded in the memory block taking into account interference in the conversion paths and equipment malfunctions, and on the other hand, to obtain some statistical estimates used later in decision making.

 The array of signals recorded in the layers D of the memory elements 7 after preliminary processing and correction in the layers of the supercomputer 8 is the source for obtaining visible images of the electromagnetic field emitted by a person.

Visualization of a person’s electromagnetic field signals and the entire range of image processing tasks are carried out by a second-level supercomputer 11. Supercomputer 11 receives information from supercomputer 8 primary channels and uses it for further processing and compression. Along with field image processing, in the second-level supercomputer 11, hardware and a number of software diagnostics are carried out, the system testing mode is controlled, and the work of virtual workstations is supported, in which the possibility of voice exchange with the operator is provided:
APM-12 technical diagnostics and maintenance;
and additionally introduced:
AWP-13 obtaining experimental data;
AWP-14 image processing and compression.

 The output / input of a super-personal computer of the second level of image processing and compression and equipment diagnostics is connected to the input / output of a supercomputer of the highest level 16 with an expert analysis and diagnosis system, which has a huge memory in which knowledge and image databases should be stored, and high performance . The main content of supercomputers is expert systems, which should ensure the effective work of medical experts, experts in diagnosing the condition of the person under study on the basis of images of his electromagnetic field.

 The work of medical experts should be carried out on special workstations 16 supported by super-computers. Such AWP 16 should be built on the basis of personal graphic stations of high performance and resolution with a high level of service, in particular, with voice exchange with the operator.

 Given the complexity and importance of maintaining a knowledge base and images, an additional virtual workstation 17 database administrator has been introduced into the device.

 As a base for the construction of automated workstations (AWS) in the device, you can use AWG type CG-8600 company SECAPA (Fig. 8). AWP CG 8600 consists of two separate blocks, built on 32-bit multiprocessors. High performance, parallel architecture, direct addressing, high speed and resolution of image reproduction characterize the high quality of the selected sample. The central processing unit of the AWP ensures the functioning of the operating system and the use of all resources: input-output, operator console, monitor, keyboard, communications, mass memory on hard and floppy disks, network devices and other equipment.

 As a standard operating system (OS), the UNIX V system is adopted, which is the most common as applied to AWP, as provides the user with operational control. The microprocessor 80386 allows, using UNIX, to directly apply software created for a personal computer (PC) running in a DOS system. The amount of main memory is 4 MB, but can be increased up to 8 MB within the CPU board and up to 16 MB at the expense of an additional board. High-capacity external memory is provided using up to 80 MB HDD as a standard. AWP can be equipped with additional hard drives with a capacity of up to 760 MB. Hard disk drives on floppy disks with a diameter of 133 mm have a capacity of 1.2 MB.

 The control panel contains a standard keyboard and monitor with an EGA adapter compatible with IBM PC and providing a resolution of 640x350 pixels with 16 colors.

 The UNIX V system allows another user to connect to the AWP using a second terminal. AWP CG-8600 can be included in the Ethernet network using appropriate protocols.

 Like the central processor unit, the graphics unit has a multiprocessor architecture for controlling internal functions, calculations, segmentation, and raster graphics. The TMS 34010 processor contained in the block provides processing of one hundred thousand vectors per second. As a supercomputer of the highest level with an expert system, for example, large personal computing systems like PS / 2 of the latest modifications can be used.

 As a second-level computer, a Pentium class supercomputer that meets the requirements for speed and data flow volumes can be used.

 The device 3 control information retrieval (Fig. 9) can be implemented from the shaper 23 addresses, block 21 memory and generator 22 pulses of synchronization.

Information is taken in 3 modes. The first mode is the mode of simultaneous readout from the outputs of the sensors, the second is the mode of simultaneous readout of the outputs of the sensors from a specific field and the third is the mode of sequential cyclic readout from certain groups of sensors. These modes are selected either by a signal from the AWP control panel or automatically by means of signals on the address buses and data from the second-level computer, which are supplied to the address shaper 23 and to the memory unit 21 of the information collection control device 3. The switches 9 and 10 can be implemented on the basis of buffer registers, accessed by commands from the second level computer 11 and the information management device 3, in accordance with the selected polling mode, the switches control the keys K _x and K _y .

 The circuit implementation of elements and blocks is based on the use of microcircuits 537, 564, 573, 133 or similar series.

 As sensors 4, broadband sensors can be used that record the emitted and absorbed integrated electromagnetic field from biological systems, for example, phased array antennas with a sharp radiation pattern.

 Using the proposed method allows to study bioenergetic processes taking place in the body of an object at all levels of BS organization, i.e. atomic-molecular, biochemical, biopolymer, subcellular, cellular, cell-population, tissue, organ, functional-subsystem, organismic.

 Analysis of KEEMPograms using modern computer technology can dramatically increase the effectiveness of diagnostics and therapy, reduce the relative frequency of diagnostic errors, shorten examination time, automation of research opens up opportunities for continuous (non-selective) preventive examinations of the entire population, for continuous dynamic monitoring of patients, and also in times of great disaster.

Sources of information
1. US patent N 5003475, IPC G 06 F 15/38, 03/26/91 (prototype).

Claims (4)

 1. A method for studying the state of a bioobject, including recording a non-thermal field and comparing it with a reference field of a bioobject, characterized in that the object is represented as a multilayer closed sphere such as an electromagnetic "nested doll", where each layer is identified with the corresponding level of organization of the biological system and its internal state by the type of resonant interaction, and which in the "norm" is represented as the state of the electromagnetic field of broadband and amplitude-stationary, limited frequency at the top, and in the “functional” state and in the “pathology” in the form of a narrow-band amplitude non-stationary type of radiation - absorption of the state of the electromagnetic field, in which non-thermal coherent energy interaction takes place between the layers in the form of bioenergy exchange, using their own coherent electromagnetic fluctuations of the biological object, characterizing endogenous and exogenous processes occurring in the biological system in the "normal" and "pathology" at all levels Organizations of the biological environment in a continuous range of resonant frequencies generated at the appropriate levels of organization, followed by the formation of a static and dynamic image of the object, as a whole, and layer-by-layer at the appropriate level of biological organization in spatial and temporal mode by multichannel parallel processing of the information flow and genetically determined the conditioned background of the “norm” and the correlation with it of the background of “functional” and “pathological” significant anomalies, and after comparison reference field, fix, at what level of biological organization develops investigated anomaly.  2. A device for studying the state of a biological object, comprising a sensor unit, consisting of sensors, a signal generator and a device for controlling information retrieval, a second-level computer and a top-level computer network with an expert system, medical specialists workstations and maintenance and diagnostic workstations, the first input-output The second-level computer is connected to the first input-output of the upper-level computer network, the second input-output of which is connected via the main line to the inputs and outputs of the medical specialists workstation, the input-output of the technical workstation of living and diagnostics through the highway is connected to the second input-output of a second-level computer, characterized in that the sensor unit is made in the form of a cylindrical chamber, the dimensions of which are not less than the dimensions of the biological object, into which are added layer-wise arranged and connected in series with each other elements of the analog memory, amplifiers and analog-to-digital converters with an intelligent signal pre-processing system, elements of digital memory, primary level supercomputers, switches corresponding the inputs and outputs of which are connected to the first and second input-output of the information acquisition control device, the third input-output of which is connected to the third input-output of a second-level computer, the fourth input-output of which is connected to one of the switches with the formation of parallel information channels, which connected to the corresponding sensors and organized in a two-dimensional matrix, rolled continuously into a cylindrical shape, and the device additionally contains an automated workstation for obtaining experimental data, automated workstation processing and compression information connected via a line to the second input-output of the second-level computer and workstation database administrator, input-output connected via a line to the second input-output of the upper level computer network.  3. The device according to claim 2, characterized in that in the two-dimensional matrix of the sensor block, the rows consist of elements of analog memory, amplifiers, analog-to-digital converters with an intelligent signal preprocessing system, elements of digital memory, primary computers of the primary level and consist of information channel, while the first inputs of the analog memory elements are connected to the corresponding sensors, the outputs of the supercomputer through the first keys are connected to the first switch, and the columns are t of layered serial connection of said elements of the information channel, the second inputs of which are connected to the outputs of the corresponding second keys that its input-output connected to the second switch.  4. The device according to claim 2, characterized in that it further comprises a spherical prefix to the camera of the sensor unit, made similar to the main cylindrical camera and closes it from the head.

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