RU146670U1 - DYNAMIC COMPUTER TOMOGRAPHY IMAGE DATA MONITORING SYSTEM - Google Patents

Abstract

A system for monitoring image data of dynamic computed tomography objects containing a module for selecting the reference address of the monitoring object in the server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the information input of the module for selecting the reference address of the monitoring object in the server database is intended for receiving codes of identifiers of specific layers of images of objects, and the synchronizing input of the system is designed to receive and the synchronization signals of entering codes of identifiers of specific layers of images of objects into the selection module for the reference address of the monitoring object in the server database, the module for receiving data records of layer-by-layer scanning of images of objects from the server database, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, and the control the input of the module for receiving data records of layer-by-layer scanning of images of objects from the server database is the control input m of the system designed to set the processing mode for layer-by-layer slices of images of objects, while the information input of the module for receiving data records of layer-by-layer scanning of images of objects from the server database is intended for receiving records of the server database, and the synchronizing input of the module for receiving records of data for layer-by-layer scanning of images of objects from the database server data is intended for receiving synchronization signals for entering server database records into the layer-by-layer scan data record receiving module

Description

The utility model relates to the field of computer engineering, in particular, a system for monitoring image data of objects of dynamic computed tomography.

Global trends in medical instrumentation have undergone significant changes in recent years. This is mainly due to the need to improve the quality of diagnostics, which leads both to the creation of new highly informative diagnostic devices and to the improvement of traditional technologies.

The modern level of medical technology makes it possible to identify structural and functional changes of the same organ using devices that have a different principle of operation, while the reliability of the data obtained will be comparable. In such conditions, the information component of research comes first.

At this stage, one of the most informative methods is tomography, which gives much more information about each elementary volume of the studied object than other known diagnostic methods. The term “tomography” came from two Greek words: that | doa - section and urafoa - I write and means layer-by-layer study of the structure of various objects.

Typically, computed tomography data is a set of tomograms (slices) with a total number of up to several hundred, with each tomogram being a halftone image with dimensions 512 × 512 and a depth of 12 bpp, the integer brightness values of which correspond to the relative densities of the tissues in the scanning plane (in Hounsfield units )

Thus, the volume of data corresponding to just one tomographic study can reach up to 100 MB, and quite a long time is required to obtain these data.

There is a problem of reducing the time of tomographic studies, which can be solved if for analytical analysis using computer processing of a limited set of tomograms in real time.

Known systems that could be used to solve the problem (1, 2).

The first known system uses projection data obtained during a tomographic examination of a periodically moving object to reconstruct a plurality of image levels, the image levels being generated from projection data segments having angular sizes that are smaller than the size necessary to provide a complete tomographic data set. The image levels are then combined to generate the first image data characteristic of the object in a randomly selected first phase of movement, and a human-readable image characteristic of the first image data is displayed.

The system includes means for using projection data for reconstructing multiple image levels, means for combining image levels, and means for displaying a human-readable image characteristic of the first image data. The system also contains a computer-readable storage medium containing instructions for implementing methods for visualization. (one).

A significant drawback of this system is its limited speed, due to the need to obtain the entire set of tomograms and its subsequent computer processing.

Another system is known, which contains a module for receiving data of layer-by-layer slices of images of an object, a module for selecting reference addresses of records of reference layer-by-layer descriptions of slices of images of objects, a module for managing data samples of a knowledge base, a module for maintaining a database of reference layer-by-layer descriptions of slices of images of objects, a module for identifying data for layer-by-layer images slices of objects, a module for receiving data of reference descriptions of layer-by-layer slices of images of objects, the first and second modules for modifying recording addresses and ityvaniya system data server database integration module signal recording and reading of database server data system. (2).

The last of the above technical solutions is closest to the described.

Its disadvantage also lies in the low speed of the system, due to the need to obtain the entire set of tomograms and its subsequent computer processing.

The purpose of the utility model is to increase the system performance by eliminating the need to obtain a complete set of tomograms and using only informative slices in real time for computer processing of data.

This goal is achieved by the fact that in the system containing the module for selecting the reference address of the monitoring object in the server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, the information input of the module for selecting the reference address of the monitoring object in the server database is intended for receiving codes of identifiers of specific layers of images of objects, and the synchronizing input of the system is designed to receive synchronizing signals codes of identifiers of specific layers of images of objects in the selection module for selecting the reference address of the monitoring object in the server database, the module for receiving data records of layer-by-layer scanning of images of objects from the server database, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, and the control input of the recording receiving module data layer-by-layer scanning of images of objects from the server database is the control input of the system, designed to install the processing mode of layer-by-layer slices of images of objects, while the information input of the module for receiving records of data of layer-by-layer scanning of images of objects from the server database is designed to receive records of the server database, and the synchronizing input of the module for receiving records of data of layer-by-layer scanning of images of objects from the server database is intended synchronization signals for recording server database records in the module for receiving data records of layer-by-layer scanning of images of objects from the database server, the first information output of the module for receiving data records of layer-by-layer scanning of images of objects from the server database is the information output of the system, intended for data output to the information input of the database server, the module for integrating data recording and reading signals, the address output of which is the address output of the system, intended for issuing write addresses and reading data to the address input of the database server, the first synchronizing output of the module for integrating write signals and data reading is the first synchronizing output of the system, intended for issuing control signals to the input of the first channel interruption of the database server, and the second synchronizing output of the module for integrating data recording and reading signals is the second synchronizing output of the system, intended for issuing control signals to the input of the second channel of the server interrupt database, a module for generating addresses for reading layer-by-layer data from a server database, the information input of which is dinan with the first information output of the module for selecting the reference address of the monitoring object in the server database, the synchronizing input of the module for generating addresses for reading personal data of the server from the server database is connected to the synchronizing output of the module for selecting the reference address of the monitoring object in the server database, while the address output for generating addresses reading data of a layer-by-layer scan from the server database is connected to the first address input of the module for integrating data recording and reading signals, and with the synchronizing output of the module for generating addresses for reading data of layer-by-layer scanning from the server database is connected to the first synchronizing input of the module for integrating data recording and reading signals; a module for determining the duration of time cycles of sampling layer-by-layer slices of images of objects is introduced, the information input of which is connected to the second information output of the module for selecting the reference address monitoring object in the server database, synchronizing the input of the module for determining the duration of time cycles The sample of layer-by-layer slices of images of objects is connected to the synchronizing output of the module for selecting the reference address of the monitoring object in the server database, the first clock input of the module for determining the duration of time cycles for sampling layer-by-layer slices of images of objects is connected to the first synchronizing output of the module for receiving records of data of layer-by-layer scanning of images of objects from the database server, one output of the module for determining the duration of time cycles for sampling layer-by-layer slices of images of soybean objects is dined with the counting input of the module for generating addresses for reading data of layer-by-layer scanning from the server database, and the other output of the module for determining the duration of time cycles for sampling layer-by-layer slices of images of objects is the signal output of the system, the module for identifying the status of data for layer-by-layer scanning of images of objects, the first and second information inputs of which are connected with the second and third information outputs of the module for receiving data records of layer-by-layer scanning of images of objects from the database server, respectively, the third information input of the module for identifying the status of data for layer-by-layer scanning of images of objects is the third information input of the system intended for setting codes for status indicators of data for layer-by-layer scanning of images of objects, and the synchronizing input of the data module for layer-by-layer scanning of images of objects is connected to the second synchronizing output of the recording reception module data layer-by-layer scanning of images of objects from the server database, while first the second and second control outputs of the module for identifying the status of data of layer-by-layer scanning of images of objects are connected to the second and third clock inputs of the module for determining the duration of time cycles of sampling layer-by-layer slices of images of objects, respectively, and the fourth clocking input of the module for determining the duration of time cycles of sampling of layer-by-layer slices of images of objects is connected to a synchronizing the output of the module for generating addresses for reading data of layer-by-layer scanning from the server database, a module for generating a reference address for recording data of layer-by-layer scanning of images of objects in a server database, the input of which is connected to the third control output of the module for identifying the status of data for layer-by-layer scanning of images of objects, and generating current addresses for recording data of layer-by-layer scanning of images of objects in a server database, information and timing inputs which are connected to the information and synchronizing outputs of the module for forming the reference address of the data recording of the layer-by-layer kanirovaniya images of objects in the server data, respectively, and the data and clock outputs forming unit records the current address data layerwise scanning images of objects in a database server connected to the second address and the second clock input module integration signal recording and reading data, respectively.

The invention is illustrated by drawings, where in FIG. 1 is a structural diagram of a system; FIG. 2 is a block diagram of a module for selecting a reference address of a monitoring object in a server database, FIG. 3 is a block diagram of a module for determining the duration of time cycles of sampling layer-by-layer slices of images of objects, FIG. 4 is a block diagram of a module for generating addresses for reading layer-by-layer data from a server database, FIG. 5 is a structural diagram of a module for receiving data records of layer-by-layer scanning of images of objects from a server database, FIG. 6 is a structural diagram of a module for identifying the status of data of layer-by-layer scanning of images of objects; FIG. 7 is a structural diagram of a module for generating a reference address for recording data of layer-by-layer scanning of images of objects in a server database; FIG. 8 is a block diagram of a module for generating current addresses of data records of layer-by-layer scanning of images of objects in a server database; FIG. 9 is a block diagram of a module for integrating write and read signals.

The system (Fig. 1) contains module 1 for selecting the reference address of the monitoring object in the server database, module 2 for determining the duration of time cycles for sampling layer-by-layer slices of images of objects, module 3 for generating addresses for reading data for layer-by-layer scanning from the server database, module 4 for receiving records of layer-by-layer data records scanning images of objects from the server database, module 5 for identifying the status of data of layer-by-layer scanning of images of objects, module 6 for generating a reference address for recording data in layers the first scan of the images of objects in the server database, a module 7 for generating the current addresses of the data records of the layer-by-layer scanning of images of objects in the server database, a module 8 for integrating the write and read signals.

In FIG. 1 also shows the control 9 system input, the first 10, second 11 and third 12 information inputs of the system, the first 13 and second 14 synchronizing inputs of the system, as well as information 15, address 16, first 17 and second 18 synchronizing, and signal 19 system outputs.

When the information input 10 of the system is designed to receive codes of identifiers of specific layers of images of objects, and the synchronizing input 13 is designed to receive synchronization signals of entering codes of identifiers of specific layers of images of objects in the selection module of the reference address of the monitoring object in the server database.

The second information input 11 is intended for receiving data records of specific layers of images of objects from the server database, and the second synchronizing input 14 is intended for receiving synchronizing signals of the server for recording data of specific layers of images of objects from the server database in the selection module of the reference address of the monitoring object in the database server.

The third information input 12 is intended for setting codes for sorting data records of layer-by-layer images of objects from the keyboard of a monitoring workstation.

The information output 15 of the monitoring system is intended for issuing data records of layer-by-layer images of objects to the information input of the database server, and the address output 16 is intended for issuing write addresses and reading data to the address input of the database server.

The synchronizing 17 output is intended for issuing synchronizing signals to the input of the first channel of the database server interrupt, and the second synchronizing 18 output is intended for issuing synchronizing signals to the input of the second channel of the database server interrupt.

Signal 19 output is intended for issuing a signal to the third input of the database server interrupt.

Module 1 (Fig. 2) of specifying identifiers for layer-by-layer slices of images of objects of scanning contains a register 21, a decoder 22, a memory unit 23 made in the form of a permanent storage device, elements 24-26 AND, elements 27-1, 27-2 of the delay. The drawing shows information 10 and synchronizing 13 inputs, as well as information 28, 29 and synchronizing 30 outputs.

Module 2 (Fig. 3) for determining the duration of time cycles of sampling current slices of images of objects contains a register 31, counter 32, comparator 33, OR element 34, delay element 35. The drawing shows information 36, synchronizing 37 and the first 38, second 39, third 40 and fourth 41 clock inputs, as well as outputs 58, 59.

Module 3 (Fig. 4) of the formation of the read addresses of the data of layerwise slices of images of scan objects from the server database contains a reverse counter 45, an OR element 46, a delay element 47. The drawing shows information 48, synchronizing 49 and counting 50 inputs, as well as address 51 and synchronizing 52 outputs.

Module 4 (Fig. 5) for receiving data of layer-by-layer slices of images of scan objects from the server database contains register 53, trigger 54, elements 55, 56 I. The drawing shows the control 9, information 11 and synchronizing 14 inputs, as well as the first 121, second 122 and third 123 information, the first 124 and second 125 synchronizing outputs.

Module 5 (Fig. 6) for identifying the status of data of layerwise slices of images of scanning objects contains the first 60 and second 61 comparators, register 62 and delay element 63. The drawing shows the first 64, second 65 and third 12 information input of the module, which is the third information input of the system, and synchronizes 66 inputs, as well as the first 71, second 72 and third 73 control outputs.

Module 6 (Fig. 7) for generating a reference address for recording sorted data of layer-by-layer slices of images of scan objects in the server database contains read-only memory 70, register 71, trigger 72, AND elements 73, 74, OR element 75, and delay elements 76, 77 . The drawing shows the input 80, as well as information 81 and synchronizing 82 outputs.

Module 7 (Fig. 8) for generating current addresses of records of sorted data of layer-by-layer slices of images of scan objects in the server database contains an adder 85, a counter 86, and delay elements 87, 88. The drawing shows information 90 and synchronizing 91 inputs, as well as information 92 and synchronizing 93 outputs.

Module 8 (Fig. 9) of the integration of write and read signals contains a trigger 94, elements 95 and 96 of the first and second groups, delay elements 97, 98, elements 99 of the OR group. The drawing shows the first 100 and second 101 address inputs, the first 102 and second 103 clock inputs, as well as address 16 and clock outputs 17, 18.

Consider the system’s operation from the moment the monitoring operator indicates the identifier of a specific image layer of the object, which from the control panel of the automated workstation through input 10 enters the input of register 21 of module 1 and is entered into it by a synchronizing pulse from input 13.

From the output of register 21, the identifier code of a particular layer of the image of the object is fed to the information input of the decoder 22, which decodes this code and prepares the signal path from input 13 of module 1, opening one of the elements 24-26 I. For definiteness, we assume that the high potential one input element 25 I.

In parallel with this, the synchronizing pulse from the input 13 of the system is delayed by the element 27-1 for the time the codogram is entered in the register 21 and the decryptor 22 is triggered, and then it polls the states of the elements 24-26 I.

Considering the fact that only the And element 25 will be open at one input, then passing through this And element, the clock pulse from the output of the Delay element 27-1 goes to the read input of the fixed memory cell of the permanent storage device 23, in which the reference address code of the parameter value recording is stored the selected image layer of the object in the server database and the code of records related to the selected monitoring object.

The data structure in the ROM memory cell is as follows:

THE CODE THE CODE Reference address for recording the parameter values of the selected monitoring object in the server database The number of records characterizing the selected monitoring object Output 28 of module 1 Output 29 of module 1

The reference address code from the output 28 of module 1 is read to the input 48 of module 3, where it enters the input of the counter 45, and the code of the number of records from the output 29 of module 1 is sent to the input 36 of module 2 and then to the information input of register 31.

In parallel with the described process, the same read pulse from the output of the element 27-1 of module 1 is delayed by the delay element 27-2 for the time of reading the contents of the fixed cell ROM 23 and then from the output 30 of module 1 acts as a clock input 49 of module 3, fixing the counter 45 the code of the reference address of the memory cell of the server database, and through the input 37 of module 2 to the synchronizing input of the register 31, fixing in it the code of the number of records characterizing the selected monitoring object

The address code from the output 51 of module 3 is issued to the input 100 of module 8, and then goes to one of the inputs of elements 95 And groups that are open at the other input with high potential from the inverse output of trigger 94, which is in its original state at this point in time. As a result of this, the address code passes through elements 95 AND groups and elements 99 OR groups to the output 16 of the system.

At the same time, the synchronizing pulse from the input 49 of module 3 passes through the OR element 46, is delayed by the element 47 for the duration of the counter 45 operation, and from the output 52 of the module 3 goes to the input 102 of the module 8, where it goes to the installation input of the trigger 94, confirming its initial state , and after the delay, the element 97 for the duration of the trigger 94 is issued to the output 17 of the system. From output 17, a synchronizing pulse is issued to the input of the first channel of the database server interrupt.

According to this signal, the database server goes to the subroutine for reading records characterizing the selected monitoring object, starting with the reference address specified on the address output 16.

The very first read-out that characterizes the selected monitoring object from the server database goes to the system input 11 and then goes to the information input of the register 53 of module 4, into which it is entered by the synchronizing pulse of the database server coming from input 14. From the output of 121 module 4 the content of this record is issued through the output of the system 15 to the input of the data processing server, which, upon receipt of this record, goes to the subroutine for comparing a layer-by-layer image slice of this object with reference layer-by-layer slices and this object, as a result of which the presence of pathology in the resulting image is determined.

In parallel with this, the same synchronizing pulse from the output 124 of module 4 goes to the input 38 of module 2, from where it passes the OR element 34 and goes to the counting input of the counter 32, counting the number of read records of the monitoring object from the server database.

From the output of the counter 32, the number of read records of the monitoring object is fed to one information input of the comparator 33, the other information input of which from the output of the register 31 is supplied with the code of the number of records characterizing the selected monitoring object.

According to the synchronizing signal from the output of the OR element 34, delayed by the element 35 at the time of operation of the counter 32, supplied to the synchronizing input of the comparator 33, the latter compares the input codes, and since the readings of the counter 32 are much less than the number of entries in the register 31, then the output 58 of module 2 an impulse is formed, which, through the input 50 of module 3, enters the counting input of the counter 45, increasing its readings by one and thereby forming the read address of the next record from the server database at the system output 16 described above th.

In parallel, the synchronizing pulse from the input 50 of module 3 passes the OR element 46, is delayed by the delay element 47 for the time the counter operates and from the output 52 of the module 3 is again output to the output 17 of the module 8 in the manner described above, from where the synchronizing pulse is transmitted to the input of the first interrupt channel database server.

By this signal, the database server again switches to the routine for reading records, and entering the read records into module 4 in the manner described above.

This process of reading records of the selected monitoring object continues until the readings of the counter 32 of module 2 become equal to the readings of the register 31. This moment of time will be fixed by the comparator 33 by generating a pulse at output 59, which is output to the input of the third channel of the database server interrupt. By this signal, the database server goes to the subroutine displaying the results on the monitor screen of the monitoring operator.

To implement the second mode of operation, in which there is no need to obtain all slices of the layer-by-layer scanning of the object of research, a control signal is supplied to the input 9 of the system. This signal is fed to the direct input of trigger 54 of module 4 and sets it to a single state, in which trigger 54 opens element 55 I.

In addition, the values of the records of the object and the duration of the time period are set by the operator from the control panel through input 12 in module 5, where these values are entered in register 62.

After that, the operator selects the monitoring object by entering the corresponding identifier in the register 21 and restarts the system by applying a synchronizing signal to the input 12 in the manner described above.

However, unlike the first mode, after the read-in of the parameter values of the selected monitoring object in the server database is entered into the register 53 of module 4, the synchronizing pulse from input 14 now passes through element 55 AND, and from output 125 of module 4 it goes to input 66 of module 5 and then to the synchronizing input of the comparator 60, to one information input 119 of which from the input 65 of module 5 the indicator value from the read record is supplied, and to the other information input 120 is the code of the indicator value specified by the monitoring operator from the output 117 Histra 62.

The synchronization signal from input 66 is delayed by the delay element 63 for the time the records are received from the server database into register 53, and is fed to the synchronization input of the comparator 60.

Using this signal, the comparator compares the input codes, and if the set value of the indicator does not match the value of the indicator from the database, then the comparator 60 generates a mismatch signal at the software output, which from the output 67 of module 5 goes to the input 39 of module 2, where element 34 passes OR and enters the counting input of the counter 32, organizing a reading cycle of the next record in the manner described above.

If the values of the indicators coincide, then the comparator 60 generates a coincidence pulse at the output 111, which is fed to the synchronizing input of the comparator 61, on one information 112 of which the code of the set time interval is received, and on the other information input 113 - the code of the interval of read write.

If the values of the time intervals do not match, then the comparator 61 generates a pulse at the output 115, from which the specified pulse through the output 68 of the module 5 and the input 40 of the module 2 again organizes the reading cycle of the next record.

If the values of the time indicators are the same, then the comparator 61 generates a filtered record signal at the output 116, which from the output 69 of the module 5 is fed to the input 80 of the module 6 and starts the procedure of forming an array of filtered records. To do this, he goes to one of the inputs of the elements 73, 74 AND module 6.

However, only one element And will be open at one input, since one of its inputs is supplied with a high potential from the inverse output of the trigger 72, which is in the initial state.

As a result of this, a synchronizing pulse from input 80 passes element 74 AND, and enters the input of a fixed memory cell in ROM 70, where the reference address of the buffer zone of the memory of the database server reserved for storing filtered records of objects of research is stored.

The same synchronizing pulse from the output of element 74 AND is delayed by element 76 for the duration of reading the code from ROM 70, and, firstly, it goes to the synchronizing input of register 71, entering the reference address of the record of the data array of layer slices.

Secondly, the same pulse is applied to the single input of trigger 72 and sets it to a single state, in which element 74 And will be closed, and element 73 And will be open.

This will prepare the circuit for the passage of the next clock pulse from input 80.

And, finally, thirdly, the pulse from the output of the delay element 76 passes through the OR element 75, is again delayed by the element 77 for the time the address code is entered into the register 71, and from the output 82 of the module 6 it enters the input 91 of the module 7.

In addition, the same pulse is fed to the synchronizing input of the adder 85, to one information input of which from the input 90 is the code of the reference address of the record from the output of the register 71 of the module 6, and to the other information input the readings of the counter 86 are given, which are equal to zero at this time since the counter 86 is in the initial state.

By a synchronizing pulse, the adder 85 summarizes the reference address code from input 90 with the counter code zero code 86, and outputs the write address code from the output 92 of the module 7 to the input 101 of the module 8 and then to the same inputs of the 96 AND group elements.

Secondly, the same clock pulse from the input 91 of the module 7 is delayed by the element 87 for the duration of the operation of the adder 85 and from the output 93 of the module 7 is fed to the input 103 of the module 8 and then to the direct input of the trigger 94, setting the latter to a single state, at which high with potential from a direct output, elements 96 And groups are opened at another input, thereby connecting the output of the adder 85 to output 16, as a result of which the reference recording address is issued to address 23 of the system output.

Thirdly, the synchronizing pulse from the input 103 of the module 8 is delayed by the element 98 for the duration of the formation of the final code at the address 16 output, and is issued to the output 18 of the system as a write control signal.

This signal is fed to the input of the third channel of the database server interrupt, through which the server goes to the routine for recording layer-by-layer slices from the information output 15 of the system to the database at the address generated at output 16.

In addition, the pulse from the output of the delay element 87 of the module 7 is delayed by the element 88 for the duration of the adder and goes to the counting input of the counter 86, fixing the first record in the array of filtered layer-by-layer slices of images of the object of study.

When the next pulse appears at the input 80 of module 6, the latter will now pass through the And element 73, open at this point in time with high potential from the direct output of the trigger 72, through the OR element 75 and after delay, the element 77 will be output to the output 82 of the module 6, and described above, the process of recording filtered layer-by-layer slices of images of the object of study will be continued as described above.

Thus, the introduction of new modules and new constructive connections made it possible to significantly increase the speed of the system by eliminating the need to obtain a complete set of tomograms and using only informative slices in real time for computer processing of data.

Sources of information taken into account when drawing up the description of the application:

1. RF patent No. 2441587 (05/09/2007)

2. RF patent №125366 (06/05/2012) - (prototype).

Claims (1)

A system for monitoring image data of dynamic computed tomography objects containing a module for selecting the reference address of the monitoring object in the server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the information input of the module for selecting the reference address of the monitoring object in the server database is intended for receiving codes of identifiers of specific layers of images of objects, and the synchronizing input of the system is designed to receive and the synchronization signals of entering codes of identifiers of specific layers of images of objects into the selection module for the reference address of the monitoring object in the server database, the module for receiving data records of layer-by-layer scanning of images of objects from the server database, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, and the control the input of the module for receiving data records of layer-by-layer scanning of images of objects from the server database is the control input m of the system designed to set the processing mode for layer-by-layer slices of images of objects, while the information input of the module for receiving data records of layer-by-layer scanning of images of objects from the server database is intended for receiving records of the server database, and the synchronizing input of the module for receiving records of data for layer-by-layer scanning of images of objects from the database server data is intended for receiving synchronization signals for entering server database records into the layer-by-layer scan data record receiving module of images of objects from the server database, the first information output of the module for receiving records of data of layer-by-layer scanning of images of objects from the database of the server is the information output of the system intended for outputting data to the information input of the database server, an integration module for recording and reading data signals, the address output of which is the address output of the system, intended for issuing write and read addresses to the address input of the database server, the first synchronizing you One of the module for integrating data recording and reading signals is the first synchronizing output of the system intended for issuing control signals to the input of the first interrupt channel of the database server, and the second synchronizing output of the module for integrating data recording and reading signals is the second synchronizing output of the system for issuing control signals to the input of the second channel for interrupting the database server, the module for generating addresses for reading data of layer-by-layer scanning from the database a raver, the information input of which is connected to the first information output of the module for selecting the reference address of the monitoring object in the server database, the synchronizing input of the module for generating addresses for reading personal data from the server database is connected to the synchronizing output of the module for selecting the reference address of the monitoring object in the server database, this address output of the formation of addresses for reading data layer-by-layer scanning from the server database is connected to the first address input of the integration module with data writing and reading signals, and the synchronizing output of the module for generating addresses for reading data from a layer-by-layer scan from the server database is connected to the first synchronizing input of the module for integrating data recording and reading signals, characterized in that it contains a module for determining the duration of time cycles for sample layer-by-layer slices of object images, the information input of which is connected to the second information output of the selection module of the reference address of the monitoring object in the server database, sync the onizing input of the module for determining the duration of the time cycles of sampling layered slices of images of objects is connected to the synchronizing output of the selection module for the selection of the reference address of the monitoring object in the server database, the first clocking input of the module for determining the duration of time cycles of sampling of layered slices of images of objects is connected to the first synchronizing output of the module for receiving records of layer data scanning images of objects from the server database, one output of the module determining the duration of time loop cycles for sampling layer-by-layer slices of images of objects is connected to the counting input of the module for generating addresses for reading data of layer-by-layer scans from the server database, and another output of the module for determining the duration of time cycles for sampling layer-by-layer slices of images of objects is a signal output of the system; the first and second information inputs of which are connected to the second and third information outputs of the recording reception module data for layer-by-layer scanning of images of objects from the server database, respectively, the third information input of the module for identifying the status of data for layer-by-layer scanning of images of objects is the third information input of the system intended for setting status codes for the data of layer-by-layer scanning of images of objects, and the synchronizing input of the data module for layer-by-layer scanning of images of objects is connected to the second synchronizing output of the module for receiving data records of a layer scan object images from the server database, while the first and second control outputs of the module for identifying the status of data for layer-by-layer scanning of images of objects are connected to the second and third clock inputs of the module for determining the duration of time cycles for sampling layer-by-layer slices of images of objects, respectively, and the fourth clock input of the module for determining the duration time cycles of sampling layerwise slices of images of objects is connected to the synchronizing output of the address generation module with extracting layer-by-layer scan data from the server database, a module for generating a reference address for recording data of layer-by-layer scanning of images of objects in the server database, the input of which is connected to the third control output of the module for identifying the status of data of layer-by-layer scanning of images of objects, and generating current addresses of records of data of layer-by-layer scanning of images of objects in the server database, the information and synchronizing inputs of which are connected to the information and synchronizing outputs by the module for generating the reference address for recording data of the layer-by-layer scanning of images of objects in the server database, respectively, and the information and synchronizing outputs of the module for generating the current addresses of the records of data for the layer-by-layer scanning of images of objects in the server database are connected to the second address and second synchronizing inputs of the module for integrating recording signals and reading data accordingly.

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