RU161314U1 - SYSTEM FOR DECISION-MAKING ON COMPLIANCE WITH ICAO PROVISIONS OF STATE STANDARDS AND REGULATIONS OF THE AVIATION AUTHORITIES FOR MONITORING SAFETY OF SAFETY - Google Patents

Abstract

A decision-making system on compliance with ICAO provisions of state standards and decisions of the aviation authorities for monitoring flight safety, containing a module for identifying the base address of answers to protocol questions, the information input of which is the first information input of the system designed to receive a request codogram from the workstation of a system user , the synchronizing input of the base address identification module of the answers to the protocol questions is the first system synchronization input, intended for receiving synchronization signals of entering the request codogram from the workstation of the system user into the identification module for the base address of answers to protocol questions, the module for selecting address parameters of answers to protocol questions of the verification area, 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 answers to protocol questions, respectively, and the synchronizing input mode While selecting the addresses of the parameters of answers to the questions of the protocol of the scan area is connected to the synchronizing output of the identification module of the base address of answers to the questions of the protocol, one information output of the module of the selection of the address of the parameters of answers to the questions of the protocol of the field of verification is the first address output of the system designed to provide the address of the parameters of the answers of the field of verification to the address input of the database server, another information output of the selection module of the address of the parameters of answers to questions of the protocol

Description

The utility model relates to computer technology, in particular, to a decision-making system on compliance with ICAO provisions of state standards and decisions of aviation authorities to monitor flight safety, which implements the use of new information technologies in the organization of flight safety control.

The ICAO International Civil Aviation Organization interacts with states through the procedure for raising standardized protocol issues, grouped by audit area, taking into account critical elements and based on the provisions of the Convention, standards and recommended practices (SARPs), safety related annexes to the Convention and related guidance material ICAO [3].

The protocol questions adopted by ICAO determine the database structure, which is uniform for all states, but filled with its answers, which, together with the initial protocol questions, are returned to ICAO. The information received is analyzed by ICAO and recommendations made to address the identified safety risk factors are sent to the aviation authorities of these countries.

The interaction is made possible due to the fact that, in accordance with clause 5.2.1 of ICAO Appendix 19, “each state creates and maintains a safety database in order to facilitate effective analysis of information received on actual or potential safety deficiencies, including information from their incident reporting systems, and in order to identify any necessary actions to improve flight safety ”[4].

In carrying out the safety audit process, ICAO sends the protocol issues to the aviation authorities of each state, grouped in the following areas of audit: basic aviation legislation and civil aviation regulations (LEG), civil aviation organization (ORG), issuing certificates to aviation personnel and training ( PEL), aircraft operations (OPS), aircraft airworthiness (AIR), accident and incident investigation AIG), aeronautical services (ANS), aerodromes and ground aids (AGA).

Moreover, in accordance with Section 2.13 of the Guide [3], as an indicator of the effective implementation of the EI, which characterizes the state’s ability to monitor safety, the ratio of the number of protocol issues with the mark “satisfactory” to the total number of protocol issues for each ICAO audit area is used:

where VP - issues of the protocol of the ICAO verification area.

A higher EI indicates that the state safety oversight system is more consistent with ICAO.

Hence the task of automating decision-making on the effectiveness of the implementation of safety oversight in all areas of ICAO verification.

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

The first of the known systems comprises data reception and storage units connected to control and data processing units, search and selection units connected to data storage and display units, the synchronizing inputs of which are connected to the outputs of the control unit [1].

A significant drawback of this system is the impossibility of solving the problem of updating data stored in memory in the form of relevant documents, simultaneously with solving the problem of delivering the contents of these documents to users in real time.

Another system is known, containing a central processor module, the inputs of which are connected to the memory modules and to the data preparation and input modules, and the outputs are connected to the corresponding memory modules, the data processing module, the information inputs of which are connected to the outputs of the corresponding memory modules, the synchronizing inputs are connected to control outputs of the central processor module, and the output of the module is the information output of the system [2].

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

Its disadvantage lies in the low speed of the system, due to the fact that the implementation of analytical data processing procedures is carried out by searching the entire database, which, when the database is large, inevitably leads to unreasonably large time spent on obtaining analytical estimates.

The purpose of the utility model is to increase the system performance by excluding data search over the entire volume of the server database and localizing the search only at the reference (base and relative) database addresses corresponding to the state identifier and ICAO verification areas.

This goal is achieved by the fact that in a system containing a module for identifying the base address of answers to protocol questions, the information input of which is the first information input of the system, designed to receive a request codogram from a workstation of a system user, synchronizing the input of the module for identifying the base address of answers to protocol questions is the first synchronizing input of the system, intended for receiving synchronizing signals of entering the request codogram with av a computerized workstation of a system user into a module for identifying the base address of answers to protocol questions, a module for selecting address parameters of answers to protocol questions of the verification area, the first and second information inputs of which are connected to the first and second information outputs of the module for identifying the base address of answers to protocol questions, respectively, and the synchronizing input of the module for selecting addresses of the parameters of answers to questions of the protocol of the verification area is connected to the synchronizing output of the module identification of the base address of answers to protocol questions, one information output of the selection module of the address of the parameters of answers to the questions of the protocol of the scan area is the first address output of the system designed to provide the address of the parameters of the answers of the scan area to the address input of the database server, another information output of the module of selection of the address of the response parameters to the questions of the protocol of the verification area is an information output of the system intended for issuing to the workstation The system of codes of the verification area, the synchronizing output of the selection module of the address of the parameters of answers to the questions of the protocol of the verification area is the first synchronizing output of the system, designed to issue control signals for reading the parameters of the answers to the questions of the protocol of the verification area at the input of the first channel of the database server interrupt, the module for registering response parameters to questions of the verification area protocol, the information input of which is the second information input of the system, intended To receive codes of response parameters of the verification area read from the server database, the synchronizing input of the module for registering answers to questions of the verification domain protocol is the second synchronizing input of the system designed to receive synchronization signals of entering the codes of response parameters to the questions of the verification domain protocol read from the database server data, to the module for registering the parameters of answers to the questions of the protocol of the verification area, the module for monitoring the completion of the analysis procedure for the array of areas test, the information input of which is connected to the third information output of the identification module of the base address of answers to the protocol questions, one synchronizing output of the control module of the completion of the analysis of the array of verification areas is connected to one installation input of the base address identification module of the answers to the protocol questions, with one installation input of the module selection of the address of the parameters of answers to questions of the protocol of the verification area, with one installation input of the module for registering the parameters of answers to polls of the protocol of the verification area and at the same time it is the first signal output of the system intended for issuing to the automated place of the user of the system a signal about the need to enter the following codogram into the system, another synchronizing output of the control module completing the analysis of the array of verification areas is connected to another installation input of the base address identification module answers to the protocol questions, with another installation input of the selection module of the address of the parameters of the answers to the protocol questions of the domain verification, with a different installation input of the module for registering the parameters of answers to questions of the protocol of the verification area, and at the same time it is the second signal output of the system, designed to give a signal to the automated place of the user of the system to complete the processing of response parameters for all requested areas of verification, an identification module has been introduced for the value of the quantity ratio satisfactory answers to the total number of questions in the protocol of the verification area, one and the other of which the information inputs are connected to one and the other information outputs of the module for registering the answers to questions of the protocol of the verification area, respectively, the synchronizing input of the module for identifying the ratio of the number of satisfactory answers to the total number of questions in the protocol of the field of verification is connected to the synchronizing output of the module for registering the parameters of answers to the questions of the protocol of the field of verification, the module for recognizing the degree of compliance state safety oversight standards ICAO, one information input of which is connected to the fourth information output of the identification module of the base address of answers to protocol questions, another information input of the recognition module of the degree of compliance of state standards for monitoring safety with ICAO provisions is connected to the information output of the identification module of the ratio of the number of satisfactory answers to the total number of questions in the protocol of the verification area, synchronizing the input of the recognition module with The degree of compliance of state safety control standards with ICAO provisions is connected to the synchronization output of the identification module of the ratio of the number of satisfactory answers to the total number of questions in the audit field protocol, one synchronization output of the recognition module of recognition of the degree of compliance of state safety control standards with ICAO provisions is connected to one counting input of the control module completing the analysis of the array areas of verification, and at the same time it is the third signal output of the system, designed to issue a signal to the user’s automated workstation about a low degree of compliance with the ICAO provisions of state safety control standards, another synchronizing output of the recognition module of the degree of compliance with state safety control standards flight regulations ICAO is connected to another counting input of the module for monitoring the completion of the analysis procedure an array of areas of verification and at the same time it is the fourth signal output of the system designed to issue a signal to the user’s automated workstation about a high degree of compliance with ICAO provisions of state safety control standards.

The essence of the utility model is illustrated by drawings, where in FIG. 1 is a structural diagram of a decision-making system on compliance with ICAO provisions of state standards and decisions of the aviation authorities to monitor flight safety; FIG. 2 shows an example of a specific constructive implementation of a base address identification module for answering protocol questions, FIG. 3 shows an example of a specific constructive implementation of the module for selecting the address of the parameters of answers to questions of the protocol of the verification area, FIG. 4 shows an example of a specific constructive implementation of the module for registering the parameters of answers to questions of the protocol of the verification area, FIG. 5 shows an example of a specific constructive implementation of the identification module of the value of the ratio of the number of satisfactory answers to the total number of questions of the protocol of the verification area, FIG. Figure 6 shows an example of a specific constructive implementation of the recognition module for the degree of compliance of state standards for the control of flight safety with ICAO provisions, and FIG. 7 shows an example of a specific constructive implementation of the control module of the completion of the analysis procedure of the array of verification areas,

The decision-making system (Fig. 1) contains module 1 for identifying the base address of answers to protocol questions, module 2 for selecting address parameters for answers to questions in the verification domain protocol, module 3 for registering response parameters for questions in the verification domain protocol, module 4 for identifying the ratio of the number of satisfactory answers to the total number of questions in the protocol of the audit area, module 5 for recognizing the degree of compliance with state safety oversight standards is laid down ICAO pits, control unit 6 complete array scan areas of analysis procedures.

In FIG. 1 shows the first 10 and second 11 information inputs of the system, the first 12 and second 13 synchronizing inputs of the system, as well as address 14, information 15. synchronizing 16 and signal 17-20 system outputs.

The base address identification module 1 of answers to protocol questions (Fig. 2) contains a register 25, a decoder 26. a memory module 27, made in the form of read-only memory (ROM), elements 28-30 I. element 31 OR, elements 32-33 delay . The drawing also shows information 34, synchronizing 35 and installation 36-37 inputs, information 42-45 and synchronizing 46 outputs.

Module 2 of the selection of address parameters of answers to questions of the protocol of the verification area (Fig. 3) contains a register 50. a decoder 51, a memory module 52, made in the form of read-only memory (ROM), an adder 53. elements 54-56 AND, element 57 OR, delay elements 58-60. The drawing also shows information 61-62, synchronizing 63 and installation 64-65 inputs, as well as information 66-67 and synchronizing 68 outputs.

Module 3 registration parameters of answers to questions of the protocol of the verification area (Fig. 4) contains a register 75, the element OR 76 and element 77 delay. The drawing also shows information 78, synchronizing 79 and installation 80-81 inputs, as well as information 82-83 and synchronizing 84 outputs.

Module 4 identifying the value of the ratio of the number of satisfactory answers to the total number of questions of the protocol of the verification area (Fig. 5) contains a decoder 90, a memory module 91, made in the form of read-only memory (ROM), a multiplier 92. elements 93-95 I, elements 96- 97 delays. The drawing also shows information 98-99 and synchronizing 100 inputs, as well as information 101 and synchronizing 102 outputs.

The recognition module 5 for the degree of compliance of state standards for the monitoring of flight safety with ICAO provisions (Fig. 6) contains a comparator 110, elements 111-112 And, a delay element 113. The drawing also shows information 114-115 and synchronizing 116 inputs, as well as synchronizing 119-120 outputs.

Module 6 control completion of the analysis of the array of verification areas (Fig. 7) contains a counter 130, a comparator 131, an OR element 132 and a delay element 133. The drawing also shows information 134 and installation 135-136 inputs, as well as synchronizing outputs 139-140.

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 the ICAO verification area code and system signals, and a personal computer keyboard.

The system operates as follows.

Each state in the ICAO database has its own base address for answers to protocol questions corresponding to its identifier. Addresses of the parameters of answers to the protocol questions for each ICAO verification area are identified as relative addresses shifted relative to the base address by an amount corresponding to the code of this ICAO verification area (Table 1).

The relative address of the parameters of answers to questions of the protocol of the ICAO verification area obtained by adding answers to the protocol questions to the base address of the protocol address is issued to the address input of the system database server.

The server reads at the exposed address the parameters of answers to the questions of the protocol of the ICAO verification area and sends them to the information input of the system. The parameters of answers to the protocol questions of the ICAO verification area read from the server database are represented by codes: the code of the number of satisfactory answers and the code of the total number of protocol questions.

Processing the accepted parameters of answers to questions of the protocol of the verification area begins with the procedure for identifying the reciprocal value of the total number of protocol questions of the considered verification area by correlating the code of the total number of protocol questions of a ROM memory cell in which the code of the inverse value of the total number of protocol questions is stored. Further, this code is multiplied with the code of the number of satisfactory answers to the protocol questions of the examined verification area.

The obtained value of the ratio of the number of satisfactory answers to the total number of protocol questions of the examined verification area is compared with a certain threshold for compliance with ICAO safety oversight standards.

If the code for the ratio of the number of satisfactory answers to the total number of protocol questions of the examined verification area generated by the system turns out to be less than the code for the specified threshold for compliance with ICAO provisions, then the signal “Low degree of compliance with ICAO provisions for safety control standards” and the number code processed validation area.

If the code of the ratio of the number of satisfactory answers to the total number of protocol questions of the examined verification area generated by the system turns out to be greater than or equal to the code of the specified threshold for compliance with ICAO provisions, then the signal “High degree of compliance with ICAO provisions for safety monitoring standards” is issued to the system’s workstation and code number of the processed scan area.

After issuing any of these signals to the system user’s AWP, the system checks whether all verification areas have been processed by the system. If not all scan areas have been processed, the system generates a request signal for entering response parameters of the next scan area, if the response parameters of all scan areas specified in the request codogram are processed, the system ends its work.

To start the system, its user (in our case, it is an ICAO expert) at his workplace generates a request codogram, which indicates the code of the inspected country, the code of the initial (start) ICAO inspection area, the code of the total number of inspected ICAO verification areas and the threshold value of the effective indicator implementation of control.

For definiteness, let the AGA verification area with code 0001 be indicated in the codogram for definiteness and the number of inspected ICAO verification areas to be eight, i.e. the system should analyze all areas of verification, starting with the first. Then the initial system user codogram will receive the form of Table 2:

The generated codogram from the workstation of the system user from ICAO is fed to the information input 10 of the system, fed to the information input 34 of module 1 for identifying the base address of answers to protocol questions, and entered into register 25 by a synchronizing pulse supplied to synchronizing input 35 of module 1 from synchronizing input 12 system.

The identifier of the inspected country from the output 38 of register 25 is fed to the input of the decoder 26. The decoder 26 decrypts the country code and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 28-30 I. For definiteness, we assume that the high potential from the output of the decoder 26 element 30 And one input will be opened.

The synchronizing pulse from the input 12 of the system goes to the synchronizing input 35 of module 1, is delayed by the delay element 32 for the response time of the register 25 and the decoder 26, and enters through the element 30 open through one input and to the read input of a fixed cell of a permanent storage device (ROM) 27.

In a fixed cell of ROM 27, the code of the base address of the answers to the protocol questions is stored, starting from which the server information stores the information about the answers for all areas of ICAO verification. Moreover, for each ICAO verification area, a separate memory area is allocated in the server database memory, the address of which is offset from the base address by a certain amount corresponding to the identifier code of the verification area under consideration.

Therefore, the ICAO verification area code from the output 43 of module 1 is sent to the information input 61 of the selection module 2 of the address of the parameters of answers to the questions of the verification area protocol and is supplied to the input of the decoder 51. The decoder 51 decodes the verification area code and generates a high potential at one of its outputs. to the respective inputs of the elements 54-56 I. For definiteness, let us assume that the high potential from the output of the decoder 51 will open the element 55 And one input.

In this case, the synchronizing pulse from the output of the delay element 32, delayed by the delay element 33 while reading the contents of the fixed cell of the ROM 27 of the module 1 and the operation of the decoder 51 of the module 2, is sent from the output 46 of the module 1 to the synchronizing input 63 of the module 2 and arrives through the open one by one input element 55 And to the read input of a fixed cell of a read-only memory (ROM) 52. In a fixed cell of a ROM 52, a bias code of the address of the parameters of the answers to questions of the protocol of the AGA protocol ICA verification ICAO is stored, 0001 which was adopted at the input 61 of the decoder 51 of the module 2.

The code for shifting the address of the parameters of the answers to the protocol questions of the verification area, read from the ROM 52, relative to the base address of the answers to the protocol questions of all the verification areas, ICAO is fed to one information input of the adder 53, the other information input 62 of which is the code of the base address of the answers to the protocol questions of all eight areas ICAO checks from the output of 42 module 1.

According to the synchronizing pulse from the input 63 of the module 2, delayed by the delay element 58 for the time of reading the fixed cell of the ROM 52, the adder 53 generates the relative address of the parameters of the answers to the questions of the protocol of the AGA verification area, the code of which was applied to the input 61 of the decoder 51 of the module 2.

Formed in the adder 53, the relative address of the response parameters of the AGA verification area is fed to the input of the register 50, where it is entered by the synchronizing pulse from the output of the delay element 58 after the delay by the delay element 59 for the operation time of the adder 51.

The same pulse from the output of the delay element 59 is delayed by the delay element 60 for the time of recording in the code register 50 the relative address of the parameters of the answers to the questions of the AGA verification protocol protocol issued to the address output 14 of the system, and from the output 16 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 interrogating the contents of its database at the address generated on the address output 14 of the system and issuing the read parameters for answering questions from the protocol of the start area of the AGA check for information input 11 of the system.

The parameters of answers to the questions of the protocol of the starting area of the AGA scan, read from the server database, are represented by two codes: the code of the number of satisfactory answers and the code of the total number of questions of the protocol of the scan area.

The AGA verification area response parameters read from the server database from the information input 11 of the system go to the information input 78 of the register 75 of the module 3 for registering the verification area response parameters, where they are entered by the server synchronizing pulse supplied to the synchronization input 79 of the register 75 from the system synchronizing input 13.

The code of the total number of questions in the protocol of the verification area from the output 83 of the register 75 of module 3 is supplied to the information input 98 of the module 4 for identifying the ratio of the number of satisfactory answers to the total number of questions in the protocol of the area of verification and is input to the decoder 90.

The decoder 90 decrypts the code of the total number of questions of the protocol of the verification area and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 93-95 I. For definiteness, suppose that a high potential from the output of the decoder 90 will open the 95 And element at one input.

In this case, the synchronizing pulse received at the synchronizing input 79 of module 3 and then delayed by the delay element 77 while the response parameter response codes are entered into the register 75, from the synchronizing output 84 of the module 3 is fed to the synchronizing input 100 of the module 4 and passes through the open one by one input element 95 And to the read input of a fixed cell of read-only memory (ROM) 91. In a fixed cell of ROM 91, a code is written for the reciprocal of the total number of questions of the protocol of the verification area.

The code of the reciprocal value of the total number of questions of the protocol of the verification area, read from the ROM 91, is fed to one information input of the multiplier 92, to the other information input 99 of which is supplied a code of satisfactory answers to the questions of the protocol of the considered verification area from the information output 82 of module 3.

By the same pulse at the clock input 100 of module 4, delayed by the delay element 96 for the read time of the fixed cell ROM 91 and applied to the clock input of the multiplier 92, the multiplier 92 multiplies the codes received at its information inputs,

The result of multiplying in the form of a code the value of the ratio of the number of satisfactory answers to the total number of protocol questions of the verification area under consideration is supplied from the information output 101 of module 4 to one information input 114 of the software comparator module 5 to recognize the degree of compliance of state standards for monitoring safety with ICAO regulations to another information input 115 of which a threshold value code of an indicator of effective implementation of security monitoring is supplied minute flight from an information output module 44 1.

According to the synchronizing pulse from the output of the delay element 96, delayed by the delay element 97 for the response time of the multiplier 92 and applied to the synchronizing input of the comparator 110 from the synchronizing input 116 of module 5, the comparator 110 compares the codes received at its information inputs.

If the code of the ratio of the number of satisfactory answers to the total number of protocol questions of the verification area considered by the system turns out to be less than the threshold code value of the indicator of effective implementation of safety control, then a signal is generated at the output of comparator 110, which opens 111 I through one input.

In this case, the synchronizing pulse from the input 116 of the module 5, delayed by the delay element 113 for the response time of the comparator 110, passes through the element 111 open through one input and the signal 119 of the system 5 is sent to the signal output of the system 19 and the signal “Low degree of compliance with ICAO safety oversight systems. ”

If the code of the ratio of the number of satisfactory answers to the total number of protocol questions of the verification area considered by the system turns out to be greater than or equal to the threshold code value of the indicator of effective implementation of safety control, then the signal is generated at the output 118 of the comparator 110, which opens one element input 112 I.

In this case, the synchronizing pulse from the input 116 of the module 5, delayed by the delay element 113 for the response time of the comparator 110, passes through the element 112 open through one input and the signal output 120 of the module 5 and the signal “High degree of compliance with ICAO safety oversight systems. ”

The signals from the outputs 119 and 120 of module 5 are received at the corresponding 135 and 136 counting inputs of the control module 6 for completing the analysis of the array of ICAO verification areas, pass the OR element 132 and are fed to the counting input of the counter 130, increasing its content by one information input by one comparator 131. To another information input 134 of comparator 131, the code of the total number of ICAO verification areas is supplied from the information output 45 of module 1, which must be processed by the system in accordance with the information received at the information input 10 s Stem Overheads ICAO request.

The synchronizing pulse from the output of the OR element 132, delayed by the delay element 133 for the increment time of the counter 130, is supplied to the synchronizing input of the comparator 131, allowing the comparison of the codes supplied to its information inputs.

Since the counter 130 counts the number of processed ICAO verification areas on an accrual basis, and at the moment only the first verification area has been registered by the counter, then its readings will be significantly less than the code supplied to the input 134 of the comparator 131. In this case, the output of the 137 comparator 131, a signal will be generated which, from the output 139 of module 6, is supplied to the installation inputs of all those modules that were involved in processing the previous verification area, namely:

- to the installation input 36 of module 1, the OR element 31 passes and enters the installation input of the register 25, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 64 of module 2, the OR element 57 passes and enters the installation input of the register 50, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 80 of module 3, the OR element 76 passes and enters the installation input of the register 75, resets its contents to zero and thereby prepares it for a new operation cycle.

In addition, a signal “Enter the code of the next verification area” is issued from the signal output of the system 17 to the user's workstation. At the same time, from the information output of the system 15, the code of the processed verification area is issued to the user's workstation.

Based on this signal, the system user at his workplace generates the following request codogram, which indicates the code of the inspected country, the code of the next ICAO inspection area, the code of the total number of inspected ICAO inspection areas and the threshold value of the indicator for the effective implementation of safety oversight.

The generated codogram from the workstation of the system user from ICAO is fed back to the information input 10 of the system, goes to the information input 34 of the identification module 1 of the base address of the answers to the protocol questions and is entered into register 25 by the synchronizing pulse supplied to the synchronizing input 35 of the module 1 from the synchronizing input 12 of the system by which the procedure begins for processing the parameters of the answers to the protocol questions of the adopted next ICAO verification area.

The described process of receiving codograms of requests and processing the parameters of answers to protocol questions for each requested ICAO verification area will continue until the parameters of answers to protocol questions of all eight ICAO verification areas are processed.

In this case, upon completion of the processing of the final, eighth, ICAO verification area, the contents of the counter 130 will be equal to the code of the total number of ICAO verification areas received at the information input 134 of the comparator 131 from the information output 45 of module 1. The comparator 131 will record the equality of codes on its information inputs with generation signal at its output 138.

This signal from the output 138 of the comparator 131, firstly, is immediately supplied to the installation input of the counter 130, returning it to its original state.

Secondly, this signal from the output 140 of module 6 is sent to the signal output 18 of the system, from where the signal “Received and processed parameters of answers to the protocol questions of all ICAO verification areas” is issued to the user workstation.

Thirdly, the same signal from the output 140 of module 6 is supplied:

- to the installation input 37 of module 1, the OR element 31 passes and enters the installation input of register 25, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 65 of module 2, the OR element 57 passes and enters the installation input of the register 50, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 81 of module 3, the OR element 76 passes and enters the installation input of the register 75, resets its contents to zero and thereby prepares it for a new operation cycle.

A distinctive feature of module 1 is that the base address of answers to protocol questions in all eight areas of ICAO verification is identified in the database of the system by the identifier of an ICAO member country. Whereas in module 2, the addresses of the answers to the protocol questions for each separate ICAO verification area are relative, since each of them is relative to the base address of the answers at a certain offset, the value of which corresponds to the code of the ICAO verification area.

Thus, the introduction of new nodes and modules and new structural connections has significantly improved system performance by eliminating data retrieval across the entire system server database.

Information sources:

1. US patent No. 5136708, M. cl. G06F 15/16, 1992.

2. US Patent No. 5129083, M. cl. G06F 12/00, 15/40, 1992 (prototype).

3. Guidelines for continuous monitoring as part of the Universal Safety Oversight Audit Program. - Doc 9735. - Fourth Edition - 2014. - © ICAO.

4. Appendix 19 to the Convention on International Civil Aviation “Safety Management”. ^ First edition - 2013. - © ICAO.

Claims (1)

A decision-making system on compliance with ICAO provisions of state standards and decisions of the aviation authorities for monitoring flight safety, containing a module for identifying the base address of answers to protocol questions, the information input of which is the first information input of the system designed to receive a request codogram from the workstation of a system user , the synchronizing input of the base address identification module of the answers to the protocol questions is the first system synchronization input, intended for receiving synchronization signals of entering the request codogram from the workstation of the system user into the identification module for the base address of answers to protocol questions, the module for selecting address parameters of answers to protocol questions of the verification area, 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 answers to protocol questions, respectively, and the synchronizing input mode While selecting the addresses of the parameters of answers to the questions of the protocol of the scan area is connected to the synchronizing output of the identification module of the base address of answers to the questions of the protocol, one information output of the module of the selection of the address of the parameters of answers to the questions of the protocol of the field of verification is the first address output of the system designed to provide the address of the parameters of the answers of the field of verification to the address input of the database server, another information output of the selection module of the address of the parameters of answers to questions of the protocol of the region and verification is the information output of the system, intended for issuing to the automated workstation of the user the system of codes of the verification area, the synchronizing output of the selection module of the address of the parameters of answers to questions of the protocol of the verification area is the first synchronizing output of the system, intended for issuing control signals for reading the parameters of the answers to questions of the protocol of the region checking the input of the first channel for interrupting the database server, module for registering parameters for answering questions protocol of the verification area, the information input of which is the second information input of the system, intended for receiving codes of response parameters of the verification area read from the server database, the synchronizing input of the module for registering answers to questions of the protocol of the verification area is the second synchronizing input of the system, intended for receiving synchronizing signals entering the codes of the parameters of answers to the protocol questions of the scan area, read from the server database, in the registration module and parameters of answers to questions of the protocol of the verification area, the control module for completing the analysis of the array of verification areas, the information input of which is connected to the third information output of the identification module of the base address of the answers to the protocol questions, one synchronizing output of the control module for the completion of the analysis of the array of verification areas is connected to one installation the input of the base address identification module for answering protocol questions, with one installation input of the param address selection module A ditch of answers to questions from the protocol of the verification area, with one installation input of the module for registering the parameters of answers to the questions of the protocol of the verification area, and at the same time it is the first signal output of the system designed to issue a signal to the system user about the need to enter the following codegram into the system, another synchronizing output the control module for completing the analysis of the array of verification areas is connected to another installation input of the module for identifying the base address of the responses to protocol issues, with a different installation input of the selection module of the address of the parameters of answers to the questions of the protocol of the verification area, with another installation input of the registration module of the parameters of answers to the questions of the protocol of the verification area, and this is the second signal output of the system designed to issue a signal about completion of processing of response parameters for all requested verification areas, characterized in that it contains a module for identifying the value of the ratio there are satisfactory answers to the total number of questions of the protocol of the verification area, one and the other information inputs of which are connected to one and the other information outputs of the module for registering the parameters of answers to the questions of the protocol of the verification field, respectively, the synchronizing input of the identification module of the ratio of the number of satisfactory answers to the total number of questions of the protocol of the region checker is connected to the synchronizing output of the module for registering parameters of answers to protocol questions areas of verification, a recognition module for the degree of compliance of state standards for monitoring safety with ICAO provisions, one information input of which is connected to the fourth information output of the module for identifying the base address of answers to protocol questions, another information input of a module for recognizing the degree of compliance of state standards for safety control flight regulations ICAO connected to the information output of the identification module to answer the number of satisfactory answers to the total number of questions of the protocol of the verification area, the synchronizing input of the recognition module of the degree of compliance of state standards for monitoring safety with ICAO provisions is connected to the synchronizing output of the identification module of the value of the ratio of the number of satisfactory answers to the total number of questions of the protocol of the verification area, one synchronizing output recognition module for the degree of compliance with state standards ICAO is connected to one counting input of the control module for completing the analysis of the array of verification areas and is the third signal output of the system, designed to issue a signal to the user’s automated workstation that the ICAO provisions comply with state standards for monitoring safety assurance, another synchronizing output of the recognition module of the degree of compliance with state standards The ICAO safety standards control unit is connected to another counting input of the control module for completing the analysis of the array of verification areas and is the fourth signal output of the system, designed to issue a signal to the user’s automated workstation that the ICAO provisions comply with state standards safety oversight.

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