RU2701049C1 - Automated system for processing laryngosal angles data of patients - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, in particular to an automated system for processing data on angles of lordoses of patients, allowing to solve tasks of analyzing and processing data on angles of lordoses of patients, recognizing the degree of their deviation and taking decisions on the detected degrees of deviation of the sequence of loads on the spine for the procedures of correction of its lordoses. Technical result is achieved by the fact that the system comprises an identification module for basic address of angles of lordoses in the system server database, an identification module for relative address of angles of lumbar lordoses in the system server database, a selection module in the server database of the lumbar lordoses of patients angles address system, a recognition module for lumbar lordosis of patients degree deviation,a selection module in the server database of address system of the sequence of loads on the spinal column for correcting the lumbar lordosis angles, a registration module for lordoses of patients angles, a recognition module for the degree of deviation of cervical lordosis of patients, a selection module in the server database of address system of the sequence of loads on the spinal column for correcting the cervical lordosis angles, a registration module for the sequence of loads on the spinal column for correcting the lumbar lordosis angles, a registration module for the sequence of loads on the spinal column for correcting the cervical lordosis angles, a synchronization module for issuing the sequence of loads on the spinal column for correcting the lordoses of patients angles, a monitoring module for the completion of the procedure for analyzing the array of patients, a registration module for the patients SNILS (Insurance Number of Individual Ledger Account) codes.

EFFECT: faster operation of the system by excluding time spent on analysis and processing of high-information tomograms of lordoses of patients and initialization of data processing of lordoses of patients angles, pre-measured and isolated on the tomograms themselves.

1 cl, 15 dwg, 2 tbl

Description

The invention relates to medicine, in particular, to an automated system for underwater correction of lordosis of the spine, allowing to solve the problems of analysis and data processing of angles of lordosis of the spinal column of patients, recognize the degree of deviation and make decisions on the revealed degrees of deviation about the sequence of loads on the spine to perform procedures for correcting it lordoses.

Known systems that could be used to solve the problem [1,2].

The first known system includes a module for identifying the base address of the tomograms of the spine in the database of the system server, a module for identifying the relative address of tomograms of the spine in the database of the system server, a module for selecting addresses of tomograms of the spine of the requested patient in the database of the system server, a module for recognizing the branch of processing tomograms of the department spinal column of patients, module for recording patient data, module for monitoring the completion of the procedure for analyzing an array of patients, module for identifying ation base address parameter correction procedures curvature arc lordosis spine patients in the system server database module address selection parameters arc curvature correction procedures lordosis of the spine of the patient in the database server database system [1].

The disadvantage of this system is its low speed, due to the processing of tomograms, which are a priori objects of high information capacity.

Another system is known that includes a module for identifying the base address of tomograms of the spine, a module for identifying the relative address of tomograms of the vertebral patients, a module for selecting addresses of tomograms of the vertebral department of the requested patient, a module for calling the subroutine for calculating the difference in tomograms of the standard vertebral section and the vertebral department of the patient, and a module for recording the difference in tomograms of the standard patient vertebral and vertebral sections of the patient, module for the identification of patients with the vertebral section without pathologies identification module base address correction procedures spinal lordosis card module address selection parameter correcting spinal lordosis card patients procedures module registration parameters patients, patients complete array of test procedure control unit [2].

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

Its disadvantage is the low speed of the system, due to the fact that the choice of parameters for the correction of lordosis of the spine is not carried out by processing the angles of lordosis autonomously measured and taken from tomograms, but by processing tomograms of lordosis of the spine, which, with a priori large information capacities of tomograms of lordosis, leads to unreasonably large time spent on the identification of parameters of procedures for the correction of lordosis.

The purpose of the invention is to increase the speed of the system by eliminating the time spent on analysis and processing of highly informative tomograms of lordoses of the spinal column of patients and initializing the processing of data of the angles of lordoses of the spinal column of patients previously measured and highlighted on the tomograms themselves.

The goal is achieved by  what's in the system  containing a module for identifying the base address of the angles of the lordosis of the spine in the system server database,  the information input of which is the first information input of the system,  designed to receive the request codogram from the workstation of the system user,  the synchronizing input of the identification module of the base address of the angles of the lordosis of the spine in the database of the system server is the first synchronizing input of the system,  designed to receive the synchronization signals of entering the request codogram from the workstation of the system user into the identification module of the base address of the angles of the lordosis of the spine in the database of the system server,  a module for identifying the relative address of the angles of the lordosis of the lumbar spine in the system server database,  the first and second information inputs of which are connected to the first and second information outputs of the identification module of the base address of the angles of the lordosis of the spine in the database of the system server, respectively,  the synchronizing input of the identification module of the relative address of the angles of the lordosis of the lumbar spine in the system server database is connected to the synchronizing output of the identification module of the identification of the base address of the angles of the lordosis of the spine in the system server database,  selection module in the database server of the system of addresses of the angles of lords of the lumbar spine of patients,  the first information and first synchronizing inputs of which are connected to the information and synchronizing outputs of the identification module of the relative address of the angles of the lordosis of the lumbar spine in the system server database,  the second information input of the selection module in the database of the server of the system of addresses of the angles of the lords of the lumbar spine of the patients is connected to the third information output of the identification module of the identification of the base address of the angles of the lords of the spine in the database of the server of the system,  the information output of the selection module in the database server of the system of addresses of the angles of lords of the lumbar spine of patients is the first address output of the system,  designed to provide addresses of the angles of the lordosis of the lumbar spine of patients to the address input of the database server,  the synchronization output of the selection module in the database server of the system of addresses of the angles of the lordosis of the lumbar spine of patients is the first synchronizing output of the system,  designed to issue control signals by reading the addresses of the angles of the lordosis of the lumbar spine of patients at the input of the first channel of the database server interrupt,  module for recording the angles of lordosis of the spine of patients,  the information input of which is the second information input of the system,  designed to receive the codes of the angles of the lordosis of the spine of patients,  read from the system server database,  the synchronizing input of the module for registering the angles of the lordosis of the spine of the patients is the second synchronizing input of the system,  designed to receive synchronization signals entering codes of the angles of the lordosis of the spine of patients,  read from the system server database,  in the module for recording angles of lordosis of the spine of patients,  selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis,  the information output of which is the second address output of the system,  designed to provide addresses of the sequence of loads on the spine to correct the angles of the lumbar lordosis to the address input of the system database server,  the synchronizing output of the module for selecting addresses of the sequence of loads on the spine for correcting the angles of the lumbar lordosis is the second synchronizing output of the system,  designed to issue control signals by reading the addresses of the sequence of loads on the spine to correct the angles of the lumbar lordosis to the input of the first channel of interruption of the system database server,  selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of cervical lordosis,  the information output of which is the third address output of the system,  designed to provide addresses of the sequence of loads on the spine to correct the angles of the cervical lordosis to the address input of the system database server,  the synchronizing output of the selection module in the database of the server system addresses the sequence of loads on the spine for correcting the angles of the cervical lordosis is the third synchronizing output of the system,  designed to issue control signals by reading the addresses of the sequence of loads on the spine to correct the angles of the cervical lordosis to the input of the second channel of the server database system interrupt,  module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis,  the information input of which is the third information input of the system,  designed to receive a sequence of loads on the spine to correct the angles of lumbar lordosis,  read from the system server database  the synchronizing input of the module for recording the sequence of loads on the spine for correcting the angles of the lumbar lordosis is the third synchronizing input of the system,  designed to receive synchronizing signals of entering a sequence of loads on the spine to correct the angles of lumbar lordosis,  read from the system server database  in the module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis,  module for recording the sequence of loads on the spine to correct the angles of cervical lordosis,  the information input of which is the fourth information input of the system,  designed to receive a sequence of loads on the spine to correct the angles of cervical lordosis,  read from the system server database  the synchronizing input of the module for recording the sequence of loads on the spine for correcting the angles of the cervical lordosis is the fourth synchronizing input of the system,  intended for receiving synchronizing signals of entering a sequence of loads on the spine to correct the angles of cervical lordosis,  read from the system server database  in the module for recording the sequence of loads on the spine to correct the angles of cervical lordosis,  module for registering SNILS-patient codes,  the information input of which is the fifth information input of the system,  intended for receiving SNILS-codes of patients from the workstation of the system user,  the synchronizing input of the registration module of the SNILS patient codes is the fifth synchronizing input of the system,  intended for receiving synchronization signals for entering SNILS-codes of patients from the workstation of a user of the system into the registration module of SNILS-codes of patients,  the information and synchronizing outputs of the registration module of the SNILS-patient codes are connected to the third information and second synchronizing inputs of the selection module in the database of the server of the address system of the angles of the lordosis of the lumbar spine of patients, respectively,  control module for completing the analysis of the array of patients,  the information input of which is connected to the fourth information output of the identification module of the base address of the angles of the lordosis of the spine in the database of the system server,  one signal output of the control module for completing the analysis of the patient array is connected to one installation input of the selection module in the database of the server system of addresses of the sequence of loads on the spine to correct the angles of cervical lordosis,  with one installation input of the selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis,  with one installation input of the selection module in the database server of the system of addresses of the angles of the lordosis of the lumbar spine of patients,  with one installation input of the module for registering the angles of the lordosis of the spine of patients,  with one installation input of the module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis,  with one installation input of the module for recording the sequence of loads on the spine to correct the angles of cervical lordosis,  with one installation input of the module for registration of SNILS-patient codes and at the same time it is the first signal output of the system,  intended for issuing to the automated workstation of the user of the system a request signal for inputting the SNILS code of the next patient,  another signal output of the control module for completing the analysis of the patient array is connected to another installation input of the selection module in the database of the server system of addresses of the sequence of loads on the spine to correct the angles of cervical lordosis,  with another installation input of the selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis,  with another installation input of the selection module in the database server of the system of addresses of the angles of the lordosis of the lumbar spine of patients,  with another installation input module registration angles of the lordosis of the spine of patients,  with the installation input of the identification module of the base address of the angles of lordosis and kyphosis of the spine in the system server database,  with another installation input module registration sequence of loads on the spine to correct the angles of lumbar lordosis,  with another installation input module registration sequence of loads on the spine to correct the angles of the cervical lordosis,  with another installation input of the module for registration of SNILS-patient codes and at the same time is the second signal output of the system,  designed to issue a signal to the user’s automated workstation to complete the analysis of the patient array,  a module for recognizing the degree of deviation of the lumbar lordosis of the spinal column of patients was introduced,  the first,  second,  third,  the fourth and fifth information inputs of which are connected to the fifth,  the sixth  the seventh  the eighth and ninth information outputs of the module identifying the base address of the angles of the lordosis of the spine in the database of the system server, respectively,  the sixth information input of the module for recognizing the degree of deviation of the lumbar lordosis of the patient’s spine is connected to the second information output of the module for identifying the base address of the angles of the lordosis of the spine in the database of the system server,  and the seventh and eighth information and synchronization inputs of the module for recognizing the degree of deviation of the lumbar lordosis of the patient’s spine are connected to the first and second information and synchronizing outputs of the module for registering the angles of the lordosis of the patient’s spine, respectively,  the first,  second and third information and the first,  the second and third synchronizing outputs of the module for recognizing the degree of deviation of the lumbar lordosis of the spine of the patients are connected to the first,  second and third information and with the first,  the second and third synchronizing inputs of the selection module in the database server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis, respectively,  the first synchronizing output of the module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the third signal output of the system,  designed to issue a signal to the user’s automated workstation about the critical degree of deviation of the patient’s lumbar lordosis,  the second synchronizing output module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the fourth signal output of the system,  designed to issue a signal to the user’s automated workstation about the average degree of deviation of the patient’s lumbar lordosis,  and the third synchronizing output of the module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the fifth signal output of the system,  designed to issue a signal to the user’s automated workstation about a small degree of deviation of the patient’s lumbar lordosis,  the fourth synchronizing output of the module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the sixth signal output of the system,  intended for the issuance of a signal on the normal state of the lumbar lordosis of the patient to the user's automated workstation,  recognition module for the degree of deviation of the cervical lordosis of the spinal column of patients,  the first,  the second and third information inputs of which are connected to the eighth,  the ninth and tenth information outputs of the module identifying the base address of the angles of the lordosis of the spine in the database server system, respectively,  and the fourth information input of the module recognizing the degree of deviation of the cervical lordosis of the patient’s spine is connected to the third information output of the module for registering the angles of the lordosis of the patient’s spine,  the synchronizing input of the recognition module of the degree of deviation of the cervical lordosis of the patient's spine is connected to the fifth synchronizing output module of the recognition of the degree of deviation of the cervical lordosis of the patient's spine,  the first,  second and third information and the first,  the second and third synchronizing outputs of the module recognizing the degree of deviation of the cervical lordosis of the spine of the patients are connected to the first,  second and third information and with the first,  the second and third synchronizing inputs of the selection module in the database server system addresses the sequence of loads on the spine to correct the angles of the cervical lordosis, respectively,  the first synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spine of patients is the seventh signal output of the system,  designed to issue a signal to the user’s automated workstation about the critical degree of deviation of the patient’s cervical lordosis,  the second synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spinal column of patients is the eighth signal output of the system,  designed to issue a signal to the user’s automated workstation about the average degree of deviation of the patient’s cervical lordosis,  and the third synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spine of the patients is the ninth signal output of the system,  designed to issue a signal to a user’s automated workstation about a small degree of deviation of the patient’s cervical lordosis,  and the fourth synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spinal column of patients is the tenth signal output of the system,  designed to issue a signal to the patient’s automated workstation about the normal condition of the patient’s cervical lordosis,  and a synchronization module issuing a sequence of loads on the spine to correct the angles of lordosis of patients,  the first information and first synchronizing inputs of which are connected to the information and synchronizing outputs of the module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis, respectively,  the second information and second synchronizing inputs of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis patients are connected to the information and synchronizing outputs of the module registering the sequence of loads on the spine for correcting the angles of the cervical lordosis, respectively,  the third synchronizing input of the synchronization module issuing a sequence of loads on the spine for correcting the angles of the patient’s lordosis is connected to the fourth synchronizing output of the module for recognizing the degree of deviation of the cervical lordosis of the patient’s spine,  and the fourth synchronizing input of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is connected to the fourth synchronizing output of the module for recognizing the degree of deviation of the lumbar lordosis of the patient’s spine,  the information output of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is the first information output of the system,  designed to issue to the user's workstation a system of a sequence of loads on the patient’s spine to correct his lordosis,  the first and second synchronizing outputs of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients are connected to the first and second synchronizing inputs of the control module completing the analysis of the patient array, respectively,  the first synchronizing output of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is the eleventh signal output of the system,  designed to issue to the user's automated workstation a signal confirming the issuance of a sequence of loads on the patient’s spine in the procedures for correcting his lordosis,  and the second synchronizing output of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is the twelfth signal output of the system,  designed to issue a signal to the patient’s spinal column to the user's workstation.

The invention is illustrated by drawings, where in FIG. 1 shows a structural diagram of an automated system for processing data of the angles of lordosis of the spinal column of patients, FIG. 2 is a structural diagram of a module for identifying the base address of the angles of the lordosis of the spine in the database of the system server, FIG. 3 is a block diagram of a module for identifying the relative address of the angles of the lordosis of the lumbar spine in the system server database; FIG. 4 is a structural diagram of a selection module in the database server of the system of addresses of the angles of the lordosis of the lumbar spine of patients, FIG. 5 is a structural diagram of a module for recognizing the degree of deviation of lumbar lordosis of the spinal column of patients; FIG. 6 is a structural diagram of a selection module in the database server of the system of addresses of the sequence of loads on the spine for correcting the angles of lumbar lordosis, FIG. 7 is a structural diagram of a module for recording angles of lordosis of the spinal column of patients; FIG. 8 is a structural diagram of a module for recognizing the degree of deviation of cervical lordosis of the spinal column of patients; FIG. 9 is a structural diagram of a selection module in a database of a server of a system of addresses of a sequence of loads on the spine for correcting the angles of cervical lordosis, FIG. 10 is a structural diagram of a module for recording a sequence of loads on the spine for correcting the angles of lumbar lordosis, FIG. 11 is a structural diagram of a module for recording a sequence of loads on the spine for correcting the angles of cervical lordosis, FIG. 12 is a structural diagram of a synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients, FIG. 13 is a structural diagram of a control module for completing a procedure for analyzing a patient array; FIG. 14 is a block diagram of a module for registering SNILS patient codes; FIG. 15 shows an example of measuring the lordosis angle of the lumbar spine directly on its tomogram.

The automated system for processing data of the angles of the lordosis of the spinal column of patients (Fig. 1) contains module 1 for identifying the base address of the angles of lordosis of the spine in the system server database, module 2 for identifying the relative address of the angles of lordosis of the lumbar spine in the system server database, and selection module 3 in the database data server system of the address of the angles of the lordosis of the lumbar spine of patients, module 4 recognition of the degree of deviation of the lumbar lordosis of the spine of patients, module 5 and in the database of the server system for addressing the load of the spine for correcting the angles of the lumbar lordosis, module 6 for recording angles of lordosis of the spinal column of the patients, module 7 for recognizing the degree of deviation of the cervical lordosis of the patient’s spine, module 8 for selection in the database of the server system of the system for addressing the load of the spine for correction angles of cervical lordosis, module 9 recording the sequence of loads on the spine to correct the angles of lumbar lordosis, module 10 registration atelnosti loads on the spine for correction of cervical lordosis angles, the synchronization unit 11 for issuing angle correction loads on the spine sequence lordosis patients, control module 12 completing patients array analysis procedure, registration module 13 patients SNILS codes.

In FIG. 1 shows the first 15, second 16, third 17, fourth 18 and fifth 19 information inputs of the system, the first 20, second 21, third 22, fourth 23 and fifth 24 synchronizing inputs of the system, as well as address 25-27, information 28, synchronizing 29 -31 and signal 32-43 system outputs.

The module 1 for identifying the base address of the angles of the lordosis of the spine in the system server database (Fig. 2) contains a register 50, a decoder 51, a memory module 52 made in the form of read-only memory (ROM), elements 53-55 I, elements 56-57 delay . The drawing also shows information 58, synchronizing 59 and installation 60 inputs, information 71-80 and synchronizing 81 outputs.

The module 2 for identifying the relative address of the angles of the lordosis of the lumbar spine in the system server database (Fig. 3) contains a decoder 85, a memory module 86, made in the form of read-only memory (ROM), adder 87, elements 88-90 I, elements 91- 92 delays. The drawing also shows information 93-94 and synchronizing 95 inputs, information 96 and synchronizing 97 outputs.

The selection module 3 in the database server of the system of addresses of the angles of the lords of the lumbar spine of patients (Fig. 4) contains a register 100, a decoder 101, a memory module 102, made in the form of read-only memory (ROM), adder 103, elements 104-106 And, OR elements 107-108, a group of OR elements 109, and delay elements 110-112. The drawing also shows information 113-115, synchronizing 116-117 and installation 118-119 inputs, information 120 and synchronizing 121 outputs.

Module 4 recognizing the degree of deviation of the lumbar lordosis of the spinal column of patients (Fig. 5) contains comparators 125-130 and elements 131-132 OR. The drawing also shows information 133-140 and synchronizing 141 inputs, information 143-145 and synchronizing 146, 148, 150, 156 and 157 outputs.

The selection module 5 in the database server system addresses the sequence of loads on the spine for correcting the angles of the lumbar lordosis (Fig. 6) contains a register 158, a decoder 159, a memory module 160, made in the form of read-only memory (ROM), elements 161-163 And, OR elements 164-165, a group of 166 OR elements, and delay elements 167-169. The drawing also shows information 170-172, synchronizing 173-175 and installation 176-177 inputs, information 178 and synchronizing 179 outputs.

Module 6 registration of the angles of the lordosis of the spine of patients (Fig. 7) contains registers 180-182, element 183 OR, elements 184-185 delay. The drawing also shows informational 186, synchronizing 187 and installation inputs 188-189, informational 192-194 and synchronizing 195 outputs.

Module 7 recognition of the degree of deviation of the cervical lordosis of the spinal column of patients (Fig. 8) contains comparators 200-202. The drawing also shows information 203-206 and synchronizing inputs 207, information 208-210 and synchronizing outputs 211, 213, 215 and 216.

The selection module 8 in the database of the server system addresses the sequence of loads on the spine for correcting the angles of the cervical lordosis (Fig. 9) contains a register 220, a decoder 221, a memory module 222, made in the form of read-only memory (ROM), elements 223-225 And, OR elements 226-227, a group of 228 OR elements, and delay elements 229-231. The drawing also shows information 232-234, synchronizing 235-237 and installation 238-239 inputs, information 240 and synchronizing 241 outputs.

Module 9 recording a sequence of loads for correcting the angles of lumbar lordosis (Fig. 10) contains a register 250, an OR element 251, an element 252 delay. The drawing also shows information 253, synchronizing 254 and installation inputs 255-256, information 257 and synchronizing 258 outputs.

Module 10 recording a sequence of loads for correcting the angles of the cervical lordosis (Fig. 11) contains a register 260, an OR element 261, a delay element 262. The drawing also shows information 263, synchronizing 264 and installation inputs 265-266, information 267 and synchronizing 268 outputs.

The synchronization module 11 for issuing a sequence of loads on the spine for correcting the angles of lordosis of patients (Fig. 12) contains a comparator 270, elements 271-276 AND, groups 277-280 elements I. Elements 281-282 OR, groups 283-284 OR elements 285 delays. The drawing also shows information 288-289, synchronizing 290-293 inputs, information 294 and synchronizing 295-296 outputs.

The module 12 for monitoring the completion of the analysis procedure for the patient array (Fig. 13) contains a counter 300, a comparator 301, an OR element 302, a delay element 303. The drawing also shows information 304 and counting 305-306 inputs, signal 310-311 outputs.

Module 13 registration SNILS-patient codes (Fig. 14) contains a register 320, an element OR 321, element 322 delay. The drawing also shows information 323, synchronizing 324 and installation 325-326 inputs, information 327 and synchronizing 328 outputs.

All nodes and elements of the system are made on standard potential-impulse elements.

A remote workstation (AWP) of a system user consists of a terminal having a screen for displaying codograms of requests and system signals, and a personal computer keyboard. Presentation of readable angles of lordosis of the spinal column of patients, load sequences for the correction of his lordosis are controlled from the system database server (not shown in the drawing).

The system operates as follows.

The claimed technical solution of the problem is based on processing the codes of the lordosis angles of the lumbar and cervical spine of the patients who underwent an MRI examination of the spine, which are read from the server database.

The spine in the system has its own identification code, which corresponds to the address of the server database memory, called the base, starting from which the system codes of the lordosis of its departments are stored in the system server database memory, for each of which its own area is allocated in the server database memory, whose address, called relative, is offset from the base address of the spine by a certain amount corresponding to the code of the vertebral spine.

In turn, in the address space of the relative address of the lumbar spine, the addresses of the lordosis angles of the lumbar patients are distributed. The offset of the lordosis angle of the lumbar spine of each requested patient relative to the relative address of the lumbar spine corresponds to the SNILS code of this patient.

This means that according to the SNILS code of the requested patient, the system determines the offset of the lordosis angle of the lumbar spine of this patient, which, summing up with the relative address of the lumbar spine of this patient, forms the address of the lordosis angle of the lumbar spine of this patient in the database of the system server, issued to the address database server login.

The server at the address at its address input reads from the memory of its database the code of the lordosis angle of the lumbar spine of the patient and sends it to the information input of the system for analysis and processing.

A feature of building a database of lordosis angles of patients who underwent an MRI examination in the system server database is that the SNILS code of one patient identifies simultaneously the angles of the lumbar and cervical lordosis. Therefore, the lordosis angle code of the patient’s lumbar region, read from the system server’s database, is divided into two components: the lordosis angle code of the lumbar region and the lordosis angle code of the patient’s cervical spine, which determine and specify two parallel channels for their processing.

In each of the channels, the degree of deviation of the lordosis angle from the norm is recognized and the memory address of the server database is determined, from which the sequence of loads on the spine is read for procedures for underwater correction of the revealed degree of deviation of the angle of lordosis. Of the read sequences of loads, the largest one is selected, which is issued to the user's workstation for performing lordosis correction procedures.

If only one of the lordoses of the patient in question has a degree of deviation, then a sequence of loads read out to correct a lordosis with a degree of deviation is issued to the user's workstation.

If the lordoses of the lumbar and cervical spine of the patient are normal, then a signal about the normal condition of the patient's spine is issued to the user's workstation.

After that, the system first fixes the moment of completion of the analysis and processing of the lordosis of the current patient, and then checks the completion of the analysis and processing of the patient array specified by the initial codogram of the processing request.

If the number of treated patients is less than the number of patients assigned to the system for processing, then the system issues a request to enter the SNILS code of the next patient. If the number of treated patients becomes equal to the number assigned to the system for processing, the system returns to its original state and ends its work.

To start the system, the user at his workplace generates a request codogram, which indicates: the code of the spine, the code of the lumbar spine, the code of the insurance certificate of the first patient requested (SNILS - code), the code of the number of patients requested, as well as the codes of the borders of the ranges of angles of the degree of deviation of lordosis spine in degrees (table 1).

The generated code from the automated workstation of the user of the system is fed to the information input 15 of the system, fed to the information input 58 of module 1 for identifying the base address of the angles of the lordosis of the spine in the database of the server of the system and entered into the register 50 by a synchronizing pulse supplied to the synchronizing input 59 of module 1 from the synchronizing input 20 of the system.

The code of the spine from the output 61 of the register 50 is fed to the input of the decoder 51. The decoder 51 decodes the code of the spine and generates at one of its outputs a high potential arriving at the corresponding inputs of the elements 53-55 I. For definiteness, we assume that the high potential from the output of the decoder 51 will be open element 55 And one input.

In this case, the synchronizing pulse from the input 20 of the system, arriving at the synchronizing input 59 of module 1, is delayed by the delay element 56 for the response time of the register 50 and the decoder 51 and enters through the element 55 open through one input and to the read input of a fixed cell of a permanent storage device (ROM) ) 52.

In a fixed cell of ROM 52, the code of the base address of the spine is stored in the database of the system server, starting from which the codes of the angles of the lordosis of its departments are stored in the memory of the database of the system server, for each of which a separate area is allocated in the memory of the server database, whose address is offset from spinal addresses by a certain amount corresponding to the code of the spine.

Therefore, the lumbar spine code requested by the codogram from the output 72 of module 1 is sent to the information input 93 of the module 2 for identifying the relative address of the lordosis angles of the lumbar spine in the system server database and is fed to the input of the decoder 85. The decoder 85 decodes the lumbar spine code and generates one from its outputs a high potential arriving at the corresponding inputs of the elements 88 - 90 I. For definiteness, we assume that the high potential from the output of the decoder 85 element 90 will be opened And one input.

In this case, the synchronizing pulse from the output of the delay element 56 of the module 1, delayed by the delay element 57 for the time of reading the contents of the fixed cell ROM 52 of the module 1 and the operation of the decoder 85 of the module 2, from the output 81 of the module 1 is sent to the synchronizing input 95 of the module 2 and comes through the open one input element 90 And to the reading input of a fixed cell of a permanent storage device (ROM) 86. In a fixed cell ROM 86 is stored code offset address angles of the lordosis of the lumbar spine relative about the base address of the spine in the system server database.

The code for shifting the address of the angles of the lordosis of the lumbar spine, read from ROM 86, is supplied to one information input of the adder 87, to the other information input 94 of which the code of the base address of the spine is supplied to the database of the system server from the information output 71 of module 1.

According to the synchronizing pulse at the input 95 of module 2, delayed by the delay element 91 for the time of reading the fixed cell of the ROM 86, in the adder 87, the relative address of the angles of the lordosis of the lumbar spine is formed in the system server database.

The code for the relative address of the angles of the lordosis arches of the lumbar spine formed in the adder 87 in the system server database is also a “base” address for storing the angles of the lordosis arches of the lumbar spine in the system server database for all patients who underwent MRI examination of the lumbar spine. It is with respect to this address that the addresses of the angles of the lordosis arches of the lumbar spine of each patient are shifted. The magnitude of the offset address of the angles of the angles of the lordosis of the lumbar spine of the patient relative to this relative address corresponds to the code of his insurance number of the individual personal account (SNILS).

To determine this bias, the SNILS code of the first patient requested is sent from the information output 73 of module 1 to the information input 113 of module 3 for selecting the address of the lordosis angles of the lumbar spine of the patients in the system server database, passes through the OR elements of group 109 and is fed to the input of the decoder 101. The decoder 101 decrypts the SNILS - code of the first requested patient and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 104-106 I. For certainty, the tolerance Thus, with a high potential, the element 105 And at one input will be open from the output of the decoder 101.

In this case, the synchronizing pulse from the output of the delay element 91 of the module 2, delayed by the delay element 92 for the duration of the operation of the adder 87 of the module 2 and the decoder 101 of the module 3 and applied from the synchronizing output 97 of the module 2 to the synchronizing input 116 of the module 3, passes through the element 107 OR through the element 105 And opened at one input, to the read input of a fixed cell of a permanent storage device (ROM) 102. In a fixed cell of a ROM 102, a code for shifting the address of the lordosis angle of the lumbar spine is stored in a database with rvera of the system of the patient, SNILS - the code which has been submitted to the decoder input 101 with data input module 113 3.

The code for shifting the address of the lordosis angle of the lumbar spine of the patient read from the ROM 102 in the system server database is fed to one information input of the adder 103, the other information input 115 of which is the code for the relative address of the lordosis angles of the lumbar spine of the patients in the system server database from the information output 96 modules 2.

By the synchronizing pulse from the output of the element 107 OR module 3, delayed by the delay element 110 for the time of reading the fixed cell ROM 102, the adder 103 generates a relative storage address in the server database of the lordosis angle code of the lumbar spine of the patient corresponding to its SNILS code.

The system server database address generated in the adder 103, containing the lordosis angle code of the lumbar spine of the requested first patient, is fed to the information input of the register 100, where it is entered by the synchronizing pulse from the output of the delay element 110 after the delay by the delay element 111 for the response time of the adder 103.

The same pulse from the output of the delay element 111 is delayed by the delay element 112 for the time of entering the register of the lordosis angle code of the lumbar spine of the first requested patient into the register 100, which is issued to the address output 25 of the system, and from the output 29 of the system is input to the first channel of the server interrupt.

With the arrival of this impulse, the server switches to a subprogram for polling the contents of its database at the address generated on the address output 25 of the system and issuing the lordosis angle code of the lumbar spine of the first patient requested to the system information input 16.

The code of the lordosis of the lumbar spine of the first requested patient, read from the system server’s database, from the information input 16 of the system goes to the information input 186 of register 180 of module 6 for registering the angles of the lordosis of the patient’s spine, where it is entered by the server’s synchronizing pulse received at synchronizing input 187 from the synchronizing input 21 systems.

The angle code of the lordosis of the lumbar spine of the requested patient adopted in register 180 has the following structure:

The lordosis angle code of the patient’s lumbar spine from the output 190 of the register 180 is fed to the information input of the register 181, and the lordosis angle code of the patient’s cervical spine from the output 191 of the register 180 is fed to the information input of register 182, where the server’s synchronizing pulse coming from the synchronizing input is entered 21 of the system to the synchronizing inputs of the registers 181 and 182 after the delay by the delay element 184 for the time of entering the lordosis angle code of the lumbar spine of the patient into the register 180 of module 6.

The structure of the actual lordosis angle code of the lumbar spine of the patient, adopted in the register 181 of module 6, consists of two fields:

The sign code of the lumbar spine from the output 192 of module 6 is fed to the information input 138 of the comparator 127 of the module 4 for recognizing the degree of deviation of the lordosis of the lumbar spine of patients, and to the other information input 137 of which is the code of the lumbar spine from the information output 72 of module 1.

According to the synchronizing pulse from the output of the delay element 184, delayed by the delay element 185 for the time of entering the lordosis angle codes of the lumbar and cervical spine of the patient into the registers 181 and 182, respectively, and applied from the synchronizing output 195 of module 6 to the synchronizing input 141 of comparator 127 of module 4, in the comparator 127 is a comparison of the codes received at its information inputs.

Since the sign code of the lumbar spine is equal to the code of the lumbar spine, then, therefore, the codes at the inputs of the comparator 127 are the same. In this case, a signal is generated at the output 142 of the comparator 127, which is supplied both to the synchronizing input of the comparator 125 of module 4, starting the procedure for recognizing the degree of deviation of the lordosis of the lumbar spine of the patient, and from the synchronizing output 157 of module 4 to the synchronizing input 207 of the comparator 200 of the recognition module 7 the degree of deviation of lordosis of the cervical spine of patients, starting the procedure for recognizing the degree of deviation of lordosis of the cervical spine of the patient.

The comparator 125 compares the angle code of the lumbar lordosis of the patient supplied to its information input 134 from the information output 193 of module 6 with the angle code 10 ° of the critical degree of deviation of the lumbar lordosis supplied to its information input 133 from the information output 75 of module 1.

If the angle code of the patient’s lumbar lordosis is less than or equal to 10 °, then the output 6 146 of the comparator 125 generates a signal “Critical degree of deviation of the lumbar lordosis of the patient”, which is output from the output 146 of the comparator 125 to the signal output 40 of the system and then sent to the automated workstation (AWP ) system user.

If the angle code of the patient’s lumbar lordosis is greater than 10 °, a signal is generated at the output 147 of the comparator 125. This signal from the output 147 of the comparator 125 is supplied to the synchronizing input of the comparator 126 and allows the comparison of the angle code of the patient’s lumbar lordosis received at the information input 134 of module 4, with the angle code of the average degree of deviation of the lumbar lordosis, equal to 15 °, and received at its information input 135 from the information output 76 of module 1.

If the angle code of the patient’s lumbar lordosis is less than or equal to 15 °, then the output "average degree of deviation of the patient’s lumbar lordosis" is generated at the output 148 of the comparator 126. This signal from the output 148 of the comparator 126 is issued to the signal output 41 of the system and then sent to the automated workstation (AWP) of the user of the system.

If the angle code of the patient’s lumbar lordosis is greater than 15 °, the signal is generated at the output 149 of the comparator 126. This signal from the output 149 of the comparator 126 is fed to the synchronizing input of the comparator 128 and allows the comparison of the angle code of the patient’s lumbar lordosis received at the information input 134 of module 4, with an angle code of 18 ° of a small degree of deviation of the lumbar lordosis, received at its information input 136 from the information output 77 of module 1.

If the angle code of the patient’s lumbar lordosis is less than or equal to 18 °, then at the output of 150 comparator 128 the signal “Small degree of deviation of the patient’s lumbar lordosis” is generated. This signal from the output 150 of the comparator 128 is issued to the signal output 42 of the system and then sent to the workstation (AWP) of the user of the system.

If the angle code of the patient’s lumbar lordosis is greater than 18 °, a signal is generated at the output 151 of the comparator 128. This signal from the output 151 of the comparator 128 is supplied to the synchronizing input of the comparator 129 and allows the comparison of the angle code of the patient’s lumbar lordosis received at the information input 134 of module 4, with the angle code of the lower boundary of the normal state of the lumbar lordosis, equal to 20 °, and received at its information input 139 from the information output 78 of module 1.

If the angle code of the patient’s lumbar lordosis is 20 °, the signal is generated at the output 152 of the comparator 129. If the angle code of the patient’s lumbar lordosis is greater than 20 °, the signal is generated at the output 153 of the comparator 128.

Each of these signals from the outputs 152 and 153 of the comparator 129 passes through the OR element 131, arrives at the synchronizing input of the comparator 130 and allows the comparison of the angle code of the patient's lumbar lordosis received at the information input 134 of module 4 with the angle code of the upper boundary of the normal state of the lumbar lordosis, equal to 30 °, and fed to its information input 140 from the information output 80 of module 1.

If the angle code of the patient’s lumbar lordosis is less than 30 °, the signal is generated at the output 154 of the comparator 130. If the angle code of the patient’s lumbar lordosis is 30 °, the signal is generated at the output of the comparator 130. Each of these signals passes through the OR element 132 and from the synchronizing output 156 of module 4 is removed by the signal "Normal condition of the lumbar lordosis of the patient", issued to the signal output 32 of the system and then sent to the workstation (AWP) of the user of the system.

At the same time, the comparator 200 of module 7, working in parallel, compares the angle code of the cervical lordosis of the patient fed to its information input 204 from the information output 194 of module 6, with the angle code of the critical degree of cervical lordosis deviation equal to 20 ° and supplied to it information input 203 from information output 78 of module 1.

If the angle code of the patient’s cervical lordosis is less than or equal to 20 °, then the signal “Critical degree of deviation of the patient’s cervical lordosis” is generated at the output 211 of the comparator 200. This signal from the output 211 of the comparator 200 is issued to the signal output 37 of the system and then sent to the automated workstation (AWP) of the user of the system.

If the angle code of the patient’s cervical lordosis is greater than 20 °, a signal is generated at the output 212 of the comparator 200. This signal from the output 212 of the comparator 200 is fed to the synchronizing input of the comparator 201 and allows the comparison of the angle code of the patient’s cervical lordosis received at one of its information inputs 204 s information output 194 of module 6, with an angle code of 30 ° of an average degree of cervical lordosis deviation, and received at its other information input 205 from information output 80 of module 1.

If the angle code of the patient’s cervical lordosis is less than or equal to 30 °, then the signal “Average degree of deviation of the patient’s cervical lordosis” is generated at the output 213 of the comparator 201. This signal from the output 213 of the comparator 201 is issued to the signal output 39 of the system and then sent to the workstation (AWP) of the user of the system.

If the angle code of the patient's cervical lordosis is greater than 30 °, then the signal is generated at the output 214 of the comparator 201. This signal from the output 214 of the comparator 201 is fed to the synchronizing input of the comparator 202 and allows the comparison of the code of the angle of the cervical lordosis of the patient received at one of its information inputs 204 s information output 194 of module 6, with a 40 ° angle code of a small degree of deviation of the cervical lordosis, received at its other information input 206 from information output 79 of module 1.

If the angle code of the patient's cervical lordosis is less than 40 °, then the output 215 of the comparator 202 generates a signal "Small degree of deviation of the cervical lordosis of the patient." This signal from the output 215 of the comparator 202 is issued to the signal output 38 of the system and then sent to the automated workstation (AWP) of the system user.

If the angle code of the patient’s cervical lordosis is equal to 40 °, then the signal is generated at the output 216 of the comparator 202. This signal is output from the output 216 of the comparator 202 by the signal “Normal state of the cervical lordosis of the patient”, issued to the signal output 33 of the system and to the workstation (AWP ) system user.

Further, the system continues parallel processing of the angles of the lumbar and cervical lordoses with the revealed degrees of deviations in order to establish the sequence of loads on the patient's spine to correct the angles of his lordoses. For this, the angle codes of the lumbar lordosis of the patient from the information outputs 143-145 of module 4 are sent to the information inputs 170-172 of the module 5 for identifying the sequence of loads on the spine to correct deviations of the lumbar lordosis, respectively, and the angle codes of the cervical lordosis of the patient from the information outputs 208-210 of module 7 are sent to the information inputs 232-234 module 8 identification of the sequence of loads on the spine to correct deviations of the cervical lordosis, respectively.

In addition, the pulses of tracking the issued codes of the angles of the lumbar lordosis of the patient from the synchronizing outputs 146, 148 and 150 of module 4 are sent to the synchronizing inputs 173-175 of the module 5, respectively, and the pulses of tracking the issued codes of the angles of the cervical lordosis of the patient from the synchronizing outputs 211, 213 and 215 to the synchronizing inputs 235-237 of module 8, respectively.

In this case, the angle code of the lumbar lordosis with a critical degree of deviation from the information output 143 of module 4 is sent to the information input 170 of module 5, the angle code of the lumbar lordosis with an average degree of deviation from the information output 144 of module 4 is sent to the information input 171 of module 4, and the code of the angle of the lumbar lordosis with a small degree of deviation from the information output 145 of module 4 is sent to the information input 172 of module 5.

In turn, the cervical lordosis angle code with a critical degree of deviation from the information output 208 of module 7 is sent to the information input 232 of module 8, the cervical lordosis angle code with an average degree of deviation from the information output 208 of module 7 is sent to the information input 233 of module 7, and the code angle of the cervical lordosis with a small degree of deviation from the information output 210 of module 7 is sent to the information input 234 of module 8.

Next, each of the angle codes of the lumbar lordosis passes through the OR elements of group 166 and enters the input of the decoder 159. The decoder 159 decodes the angle code of the lumbar lordosis of the patient’s spine and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 161-163 I.

In parallel with this, each of the cervical lordosis angle codes passes through the OR elements of group 228 and enters the input of the decoder 221. The decoder 221 decodes the cervical lordosis angle code of the patient’s spine and generates a high potential at one of its outputs that goes to the corresponding inputs of the elements 223-225 AND .

Suppose that the decoder 159 received from the information input 170 of module 5 the angle code of the lumbar lordosis with a critical degree of deviation. Decoder 159 decrypts the angle code of the patient’s lumbar lordosis with a critical degree of deviation and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 161-163 I. For definiteness, suppose that element 161 And will be opened from the output of decoder 159 with high potential one input, waiting for a pulse to arrive at one of the synchronizing inputs 173-175 of module 5 at the other input.

The pulse of tracking the angle code of the lumbar lordosis with a critical degree of deviation is the signal generated from the output 146 of the comparator 125 of module 4. This pulse from the output 146 of the comparator 125 of module 4 is sent to the synchronizing input 173 of module 5, passes through the element 164 OR, is delayed by the element 167 of the delay the response time of the decoder 159 and passes through the element 161 And open at one input to the read input of a fixed cell of read-only memory (ROM) 160. An address code is stored in a fixed cell of ROM 160 ase data server system, comprising code sequences loads on the spine for correction of the critical degree of deviation of the lumbar lordosis of the spine of the patient.

The code from the ROM 160 for the address of the system server database containing the sequence of loads on the spine to correct the critical degree of deviation of the lumbar lordosis is fed to the information input of the register 158, where it is entered by the synchronizing pulse from the output of the delay element 167, the delayed element 168 of the delay for the reading time is fixed ROM cells 160.

The same pulse from the output of the delay element 168 is delayed by the delay element 169 for the time in which the code of the system server database address code is entered into the register 158, containing a sequence of loads on the spine to correct the degree of deviation of the lumbar lordosis, issued to the address output 26 of the system, and from the system output 30 to the input of the first channel of the system database server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 26 of the system and issuing a code for the sequence of loads on the spine to correct the degree of deviation of the lumbar lordosis to the information input 17 of the system.

In turn, suppose that the code of the cervical lordosis angle with an average degree of deviation was received at the input of the decoder 221 of module 8 from the information input 233 of module 8. Decoder 221 decodes the angle code of the cervical lordosis of the patient's spine with an average degree of deviation and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 223-225 I. For definiteness, suppose that element 224 And will be opened from the output of decoder 221 with high potential one input, waiting for a pulse to arrive at one of the synchronizing inputs 235-237 of module 8 at the other input.

The pulse of tracking the cervical lordosis angle code with an average degree of deviation is the signal issued from the output 213 of the comparator 201 of the module 7. This pulse from the output 213 of the comparator 201 of the module 7 is sent to the clock input 236 of the module 8, passes through the OR element 226, is delayed by the delay element 229 by the response time of the decoder 221 and passes through the element 224 open to one input and to the read input of a fixed cell of a read-only memory device (ROM) 222. In a fixed cell of the ROM 222, the base address code is given system server containing the code of the sequence of loads on the spine to correct the average degree of deviation of the cervical lordosis of the patient's spine.

The code from the ROM 222 for the system server database address code containing a sequence of loads on the spine to correct the average degree of deviation of the cervical lordosis is fed to the information input of register 220, where it is entered by the synchronizing pulse from the output of the delay element 229, delayed by the delay element 230 for the reading time, fixed ROM cells 222.

The same pulse from the output of the delay element 230 is delayed by the delay element 231 for the time the system code of the database server address code is entered into the register 220, containing a sequence of loads on the spine to correct the degree of deviation of the cervical lordosis, issued to the address output 27 of the system, and from the output of the system 31 to the input of the second channel of the system database server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 27 of the system and issuing a code of the sequence of loads on the spine to correct the degree of deviation of the cervical lordosis to the information input 18 of the system.

The code of the sequence of loads on the spine to correct the degree of deviation of the lumbar lordosis from the information input 17 of the system is fed to the information input of the register 250 of the module 9 for recording the sequence of loads for correction of the lumbar lordosis, where it is entered by the synchronizing pulse of the server fed to the synchronizing input 22 of the system.

The same synchronizing pulse from the input 254 of module 9 is delayed by the delay element 252 for the response time of the register 250 and from the synchronizing output 258 of module 9 is fed to the synchronizing input 290 of the synchronization module 11 for issuing a load sequence for correction of lordosis and opens the elements 271 and 273 of one input.

At the same time, the code of the sequence of loads on the spine to correct the degree of deviation of the cervical lordosis from the information input 18 of the system is supplied to the information input of the register 260 of the module 10 for recording the sequence of loads for the correction of cervical lordosis, where it is entered by the synchronizing pulse of the server fed to the synchronizing input 23 of the system.

The same synchronizing pulse from the input 264 of the module 10 is delayed by the delay element 262 for the response time of the register 260 and from the synchronizing output 268 of the module 10 is supplied to the synchronizing input 291 of the module 11 and opens AND elements 275 through one input.

In addition, the same pulse from the synchronizing input 291 passes through the element 273 And open at one input, and arriving at the synchronizing input of the comparator 270, it allows the operation of comparing codes at its information inputs.

At one information input 288 of the comparator 270 from the information output 257 of module 9, a load sequence code for correction of the lumbar lordosis is fed, and at another information input 289 of the comparator 270 from the information output 267 of module 10, a load sequence code for correction of the cervical lordosis is fed.

If the code of the load sequence for the correction of lumbar lordosis at the information input 288 of the comparator 270 is larger and equal to the code of the sequence of loads for the correction of cervical lordosis at its information input 289, then the output 286 of the comparator 270 produces a signal that opens the And 272 element via one input.

In this case, the synchronizing pulse from the output of the And element 273, delayed by the delay element 285 for the response time of the comparator 270, passes through the And element 272 open at one input and passes the load sequence code for lumbar correction received from the information input 288 of the module 11 through the And elements of group 278 lordosis, which, passing through the OR elements of groups 283 and 284, passes to the information output 294 of module 11 and then from the information output 28 of the system is issued to the user's workstation.

The issuance of a code for the sequence of loads on the spine in the procedures for correcting its lordosis is accompanied by a signal “The sequence of loads on the spine of the patient in the procedures for correcting its lordoses”, which is removed from the output of element 272 AND, sequentially passes through elements 281 and 282 OR, and goes to the synchronizing output 295 of module 11 and from the signal output 34 of the system is issued to the user workstation of the system.

If the code of the sequence of loads on the spine for correction of lumbar lordosis at the information input 288 of comparator 270 is less than the code of the sequence of loads on the spine for correction of cervical lordosis at its information input 289, then in this case a signal is generated at the output 287 of comparator 270 and one input is opened already element 274 I.

In this case, the synchronizing pulse from the output of the delay element 285 now passes only through the And 274 element open through one input and passes through the And group 279 elements the sequence code of the loads on the spine received from the information input 289 of the module 11 to correct the cervical lordosis, which, passing through the elements OR groups 283 and 284, passes to the information output 294 of the module 11 and then from the information output 28 of the system is issued to the user's workstation.

The tracking signal issued to the user’s AWP of the system of loadings on the spine in the procedures for correcting its lordosis is now removed from the output of the element 274 AND, sequentially passes through the elements 281 and 282 OR, is fed to the synchronizing output 295 of the module 11 and is issued from the signal output 34 of the system to AWP of the system user in the form of a signal “Sequence of loads on the patient’s spine in the procedures for correcting his lordosis”.

Each signal from the synchronizing output 295 of module 11 is supplied to the synchronizing input 305 of the module 12 for monitoring the completion of the analysis of the patient array, the OR element 302 passes and enters the counting input of the counter 300 and increments it, thereby fixing the moment of completion of processing of the lordosis angles of the spine of the first patient.

The counter 300 counts on an accrual basis the total number of patients received and processed, each time outputting its contents to one information input of the comparator 301, to the other information input 304 of which from the information output 74 of module 1 a code is received for the total number of all requested patients to be processed in the system.

Since the counter 300 currently recorded the completion of processing only the first patient, therefore, its contents supplied to one information input of the comparator 301 will be much less than the code of the total number of all requests for processing in the patient system, supplied to its other information input 304 from the information output 74 module 1.

In this case, a signal is generated at the output 308 of the comparator 301, which is output from the output 310 of the module 12:

- to the installation input 118 of module 3, the OR element 108 passes and enters the installation input of the register 100, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 176 of module 5, the OR element 165 passes through and enters the installation input of the register 158, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 238 of module 8, the OR element 227 passes and enters the installation input of the register 220, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 188 of module 6, the OR element 183 passes and enters the installation input of the register 180, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 255 of module 9, the OR element 251 passes and enters the installation input of the register 250, resets its contents to zero and thereby prepares it for a new operation cycle.

- to the installation input 265 of the module 10, the OR element 261 passes and enters the installation input of the register 260, resets its contents to zero and thereby prepares it for a new operation cycle.

- to the installation input 325 of module 13, the OR element 321 passes and enters the installation input of register 320, resets its contents to zero and thereby prepares it for a new operation cycle.

The same signal from the output 310 of the module 12 is removed in the form of a request signal “Enter the SNILS code of the next patient”, which is issued from the signal output 35 of the system to the user's workstation.

Having received this request, the user of the system from his workplace sends the SNILS code of the next patient to the information input 19 of the system, from where he enters the information input 323 of register 320 of module 13, where it is entered by the synchronizing pulse received at the synchronizing input 324 of module 13 from the synchronizing input 24 systems.

The received SNILS - code for the next patient from the information output 327 of module 13 is sent to the information input 114 of module 3, passes through the OR elements of group 109 and goes to the input of the decoder 101. The decoder 101 decrypts the SNILS - code of the next patient and generates high potential at one of its outputs arriving at the corresponding inputs of elements 104-106 I. For definiteness, suppose that a high potential from the output of the decoder 101 will open the element 106 And one input.

The impulse to start a new cycle of processing the SNILS code of the next patient is a synchronizing pulse at the synchronizing input 324 of module 13, which is delayed by the delay element 322 for the response time of register 320 of module 13 and from the synchronizing output 328 of module 13 is supplied to the synchronizing input 117 of module 3, passes through the element 107 OR and through the AND element 106 open to one input and to the read input of a fixed cell of read-only memory (ROM) 102. In a fixed cell of ROM 102, the address offset code is stored in AZE system server data of the angle of lordosis of the lumbar spine next patient, SNILS - the code which has been submitted to the decoder input 101 with data input module 114 3.

The address offset code read from ROM 102 in the database database of the server of the lordosis angle system of the lumbar spine of the next patient is fed to one information input of the adder 103, to the other information input 115 of which is the code of the relative address of the angles of lordosis of the lumbar spine of the patients in the database of the system server from the information output 96 of module 2.

According to the synchronizing pulse from the output of the element 107 OR module 3, delayed by the delay element 110 for the time of reading the fixed cell ROM 102, the adder 103 generates the relative storage address in the server database of the lordosis angle code of the lumbar spine of the next patient corresponding to its SNILS code .

The system server database address generated in the adder 103, containing the lordosis angle code of the lumbar spine of the next patient, is fed to the information input of the register 100, where it is entered by the synchronizing pulse from the output of the delay element 110 after the delay by the delay element 111 for the operation time of the adder 103.

The same pulse from the output of the delay element 111 is delayed by the delay element 112 for the time of entering the code of the address of the lordosis angle of the lumbar spine of the next patient into the register 100, which is issued to the address output 25 of the system, and from the output 29 of the system is fed to the input of the first server interrupt channel.

With the arrival of this impulse, the server switches to the subprogram for interrogating the contents of its database at the address generated at the address output 25 of the system and issuing the lordosis angle code of the lumbar spine of the next patient to the information input 16 of the system.

The code of the lordosis angle of the lumbar spine of the next patient, read from the system server’s database, from the information input 16 of the system goes to the information input 186 of register 180 of module 6, where it is entered by the server’s synchronizing pulse, which arrives at the synchronizing input 187 from the synchronizing input 21 of the system.

The lordosis angle code of the lumbar spine of the next patient from the output 190 of the register 180 is fed to the information input of the register 181, and the lordosis angle code of the cervical spine of the next patient from the output 191 of the register 180 is fed to the information input of the register 182, where they are entered by the server synchronizing pulse received from the synchronizing input 21 of the system to their synchronizing inputs after the delay by the delay element 184 for the time of entering the lordosis angle code of the lumbar spine of the next patient into the 180 mode register I have 6 to 16 data input system.

The sign code of the lumbar spine from the output 192 of module 6 is fed to the information input 138 of the comparator 127 of module 4, and to another information input 137 of which the code of the lumbar spine is sent from the information output 72 of module 1.

According to the synchronizing pulse from the output of the delay element 184 of module 6, delayed by the delay element 185 for the time of entering the lordosis angle codes of the lumbar and cervical spine of the patient into the registers 181 and 182, respectively, and supplied from the synchronizing output 195 of module 6 to the synchronizing input 141 of the comparator 127 of module 4, comparator 127 compares the codes received at its information inputs.

Since the sign code of the lumbar spine is equal to the code of the lumbar spine, then, therefore, the codes at the inputs of the comparator 127 are the same. In this case, a signal is generated at the output 142 of the comparator 127, which is supplied both to the synchronizing input of the comparator 125 of module 4, starting the procedure for recognizing the degree of deviation of the lordosis of the lumbar spine of the patient, and from the synchronizing output 157 of module 4 to the synchronizing input 207 of the comparator 200 of module 7, starting the procedure for recognizing the degree of deviation of the lordosis of the cervical spine of the patient.

Before the recognition of the degrees of deviation of the lordosis of the spine of the next patient and the selection of the sequence of loads on the patient’s spine for the procedures for correcting his lordosis, we formulate a task for the system and show how the system solves the problem.

Let the angle of the lumbar lordosis of the next patient be 17 °, the code of which from the information output 193 of module 6 is fed to the information input 134 of comparators 125, 126, 128-130 of module 4, and the angle of the cervical lordosis is 40 °, the code of which is from the information output 194 of module 6 fed to the information input 204 of the comparators 200-202 module 7.

The task of the system is to recognize the degree of deviation of each lordosis and to select the sequence of loads on the spine for the procedures for correcting its lordosis.

Consider the phased work of module 7 in recognizing the degree of deviation of the cervical lordosis angle, triggered by the input to the synchronizing input 207 of module 7 from the synchronizing output 157 of module 4 of the synchronizing pulse, by which the comparison of codes on the information inputs of the comparator 200 of module 7 begins.

Step 1. The comparator 200 compares the 40 ° angle code of the cervical lordosis of the patient at its information input 204 with the 20 ° angle code of the critical degree of cervical lordosis deviation at its information input 203, obtained from the information output 78 of module 1. If the patient’s cervical lordosis angle code is larger 20 °, the signal is generated at the output 212 of the comparator 200.

In our case, at the information input 204 of the comparator 200 is the angle code of the patient's cervical lordosis, equal to 40 °, which is larger than the angle code 20 ° of the critical degree of deviation of the cervical lordosis at the information input 203 of this comparator. Therefore, the output 212 of the comparator 200 will generate a signal supplied to the clock input of the comparator 201.

Step 2. The comparator 201 compares the 40 ° angle code of the cervical lordosis of the patient at its information input 204 with the 30 ° angle code of the average degree of cervical lordosis deviation at its information input 205, received from the information output 80 of module 1. If the patient’s cervical lordosis angle code is larger 30 °, the signal will be generated at the output 214 of the comparator 201.

In our case, at the information input 204 of the comparator 201 is the angle code of the patient's cervical lordosis, equal to 40 °, which is larger than the angle code 30 ° of the average degree of deviation of the cervical lordosis at the information input 205 of this comparator. Therefore, the output 214 of the comparator 201 will generate a signal supplied to the clock input of the comparator 202.

Step 3. The comparator 202 compares the 40 ° angle code of the cervical lordosis of the patient at his information input 204 with the 40 ° angle code of the small degree of cervical lordosis deviation received at his information input 206 from the information output 79 of module 1. If the patient's cervical lordosis angle code is equal 40 °, the signal is generated at the output 216 of the comparator 202.

In our case, at the information input 204 of the comparator 201 is the angle code of the patient's cervical lordosis, equal to 40 °, which is equal to the 40 ° angle code of the small degree of deviation of the cervical lordosis at the information input 206 of this comparator. Therefore, at the output 216 of the comparator 202, the signal “Normal condition of the cervical lordosis of the patient” will be generated, which is issued to the signal output 33 of the system and then sent to the automated workstation (AWP) of the user of the system.

In addition, this signal from the output 216 of the comparator 202 is supplied to the clock input 293 of the module 11 and opens one input of the elements 271 and 276 And one input.

At a different input, element 271 And will be open when a pulse arrives at the clock input 290 of module 11, and element 276 And at another input will be open when a pulse arrives at a clock input 292 of module 11.

Let us now consider the step-by-step operation of module 4 in recognizing the degree of deviation of the angle 17 ° of the lumbar lordosis, received at the information input 134, which is triggered in parallel by the pulse input to the synchronizing input of the comparator 125 of module 4.

Step 1. The comparator 125 compares the angle code 17 ° of the lumbar lordosis of the patient at its information input 134 with the angle code 10 ° of the critical degree of deviation of the lumbar lordosis at its information input 133, taken from the information output 75 of module 1. If the angle code of the lumbar lordosis of the patient is on the information input 134 will be more than 10 °, the signal is generated at the output 147 of the comparator 125.

In our case, at the information input 134 of the comparator 125 is the angle code of the lumbar lordosis of the patient, equal to 17 °, which is larger than the corner code 10 ° of the critical degree of deviation of the lumbar lordosis at the information input 133 of this comparator. Therefore, the output 147 of the comparator 125 will generate a signal supplied to the clock input of the comparator 126.

Step 2. The comparator 126 compares the angle code 17 ° of the lumbar lordosis of the patient at its information input 134 with the code of the angle of the average degree of deviation of the lumbar lordosis, equal to 15 °, and received at its information input 135 from the information output 76 of module 1. If the angle code of the lumbar lordosis patient at the information input 134 will be more than 15 °, the signal is generated at the output 149 of the comparator 126.

In our case, at the information input 134 of the comparator 125 is the angle code 17 ° of the lumbar lordosis of the patient, which is larger than the angle code 15 ° of the average degree of deviation of the lumbar lordosis at its information input 135. Therefore, the output 149 of the comparator 126 will generate a signal supplied to the synchronizing input of the comparator 128.

Step 3. The comparator 128 compares the angle code 17 ° of the lumbar lordosis of the patient at its information input 134 with the angle code 18 ° of a small degree of deviation of the lumbar lordosis received at its information input 136 from the information output 77 of module 1. If the angle code of the lumbar lordosis of the patient is on the information input 134 is less than or equal to 18 °, then the output 150 of the comparator 128 produces a signal "Small degree of deviation of the lumbar lordosis of the patient." This signal from the output 150 of the comparator 128 is issued to the signal output 42 of the system and then sent to the workstation (AWP) of the user of the system.

In this case, the angle code of the lumbar lordosis with a small degree of deviation from the information output 145 of module 4 is sent to the information input 172 of module 5, passes through the OR elements of group 166 and enters the decoder 159. The decoder 159 decodes the angle code of the lumbar lordosis of the patient's spine with a small degree of deviation and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 161-163 I. For definiteness, suppose that a high potential opens from the output of the decoder 159 t 163 And on one input, waiting for a pulse to arrive at one of the synchronizing inputs 173-175 of module 5 at the other input.

Such an impulse is precisely the impulse issued from the output 150 of the comparator 128 of the module 4, fixing a small degree of deviation of the angle of the lumbar lordosis. This pulse from the output 150 of the comparator 128 of module 4 is sent to the synchronizing input 175 of module 5, passes through the OR element 164, is delayed by the delay element 167 for the response time of the decoder 159, and passes through the element And open to the readout of the fixed cell of the read-only memory (ROM) 160. In a fixed cell ROM 160 is stored the code of the database address of the system server, containing the code of the sequence of loads on the spine to correct a small degree of deviation of the lumbar lordosis onochnika patient.

The code from the ROM 160 for the address of the system server database containing the sequence of loads on the spine to correct a small degree of deviation of the lumbar lordosis is fed to the information input of the register 158, where it is entered by the synchronizing pulse from the output of the delay element 167, the delayed element 168 of the delay for the reading time is fixed ROM cells 160.

The same pulse from the output of the delay element 168 is delayed by the delay element 169 for the time in which the code of the system server database address code is entered into the register 158, containing a sequence of loads on the spine to correct the degree of deviation of the lumbar lordosis, issued to the address output 26 of the system, and from the system output 30 to the input of the first channel of the system database server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 26 of the system and issuing a code for the sequence of loads on the spine to correct the degree of deviation of the lumbar lordosis to the information input 17 of the system.

The code of the sequence of loads on the spine to correct the degree of deviation of the lumbar lordosis from the information input 17 of the system is fed to the information input of the register 250 of module 9, where it is entered by the synchronizing pulse of the server to the synchronizing input 22 of the system.

The same clock pulse from the clock input 254 of the module 9 is delayed by the delay element 252 for the response time of the register 250 and from the clock output 258 of the module 9 is fed to the clock input 290 of the module 11 and opens the element 273 And one input.

In this case, the code of the sequence of loads on the spine to correct the degree of deviation of the lumbar lordosis from the information output 257 of module 9 is sent to the information input 288 of module 11.

In addition, the same pulse from the synchronizing input 290 of module 11 passes through the I 271 element open through one input and passes through the elements of group 277 the code for the sequence of loads on the spine received at the information input 288 of module 11 to correct the degree of deviation of the lumbar lordosis, which, having passed Further, through the elements of the OR group 284, it enters the information output 294 of the module 11 and from the information output 28 of the system is issued to the user's workstation.

The tracking signal of the sequence of loads on the spine issued to the user's workstation in the procedures for correcting its lordosis is now removed from the output of the AND element 271, passes through the OR element 282, goes to the synchronizing output 295 of the module 11, and from the system output 34 is issued to the user's workstation in the form signal "The sequence of loads on the spine of the patient in the procedures for the correction of his lordosis."

Now let the lumbar lordosis be normal, and the cervical lordosis has a deviation. In this case, after the processing of the lumbar lordosis angle code received at the information input 134 of module 4 is completed, the signal “Normal state of the lumbar lordosis of the patient” is received from the synchronizing output 156 of module 4, which is output to the signal output 32 of the system and sent to the workstation of the system user .

In addition, the signal from the output 156 of module 4 is supplied to the synchronizing input 292 of module 11 and opens one input of elements 275 and 276 AND one input. At a different input, element 275 And will be open when a pulse arrives at the clock input 291 of module 11, and element 276 And at another input will be open when a pulse arrives at a clock input 293 of module 11.

In turn, the code of the sequence of loads on the spine to correct the degree of deviation of the cervical lordosis is issued by the database server after the recognition of the degree of deviation in modules 7 and 8 is completed to the information input 18 of the system, from where it goes to the information input of the register 260 of module 10, where it is entered server synchronizing pulse received at the synchronizing input 23 of the system.

The same synchronizing server pulse from the synchronizing input 264 of the module 10 is delayed by the delay element 262 for the response time of the register 260 and from the synchronizing output 268 of the module 10 is supplied to the synchronizing input 291 of the module 11 and opens the And 273 element through one input.

In this case, the code of the sequence of loads on the spine to correct the degree of deviation of the cervical lordosis from the information output 267 of the module 10 is sent to the information input 289 of the module 11.

In addition, the same pulse from the synchronizing input 291 of module 11 passes through the I 275 element that is already open at one input and passes through the elements of the group 280 the code of the sequence of loads on the spine received at the information input 289 of the module 11 to correct the degree of deviation of the cervical lordosis, which, passing further through the elements of the OR group 284, it goes to the information output 294 of the module 11 and from the information output 28 of the system is issued to the user's workstation.

The tracking signal of the sequence of loads on the spine issued to the user's workstation in the procedures for correcting its lordosis is now removed from the output of the 275 element, passes through the 282 OR element, goes to the synchronizing output 295 of the module 11, and is sent to the system user's workstation from the system output 34 as signal "The sequence of loads on the spine of the patient in the procedures for the correction of his lordosis."

By issuing this signal and a code of the sequence of loads on the patient’s spine for the procedures for correcting his lordosis to the user’s AWP of the system, the cycle of processing the angles of the patient’s lordosis is completed.

The second signal to complete the cycle of processing the angles of the patient’s lordosis is a signal issued from the synchronizing output 296 of module 11, provided that both lordoses of the patient in question are in a normal state.

In this case, a signal identifying the normal state of the lumbar lordosis from the synchronizing output 156 of module 4 is sent to the synchronizing input 292 of the module 11, and a signal identifying the normal state of the cervical lordosis from the synchronizing output 216 of the module 7 is sent to the synchronizing input 293 of the module 11.

Since any of these signals opens the And element 276 through one input, then when the second signal arrives, it passes through the And element 276 to the synchronizing output 296 of module 11 and from the signal output of the system 43 is issued to the user's workstation in the form of a “Patient's spine is normal” signal .

The pulses from the synchronizing outputs 295 and 296 of the module 11 are sent respectively to the synchronizing inputs 305 and 306 of the module 12, which controls the process of analysis and processing of the lordosis angles of the patient array specified by the initial query codogram. Each of these pulses passes through the OR element 302 and enters the counting input of the counter 300 and increments it, thereby fixing the moment of completion of processing of the corners of the lordosis of the patient's spine.

The counter 300 counts on an accrual basis the total number of patients received and processed, each time outputting its contents to one information input of the comparator 301, to the other information input 304 of which from the information output 74 of module 1 a code is received for the total number of all requested patients to be processed in the system.

If the contents of the counter 300 supplied to one information input of the comparator 301 is equal to the code of the total number of all patients requested for processing in the system, supplied to its other information input 304 from the information output 74 of module 1, then a signal is generated at the output 309 of the comparator 301, which, firstly, immediately goes to the installation input of the counter 300, returning it to its original state.

Secondly, the signal from the output 311 of the module 12 is supplied:

- to the installation input 119 of module 3, the OR element 108 passes and enters the installation input of the register 100, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 177 of module 5, the OR element 165 passes through and enters the installation input of the register 158, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 239 of module 8, the OR element 227 passes and enters the installation input of the register 220, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 189 of module 6, the OR element 183 passes and enters the installation input of the register 180, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 256 of module 9, the OR element 251 passes and enters the installation input of the register 250, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 266 of module 10, the OR element 261 passes and enters the installation input of the register 260, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 326 of module 13, the OR element 321 passes and enters the installation input of the register 320, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 60 of module 1, resets its contents to zero and thereby prepares it for a new operation cycle

In addition, the signal from the output 311 of the module 12 from the signal output 36 of the system removes the signal "Processing the angles of the lordosis of the patient’s spines is completed", which is issued to the user's workstation.

A comparative analysis of the characteristics of a specific design of the considered technical solution and technical solution in [2] can be presented in the form of Table 2:

Thus, in accordance with Table 2, the initialization of processing instead of tomograms of lordosis of the patient’s spine only the angles of their correspondence (module 6), measured on the tomograms themselves and read from the server database (module 3), allows you to quickly make decisions about choosing the sequence of loads on the patient’s spine for the correction of his lordosis (modules 5 and 8) not by the difference of tomograms of the patient’s vertebral section and his standard having a large information capacity, but by the degree of deviation of each angle of the patient’s lordosis (mod St. 4 and 7).

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

1. RF patent No. 2666588, M. cl. A61B 8/13, 2018.

2. RF patent No. 2670387, M. cl. G06K 9/40, G06T 11/00, 2018 (prototype).

Claims (1)

Automated system for processing data of the angles of lordosis of the spine of patients,  containing a module for identifying the base address of the angles of the lordosis of the spine in the system server database,  the information input of which is the first information input of the system,  designed to receive the request codogram from the workstation of the system user,  the synchronizing input of the identification module of the base address of the angles of the lordosis of the spine in the database of the system server is the first synchronizing input of the system,  designed to receive the synchronization signals of entering the request codogram from the workstation of the system user into the identification module of the base address of the angles of the lordosis of the spine in the database of the system server,  a module for identifying the relative address of the angles of the lordosis of the lumbar spine in the system server database,  the first and second information inputs of which are connected to the first and second information outputs of the identification module of the base address of the angles of the lordosis of the spine in the database of the system server, respectively,  the synchronizing input of the identification module of the relative address of the angles of the lordosis of the lumbar spine in the system server database is connected to the synchronizing output of the identification module of the identification of the base address of the angles of the lordosis of the spine in the system server database,  selection module in the database server of the system of addresses of the angles of lords of the lumbar spine of patients,  the first information and first synchronizing inputs of which are connected to the information and synchronizing outputs of the identification module of the relative address of the angles of the lordosis of the lumbar spine in the system server database,  the second information input of the selection module in the database of the server of the system of addresses of the angles of the lords of the lumbar spine of the patients is connected to the third information output of the identification module of the identification of the base address of the angles of the lords of the spine in the database of the server of the system,  the information output of the selection module in the database server of the system of addresses of the angles of lords of the lumbar spine of patients is the first address output of the system,  designed to provide addresses of the angles of the lordosis of the lumbar spine of patients to the address input of the database server,  the synchronization output of the selection module in the database server of the system of addresses of the angles of the lordosis of the lumbar spine of patients is the first synchronizing output of the system,  designed to issue control signals by reading the addresses of the angles of the lordosis of the lumbar spine of patients at the input of the first channel of the database server interrupt,  module for recording the angles of lordosis of the spine of patients,  the information input of which is the second information input of the system,  designed to receive the codes of the angles of the lordosis of the spine of patients,  read from the system server database,  the synchronizing input of the module for registering the angles of the lordosis of the spine of the patients is the second synchronizing input of the system,  designed to receive synchronization signals entering codes of the angles of the lordosis of the spine of patients,  read from the system server database,  in the module for recording angles of lordosis of the spine of patients,  selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis,  the information output of which is the second address output of the system,  designed to provide addresses of the sequence of loads on the spine to correct the angles of the lumbar lordosis to the address input of the system database server,  the synchronizing output of the module for selecting addresses of the sequence of loads on the spine for correcting the angles of the lumbar lordosis is the second synchronizing output of the system,  designed to issue control signals by reading the addresses of the sequence of loads on the spine to correct the angles of the lumbar lordosis to the input of the first channel of interruption of the system database server,  selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of cervical lordosis,  the information output of which is the third address output of the system,  designed to provide addresses of the sequence of loads on the spine to correct the angles of the cervical lordosis to the address input of the system database server,  the synchronizing output of the selection module in the database of the server system addresses the sequence of loads on the spine for correcting the angles of the cervical lordosis is the third synchronizing output of the system,  designed to issue control signals by reading the addresses of the sequence of loads on the spine to correct the angles of the cervical lordosis to the input of the second channel of the server database system interrupt,  module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis,  the information input of which is the third information input of the system,  designed to receive a sequence of loads on the spine to correct the angles of lumbar lordosis,  read from the system server database  the synchronizing input of the module for recording the sequence of loads on the spine for correcting the angles of the lumbar lordosis is the third synchronizing input of the system,  designed to receive synchronizing signals of entering a sequence of loads on the spine to correct the angles of lumbar lordosis,  read from the system server database  in the module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis,  module for recording the sequence of loads on the spine to correct the angles of cervical lordosis,  the information input of which is the fourth information input of the system,  designed to receive a sequence of loads on the spine to correct the angles of cervical lordosis,  read from the system server database  the synchronizing input of the module for recording the sequence of loads on the spine for correcting the angles of the cervical lordosis is the fourth synchronizing input of the system,  intended for receiving synchronizing signals of entering a sequence of loads on the spine to correct the angles of cervical lordosis,  read from the system server database  in the module for recording the sequence of loads on the spine to correct the angles of cervical lordosis,  module for registering SNILS-patient codes,  the information input of which is the fifth information input of the system,  intended for receiving SNILS-codes of patients from the workstation of the system user,  the synchronizing input of the registration module of the SNILS patient codes is the fifth synchronizing input of the system,  intended for receiving synchronization signals for entering SNILS-codes of patients from the workstation of a user of the system into the registration module of SNILS-codes of patients,  the information and synchronizing outputs of the registration module of the SNILS-patient codes are connected to the third information and second synchronizing inputs of the selection module in the database of the server of the address system of the angles of the lordosis of the lumbar spine of patients, respectively,  control module for completing the analysis of the array of patients,  the information input of which is connected to the fourth information output of the identification module of the base address of the angles of the lordosis of the spine in the database of the system server,  one signal output of the control module for completing the analysis of the patient array is connected to one installation input of the selection module in the database of the server system of addresses of the sequence of loads on the spine to correct the angles of cervical lordosis,  with one installation input of the selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis,  with one installation input of the selection module in the database server of the system of addresses of the angles of the lordosis of the lumbar spine of patients,  with one installation input of the module for registering the angles of the lordosis of the spine of patients,  with one installation input of the module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis,  with one installation input of the module for recording the sequence of loads on the spine to correct the angles of cervical lordosis,  with one installation input of the module for registration of SNILS-patient codes and at the same time it is the first signal output of the system,  intended for issuing to the automated workstation of the user of the system a request signal for inputting the SNILS code of the next patient,  another signal output of the control module for completing the analysis of the patient array is connected to another installation input of the selection module in the database of the server system of addresses of the sequence of loads on the spine to correct the angles of cervical lordosis,  with another installation input of the selection module in the database of the server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis,  with another installation input of the selection module in the database server of the system of addresses of the angles of the lordosis of the lumbar spine of patients,  with another installation input module registration angles of the lordosis of the spine of patients,  with the installation input of the identification module of the base address of the angles of lordosis and kyphosis of the spine in the system server database,  with another installation input module registration sequence of loads on the spine to correct the angles of lumbar lordosis,  with another installation input module registration sequence of loads on the spine to correct the angles of the cervical lordosis,  with another installation input of the module for registration of SNILS-patient codes and at the same time is the second signal output of the system,  designed to issue a signal to the user’s automated workstation to complete the analysis of the patient array,  characterized in  that the system contains a module for recognizing the degree of deviation of the lumbar lordosis of the spinal column of patients,  the first,  second,  third,  the fourth and fifth information inputs of which are connected to the fifth,  the sixth  the seventh  the eighth and ninth information outputs of the module identifying the base address of the angles of the lordosis of the spine in the database of the system server, respectively,  the sixth information input of the module for recognizing the degree of deviation of the lumbar lordosis of the patient’s spine is connected to the second information output of the module for identifying the base address of the angles of the lordosis of the spine in the database of the system server,  and the seventh and eighth information and synchronization inputs of the module for recognizing the degree of deviation of the lumbar lordosis of the patient’s spine are connected to the first and second information and synchronizing outputs of the module for registering the angles of the lordosis of the patient’s spine, respectively,  the first,  second and third information and the first,  the second and third synchronizing outputs of the module for recognizing the degree of deviation of the lumbar lordosis of the spine of the patients are connected to the first,  second and third information and with the first,  the second and third synchronizing inputs of the selection module in the database server system addresses the sequence of loads on the spine to correct the angles of lumbar lordosis, respectively,  the first synchronizing output of the module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the third signal output of the system,  designed to issue a signal to the user’s automated workstation about the critical degree of deviation of the patient’s lumbar lordosis,  the second synchronizing output module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the fourth signal output of the system,  designed to issue a signal to the user’s automated workstation about the average degree of deviation of the patient’s lumbar lordosis,  and the third synchronizing output of the module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the fifth signal output of the system,  designed to issue a signal to the user’s automated workstation about a small degree of deviation of the patient’s lumbar lordosis,  the fourth synchronizing output of the module recognizing the degree of deviation of the lumbar lordosis of the spine of the patients is the sixth signal output of the system,  intended for the issuance of a signal on the normal state of the lumbar lordosis of the patient to the user's automated workstation,  recognition module for the degree of deviation of the cervical lordosis of the spinal column of patients,  the first,  the second and third information inputs of which are connected to the eighth,  the ninth and tenth information outputs of the module identifying the base address of the angles of the lordosis of the spine in the database server system, respectively,  and the fourth information input of the module recognizing the degree of deviation of the cervical lordosis of the patient’s spine is connected to the third information output of the module for registering the angles of the lordosis of the patient’s spine,  the synchronizing input of the recognition module of the degree of deviation of the cervical lordosis of the patient's spine is connected to the fifth synchronizing output module of the recognition of the degree of deviation of the cervical lordosis of the patient's spine,  the first,  second and third information and the first,  the second and third synchronizing outputs of the module recognizing the degree of deviation of the cervical lordosis of the spine of the patients are connected to the first,  second and third information and with the first,  the second and third synchronizing inputs of the selection module in the database server system addresses the sequence of loads on the spine to correct the angles of the cervical lordosis, respectively,  the first synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spine of patients is the seventh signal output of the system,  designed to issue a signal to the user’s automated workstation about the critical degree of deviation of the patient’s cervical lordosis,  the second synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spinal column of patients is the eighth signal output of the system,  designed to issue a signal to the user’s automated workstation about the average degree of deviation of the patient’s cervical lordosis,  and the third synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spine of the patients is the ninth signal output of the system,  designed to issue a signal to a user’s automated workstation about a small degree of deviation of the patient’s cervical lordosis,  and the fourth synchronizing output of the module recognizing the degree of deviation of the cervical lordosis of the spinal column of patients is the tenth signal output of the system,  designed to issue a signal to the patient’s automated workstation about the normal condition of the patient’s cervical lordosis,  and a synchronization module issuing a sequence of loads on the spine to correct the angles of lordosis of patients,  the first information and first synchronizing inputs of which are connected to the information and synchronizing outputs of the module for recording the sequence of loads on the spine to correct the angles of lumbar lordosis, respectively,  the second information and second synchronizing inputs of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis patients are connected to the information and synchronizing outputs of the module registering the sequence of loads on the spine for correcting the angles of the cervical lordosis, respectively,  the third synchronizing input of the synchronization module issuing a sequence of loads on the spine for correcting the angles of the patient’s lordosis is connected to the fourth synchronizing output of the module for recognizing the degree of deviation of the cervical lordosis of the patient’s spine,  and the fourth synchronizing input of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is connected to the fourth synchronizing output of the module for recognizing the degree of deviation of the lumbar lordosis of the patient’s spine,  the information output of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is the first information output of the system,  designed to issue to the user's workstation a system of a sequence of loads on the patient’s spine to correct his lordosis,  the first and second synchronizing outputs of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients are connected to the first and second synchronizing inputs of the control module completing the analysis of the patient array, respectively,  the first synchronizing output of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is the eleventh signal output of the system,  designed to issue to the user's automated workstation a signal confirming the issuance of a sequence of loads on the patient’s spine in the procedures for correcting his lordosis,  and the second synchronizing output of the synchronization module issuing a sequence of loads on the spine for correcting the angles of lordosis of patients is the twelfth signal output of the system,  designed to issue a signal to the patient’s spinal column to the user's workstation.

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