RU67303U1 - AUTOMATED PASSENGER AIR TRANSPORT MANAGEMENT SYSTEM - Google Patents

Abstract

The invention relates to computer technology, in particular, to an automated control system for passenger air transportation. The technical result is to increase the system performance by excluding data search for decision making across the entire database and localizing the search only by the temporary and distinctive signs of the identifiers of signs of the corresponding economic indicators. The technical result is achieved by the fact that the system comprises a module for identifying a base address for reading, a module for generating signals for reading a database of a server, a module for selecting flights, a module for identifying flights for a given year, a memory module for identifying a time interval for analysis. 6 ill.

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

1. US Patent No. 0,005,651, M. cl. G06F 13/40, 13/38, 1992.

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

Description

The invention relates to computer technology, in particular, to an automated control system for passenger air transportation.

For the operational analysis and decision-making on passenger air transportation performed for any given period of time, the system usually uses the following set of indicators: flight number; name of the route; the number of completed flights of each room for a given period; income attributable to each flight; income per passenger kilometer; average return rate per flight for each booking class; full flight income for a given period; percent

seat occupancy on the flight; number of passengers carried; million passenger kilometers; million armchair kilometers, etc.

Comparison of the dynamics of changes in these indicators in their interconnection allows us to judge with sufficient probability the potential of the operated market, the structure of passenger traffic (at the profitable rate), the effectiveness of the schedule (the correct placement of aircraft), the correct application of tariffs, etc.

In this regard, it seems advisable to create such an automated system that would ensure the achievement of the highest efficiency (profitability) of flights.

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 that contains a central processing unit (CPU), the inputs of which are connected to the memory blocks and to the data preparation and input units, and the outputs are connected to the corresponding memory blocks, the data processing unit, the information inputs of which are connected to the outputs of the corresponding memory blocks, synchronizing the inputs are connected to the control outputs of the CPU, and the output of the block 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 invention is to increase the speed of the system by eliminating data search for decision making throughout the server database and localizing the search only by the temporary and distinguishing features of identifiers of economic indicators.

This goal is achieved by the fact that in a known system containing a memory module, one information output of which is the first information output of the system, designed to provide information in the form of the number of flights performed with a given value of the requested attribute for each year of analysis from a given time interval to the user's automated location upon request, the module for generating signals to read the server database, the information output of which is the address output of the system intended for issuing a read address to the address input of the database server, and the synchronizing output of the module for generating read signals of the server database is a synchronizing output of the system, intended for issuing read signals to the read input of the database server, a read base identification module has been introduced, the information input of which it is the first information input of the system intended for receiving a request codogram from workstations of system users , A clock input module identification

the reading base address is the first synchronizing input of the system, intended for entering the request codogram from workstations of users of the system into the reading base address identification module, one installation input of the reading base address identification module is connected to the synchronizing output of the memory module, the first information output of the reading base address identification module connected to the information input of the module for generating signals for reading the server database, and the syn the resetting output of the identification base address identification module is connected to the synchronizing input of the server database read signal generation module, the flight identification module of a given year, one information input of which is connected to the second information output of the reading base address identification module, one output of the flight identification module of a given year is connected to the counting the input of the module for generating signals for reading the server database, and the other output of the module for identifying flights of a given year with connected to the synchronizing input of the memory module, a flight selection module, the first information input of which is the second information input of the system intended for receiving records from the server database, the second information input of the flight selection module is connected to the third information output of the reading base address identification module, and the third information the input of the flight selection module is connected to the fourth information output of the read base address identification module, which synchronizes the module input flight selection is the second synchronizing input of the system, intended for recording records read from the server database in the flight selection module, the first information output of the flight selection module is the second information

the system’s output intended for issuing records read from the server database to automated workstations of system users, the second information output of the flight selection module is connected to another information input of the flight identification module of a given year, the third information output of the flight selection module is connected to the information input of the memory module , the first, second and third synchronizing outputs of the flight selection module are connected to the first, second and third synchronizing inputs of the identification module and flights of a given year, respectively, and an analysis time interval identification module, one information input of which is connected to another information output of the memory module, another information input of the analysis time interval identification module is connected to the fifth information output of the identification base address identification module, and the synchronization input of the time identification module the analysis interval is connected to the synchronizing output of the memory module, while one output of the identification module of the time int tearing analysis counting input is connected to the base module identification read address, and another output time slot identification module connected to the analysis input of the installation of the memory module to the mounting module entry and selection of flights to another entry identification module the mounting base read address.

The invention is illustrated by drawings, where Fig. 1 is a structural diagram of a system, Fig. 2 shows an example of a specific structural implementation of a module for identifying a base address of a read, Fig. 3 shows an example of a specific constructive implementation of a module for generating read signals of a server database, Fig. 4 shows an example of a specific constructive implementation of the module

flight selection, figure 5 shows an example of a specific structural implementation of the module identifying flights of a given year, figure 6 shows an example of a specific structural implementation of the memory module.

The system (Fig. 1) comprises a module for identifying a base address for reading, a module 2 for generating read signals for a server database, a module 3 for selecting flights, a module 4 for identifying flights for a given year, a module 5 for identifying a module 6 for identifying an analysis time interval.

Figure 1 shows the first 11 and second 12 information inputs of the system, the first 13 and second 14 synchronizing inputs of the system, as well as address 15, the first 16 and second 17 information outputs of the system and synchronizing 18 system output.

The reading base address identification module 1 (FIG. 2) contains registers 20, 21, a decoder 22, a memory unit 23 made in the form of read-only memory (ROM), a counter 24, elements 25-27 AND, elements 28, 29 OR, elements 30-32 delay. The drawing also shows information 33, synchronizing 34, counting 35 and one 36, and the other 37 installation inputs, information 38-42 and synchronizing 43 outputs.

The server database read signal generation module 2 (FIG. 3) comprises a counter 48, an OR element 49, and a delay element 50. The drawing also shows information 51, synchronizing 52 and counting 53 inputs, information 54 and synchronizing 55 outputs.

Flight selection module 3 (FIG. 4) contains counters 60, 61, comparators 62, 63, register 64, OR elements 65, 66, and delay element 67. The drawing also shows information 68-70, installation 71 and synchronizing 72 inputs, information 73-75 and synchronizing 76-78 outputs.

The flight identification module 4 for a given year (FIG. 5) comprises a comparator 81, an OR element 82, and a delay element 83. The drawing also shows information 84, 85 and clock inputs 86-88, as well as module outputs 89, 90.

The memory module 5 (Fig.6) contains elements registers 91-93, counter 94, decoder 95, elements 96-98 AND, group 99 elements OR, elements 100, 101 delay. The drawing also shows information 102, synchronizing 103 and installation 104 inputs, information 105, 106 and synchronizing outputs.

The analysis time interval identification module 6 is implemented as a standard comparator.

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

The system operates as follows.

In the database of the system, economic indicators for each of the completed passenger flights are stored in the form of records having the following structure:

THE CODE THE CODE Flight id Flight Attributes

Moreover, each flight attribute has a structure consisting of two fields (attribute code and attribute value code):

Attribute code Attribute Value Code

The attribute code field contains some digital correspondence of its name. As such a digital correspondence, for example, the serial number of the attribute name can be indicated in the form of some economic indicator in the listing table of the attribute names used.

A sample list of attribute names used is provided in the following table:

Names and attribute codes for each flight Attribute code Attribute name 01 Route name 02 The number of completed flights of this route for a given period 03 Income per flight on this route 04 Passenger Kilometer Income 05 Average flight return rate 06 Average revenue rate for each booking class 07 Complete flight revenue for a given period 08 Percentage of seat occupancy on flight 09 Number of passengers carried 10 Million passenger kilometers eleven Million armchair kilometers

To solve the problems of managing passenger traffic at the workplace of users of an automated system, requests are generated. Each request is a codogram in which the type of the selected analysis attribute in the form of an attribute code (attribute) and its numerical value is indicated as a variable of the mismatch vector, and the year of the beginning of the analysis time interval and its length (duration) as the number of years are indicated, data on which are necessary for making a decision.

To illustrate the system’s operation, as the mismatch vector variable, we choose the average income (average income rate with code 05 in the table of names transfer) per each completed flight.

Thus, the generated user request codogram will have the following structure:

Attribute Code (Attribute Number) The value of the attribute of the average income rate on the flight Year of start of the analysis interval Analysis Time Interval Length The code for the selected attribute is entered. Enter the numerical value of the attribute The numerical value of the year of the beginning of the analysis is introduced Enter the numerical value of the interval as the number of years

From the automated workstation of the user of the system, the requested codogram containing the code of the selected attribute of the average income rate (average return) per flight, the code of the numerical value of the average return per flight, the code of the year when the flight analysis began and the length code of the time interval (number of years) of the analysis of completed flights is received to the information input 11 of the system. From the information input 11 of the system, the requested codogram passes through the information input 33 of the identification base identification module 1 of the reading address and enters the information input of the register 20 of module 1.

The arrival of the request codogram is accompanied by a synchronizing pulse arriving at the synchronizing input 13 of the system. The clock pulse from the input 13 of the system passes through the synchronization input 34 of the module 1 identification of the base address of the read and goes to the synchronization input of the register 20 of the module 1, bringing it received the codogram.

The same clock from the input 13 of the system, passing through the synchronizing input 34 of the module 1 identification of the base address of the reading, is delayed by the element 30 for the response time of the register 20 and is supplied to the synchronizing input of the counter 24, the information input of which from the output 113 of the register 20 receives the digital value of the year code start analyzing completed flights.

In addition, the same synchronizing pulse from the output of the delay element 30 passes through the OR element 28, is delayed by the element 31 while the year code is entered into the counter 24 and the decoder 22 is activated, and is sent to the state survey of elements 25-27 I.

Decoder 22 decodes the digital value of the year code of the beginning of the analysis, giving out one of its outputs high potential and thereby opening one of the elements 25-27 I.

Given the fact that only one of the elements 25-27 I will be open at one input, then, having passed the corresponding element And, the clock pulse goes to the read input of the fixed cell ROM 24, where the base address of the database section is stored for the specified year of the beginning of the analysis of completed flights server (not shown in the drawing), starting from which in this section of memory all flight records and the code of the total number of flight records performed in a given year are stored.

The structure of the read code from the fixed cell ROM 23 for each year of analysis has the following form:

The base address code of the current year section in the server database Code of the total number of records of completed flights of the current year

The base address code of the current year section of the server database from the output of the 117 ROM passes through the output 38 of the module 1 for identifying the base address of the read and goes to the information input 51 of the module 2 for generating the read signals of the server database. The code of the total number of flight records completed this year, from the output of 118 ROMs, is fed to the information input of register 21 of the module 1 for identifying the base read address.

The code of the base address of the current year section of the server database is entered into the module 2 for generating the server database read signals and the code for the total number of records of the current year’s flights in the register 21 of module 1 is provided by the clock from the output of the delay element 31 of module 1.

The clock pulse from the output of element 31 is delayed by element 32 for the duration of reading data from ROM 23 and is supplied to the synchronizing input of register 21, ensuring that the code contains the total number of flight records made in the current year.

The same clock pulse from the output of element 32 passes through the output 43 of module 1 and arrives at the synchronizing input 52 of module 2 for generating the server database read signals, providing the code for the base address of the current year section in counter 48 of module 2.

Based on this impulse, at the output 54 of the module 2 for generating the read signals of the server database and, accordingly, at the information output 15 of the system, the base address for reading the current year section from the server database will be generated.

The same synchronizing pulse from the input 52 of the module 2 for generating the read signals of the server database passes through the element 49 OR, is delayed by the element 50 for the duration of the counter 48 and through the output 55 of the module 2 is issued to the output 18 of the system, from where it goes to the input of the database server interrupt .

With the arrival of this impulse, the database server proceeds to the subprogram for polling the base address of the current year section and reads from the server database the contents of the first cell of the current year section to the information input 12 of the system.

The first record of the current year’s section, read from the server’s database, from the information input 12 of the system goes to the information input 70 of module 3 of flight selection, from where it is sent both to the information input of register 64 and to the information output 75 of module 3.

The first read-out of a section of the current year from the information output 75 of the module 3 of flight selection is sent to the information output 17 of the system, and then sent to the workstation of the user who submitted the request.

The arrival of the first read record of the current year section to the information input of the register 64 is accompanied by a synchronizing pulse of the server, which is fed to the synchronizing input 14 of the system, then goes to the synchronizing input 72 of the module 3 of flight selection and then goes to the synchronizing input of the register 64, entering the first record of the section current year.

The same synchronizing pulse from the input 72 of the flight selection module 3, delayed by the delay element 67 for the time of recording the read in the register 64, is fed to the synchronizing input of the comparator 63 of module 3. With the arrival of this pulse, the comparator 63 compares the code of the requested flight attribute at input 122 with the code the read attribute of the flight at input 123.

The code of the requested flight attribute, received with the request codogram to the register 20 of module 1, from the output 114 of register 20 passes through the information output 40 of module 1 to the information input 69 of module 3 of flight selection and then goes to information input 122 of comparator 63.

The code of the read attribute of the flight, adopted with the codogram of the first read entry in the register 64 of the module 3 flights selection, from the output 120 of the register 64 goes to the input 123 of the comparator 63.

If the attribute codes match, then the comparator 63 of module 3 generates a signal 125 at its output. This signal is supplied to the synchronizing input 129 of the comparator 62, which compares the value of the requested average value of the flight income at the input 127 with the value of the read average value of the flight income received at the input 128 from the output 121 of the register 64.

The value of the requested average value of the flight income received as part of the adopted codogram in the register 20 of module 1, from the output 115 of the register 20 goes to the output 41 of the module 1, is sent to the input 68 of the module 3 and then goes to the input 127 of the comparator 62.

If the numerical value of the average value of the flight income obtained from the server database is greater than or equal to the numerical value set by the user’s request, then an impulse is generated at the output 130 of the comparator 62 of module 3. This pulse is fed to the counting input of the counter 60 for recording the signs of a given value, counting the number of completed flights with a similar numerical value of the sign.

The same impulse, passing through the elements 65 and 66 OR, enters the counting input of the counter 61 for recording records of the current year, which counts on an accrual basis the total number of read records on completed flights of the current year.

In addition, the same synchronizing pulse from the output 78 of module 3 is supplied to the input 88 of the flight identification module 4 of a given year, the OR element 82 passes, it is delayed by the element 83 for the time of operation of the counters 60 and 61, and it arrives at the synchronizing input of the comparator 81 of the module 4.

Based on this signal, comparator 81 compares the total number of records available in the server database in the current year section received at input 84 of module 4 from output 39 of module 1 with the number of read records received at input 85 of module 4 from output 74 of module 3.

If the number of read and viewed database records for completed flights from the section of the current year in the counter 61 of module 3 is less than the total number of records of completed flights of the current year specified by the request, then the comparator 81 generates a signal at the output 89 of module 4, which through the input 53 of module 2 of formation read signals arrives at the counting input of the counter 48, forming the next read address at the output 15 of the system.

In addition, the same synchronizing pulse from the input 53 of module 2 passes through the element 49 OR, is delayed by the element 50 for the duration of the counter 48 and through the output 55 of the module 2 is issued to the output 18 of the system, from where it again goes to the interrupt input of the database server.

With the arrival of this impulse, the database server again proceeds to the routine for polling the next memory address from the current year section and reads its contents to the information input 12 of the system. From the information input 12 of the system, the read contents of the next address are sent through the information input 70 of module 3 to the information input of the register 64, where it is entered by the synchronizing pulse of the server, which is input to the system 14.

If the numerical value of the average flight income obtained from the server’s database is less than the numerical value set by the user’s request, an impulse is generated at the output 131 of the comparator 62 of module 3. This impulse passes through OR elements 65 and 66 and enters the counting input of the counter 61 for recording records of the current year, which counts the cumulative total number of records read on completed flights of the current year.

In addition, the same synchronizing pulse from the output 77 of module 3 is supplied to the input 87 of the flight identification module 4 of a given year, the OR element 82 passes, it is delayed by the element 83 for the time of operation of the counter 61, and is transmitted to the synchronizing input of the comparator 81 of the module 4.

Based on this signal, comparator 81 compares the total number of records available in the server database in the current year section received at input 84 of module 4 from output 39 of module 1 with the number of read records received at input 85 of module 4 from output 74 of module 3.

If the number of read and viewed database records for completed flights from the section of the current year in the counter 61 of module 3 is less than the total number of records of completed flights of the current year specified by the request, then the comparator 81 generates a signal at the output 89 of module 4, which through the input 53 of module 2 of formation read signals arrives at the counting input of the counter 48, forming the next read address at the output 15 of the system.

In addition, the same synchronizing pulse from the input 53 of module 2 passes through the element 49 OR, is delayed by the element 50 for the duration of the counter 48 and through the output 55 of the module 2 is issued to the output 18 of the system, from where it again goes to the interrupt input of the database server.

With the arrival of this impulse, the database server again proceeds to the routine for polling the next memory address from the current year section and reads its contents to the information input 12 of the system. From the information input 12 of the system, the read contents of the next address are sent through the information input 70 of module 3 to the information input of the register 64, where it is entered by the synchronizing pulse of the server, which is input to the system 14.

If the attribute codes do not match, then the comparator 63 of module 3 generates a signal at its output 126, which passes the OR element 66 and enters the counting input of the counter 61, which counts the cumulative total of the read records of completed flights from the current year section of the server database.

In addition, the same synchronizing pulse from the output 76 of module 3 is fed to the input 86 of the flight identification module 4 of the analyzed year, the OR element 82 passes, it is delayed by the element 83 for the duration of the counter 61 operation, and is transmitted to the synchronizing input of the comparator 81 of the module 4.

Based on this signal, comparator 81 compares the total number of records available in the server database in the current year section received at input 84 of module 4 from output 39 of module 1 with the number of read records received at input 85 of module 4 from output 74 of module 3.

If the number of read and viewed database records for completed flights from the section of the current year in counter 61 of module 3 is less than the total number of records of completed flights of the current year specified by the request, then comparator 81 generates a signal at the output 89 of module 4. This signal through the input 53 of the module 2 of the formation of read signals is fed to the counting input of the counter 48, forming the next read address at the output 15 of the system.

In addition, the same synchronizing pulse from the input 53 of module 2 passes through the element 49 OR, is delayed by the element 50 for the duration of the counter 48 and through the output 55 of the module 2 is issued to the output 18 of the system, from where it again goes to the interrupt input of the database server.

With the arrival of this impulse, the database server again proceeds to the routine for polling the next memory address from the current year section and reads its contents to the information input 12 of the system. From the information input 12 of the system, the read contents of the next address are sent through the information input 70 of module 3 to the information input of the register 64, where it is entered by the synchronizing pulse of the server, which is input to the system 14.

The process of reading records of completed flights from the current year section of the server database and counting flight records with a given value of the requested attribute continues until the comparator 81 of the module for identifying flights of a given year fixes the equality of input codes by generating a signal at its 90 output. This equality indicates that all records of completed flights of the current year are reviewed and the number of flights with a given value of a requested feature is counted by a counter 60 for recording features of a given value.

The signal from the output 90 of the flight identification module 4 of a given year, firstly, goes to the input 103 of the memory module 5, passes through the 96 And element, open at the other input with high potential from the output of the decoder 95, and goes to the synchronizing input of the register 91, entering from the entrance, 102 the number of flights with predetermined income indicators, fixed by the counter 60.

The number of flights with predetermined income indicators from the output of the register 91 of the memory module 5 passes through a group of 99 OR elements and is transmitted to the output 105 of the memory module 5, from where it is fed to the information output 16 of the system and then sent to the workstation of the user who issued the request.

Element 96 And will be in the open state because the counter 94 of the memory module 5 is in the initial (zero) state, according to which the decoder 95 generates a high potential, which arrives at one of the inputs of the element 96 I.

Secondly, the same synchronizing pulse from the output 90 of module 4, received through input 103 into memory module 5, is delayed by element 100 for the time the code is entered in register 91 and enters the counting input of counter 94, changing its readings by one. As a result, the decoder 95 removes the high potential from the input of the 96 And element and gives it to the input of the next 97 And the element, opening it one at a time. Thus, a new circuit is prepared for the passage of the synchronizing pulse in the next reading cycle from the input 103 of the module 5 to the synchronization input is now register 92.

In this case, the number of flights with the requested income of the next year of analysis, recorded by the counter 60 of module 3, will be entered in the register 92 for further transmission through the information output 16 of the system to the workstation of the user who submitted the request.

In addition, the synchronizing pulse from the output of the delay element 100 is delayed by the element 101 for the duration of the counter 94 operation and from the output 107 of the module 5 it enters the installation input 37 of the module 1, passes through the OR element 29, and enters the installation input of the register 21 of the module 1, setting it to the initial state.

The same clock pulse from the output 107 of the module 5 is fed to the clock input 110 of the module 6 identification of the time interval of analysis. According to this pulse, the readings of the counter 94, arriving at the information input 108 of the module 6 from the output 106 of the module 5, are compared with the requested value of the analysis time interval coming from the output 116 of the register 20 of the module 1 through the output 42 of the module 1 to the information input 109 of the module 6.

If the readings of the counter 94 of module 5 are less than the value of the requested analysis time interval, then an output is generated at the output 112 of module 6. This pulse through the counting input 35 of module 1 enters both the counting input of the counter 24, setting the code for the next (new) year of analysis at its output, and the input of the element 28 OR of this module.

The code of the next year of analysis from the output of the counter 24 is fed to the input of the decoder 22, which decrypts the code of the next year of analysis and generates a high potential, coming to one of the inputs of one of the elements 25-27 AND, opening it at one input.

Having passed the OR element 28, the synchronizing pulse is delayed by the element 31 for the time of operation of the counter 24 and the decoder 22 and goes to the polling of the state of the elements 25-27 I.

Given the fact that only one of the elements 25-27 I will be open at one input, then, passing the corresponding element And, the synchronizing pulse is fed to the read input of a new fixed memory cell ROM 23, where the base address of the new year section of the server database analysis is stored starting from which in this section of memory all flight records and the code of the total number of flight records performed in the new year are stored.

The base address code of the new year section of the server database from the output 117 of the ROM 23 is supplied through the output 38 of the module 1 to the information input 51 of the module 2 for generating read signals and is supplied to the information input of the counter 48 of this module. The code of the total number of records of flights of the new year with the release of 118 ROM 23 is fed to the information input of the register 20 of the module 1 identification of the base address of reading.

In parallel with this, the clock from the output of element 31 is delayed by element 32 while reading data from ROM 23 and is fed to the clock input of register 21, providing a code for the total number of records of completed flights of the new year. The same clock pulse from the output of the element 32 is fed through the output 43 of the module 1 to the clock input 52 of the module 2 for generating read signals, providing the code entry of the base address of the new year section in the counter 48 of this module.

At the information output 54 of the module 2 for generating read signals and, accordingly, at the information output 15 of the system, the base address for reading the new year section from the server database will be generated.

In addition, the same clock pulse from the input 52 of the module 2 for generating the read signals of the server database passes through the element 49 OR, is delayed by the element 50 for the duration of the counter 48 and through the output 55 of the module 2 is issued to the output 18 of the system, from where it goes to the interrupt input database server.

With the arrival of this impulse, the database server proceeds to the subprogram for polling the base address of the new year’s section and reads from the server database the contents of the first cell of the new year’s section of the analysis to the information input 12 of the system, from where it is sent to the information input 70 of module 3 of flight selection.

From the information input 70 of module 3, the first record of the new year of analysis, read from the server database, goes both to the information input of the register 64 of module 3 of flight selection, where the server clock is fed to the synchronizing input of the system 14, and through the information output of module 75 3 information output 17 of the system, from where it is sent to the workplace of the user who submitted the request.

Thus, with the arrival of the server clock on the synchronizing input 14 of the system, for the next year of analysis, the procedure of reading the attributes of flights and their values from the server’s database and counting in the counter 60 of the selection module 3 flights with an income equal to or greater than the requested value is re-started, followed by entering into the corresponding registers 91-93 of the memory module 5 for transferring them to the automated place of the user who submitted the request.

The described process of selecting data from the server database and analyzing it will continue until module 6 identifies the time interval of the analysis and fixes the equality of the number of scanned years arriving at its information input 108 from the output 106 of memory module 5 with a given value of the length of the time interval analysis received at the information input 109 from the information output 42 of the module 1.

If the values of the time intervals at the inputs 108 and 109 of module 6 are equalized by a clock signal supplied to its input 110 from the output 107 of the memory module 5, a signal is generated at the output 111 of the module 6, which is fed to the installation input 104 of the memory module 5, to the installation input 36 module 1 identification of the base address of the reading and the installation input 71 module 3 selection of flights.

This signal from the installation input 104 of the memory module 5 is supplied to the installation input of the counter 94, returning it to its original state.

The same signal from the installation input 36 of the reading base identification module 1 is supplied to the installation input of the counter 24, returning it to its original state, and through the OR element 29 to the installation input of the register 21, resetting it to its original state.

The same signal from the installation input 71 of the module 3 is supplied to the installation inputs of the counters 60 and 61, preparing them for the next cycle of work.

Thus, the introduction of new nodes and blocks and new structural connections has significantly improved the system’s speed by eliminating the search for data necessary for decision-making throughout the system’s database.

Claims (1)

An automated passenger air traffic management system containing a memory module, one information output of which is the first information output of the system, designed to provide information in the form of the number of flights with a given value of the requested attribute for each year of analysis from a given time interval to the automated place of the user who made the request, a module for generating read signals of a server database, the information output of which is an address output the house of the system intended for issuing a read address to the address input of the database server, and the synchronizing output of the module for generating read signals of the server database is the synchronizing output of the system for issuing read signals for the read input of the database server, characterized in that it contains an identification module the base address of the reading, the information input of which is the first information input of the system, designed to receive a request codogram with automated of workstations of users of the system, the synchronizing input of the identification module of the base address of reading is the first synchronizing input of the system designed to enter the request codogram from the automated workstations of users of the system into the module of identification of the base address of reading, one installation input of the module of identification of the base address of reading is connected to the synchronizing output of the module memory, the first information output of the base read address identification module is connected to to the monitoring input of the server database read signal generation module, and the synchronizing output of the read base address identification module is connected to the synchronizing input of the server database read signal generation module, a flight identification module of a given year, one information input of which is connected to the second information output of the read base address identification module , one output of the flight identification module of a given year is connected to the counting input of the read signal generation module a server database, and the other output of the flight identification module of a given year is connected to the synchronizing input of the memory module, a flight selection module, the first information input of which is the second information input of the system for receiving records from the server database, the second information input of the flight selection module is connected to the third information output of the identification module of the base address of reading, and the third information input of the module of flight selection is connected to the fourth information output during the reading base identification module, the synchronizing input of the flight selection module is the second synchronizing input of the system, intended for recording records read from the server database in the flight selection module, the first information output of the flight selection module is the second information output of the system, for issuing records, read from the server database to the automated workstations of system users, the second information output of the flight selection module is connected to another information input of the flight identification module of the given year, and the third information output of the flight selection module is connected to the information input of the memory module, the first, second and third synchronizing outputs of the flight selection module are connected to the first, second and third synchronizing inputs of the flight identification module of the given year, respectively, and an analysis time interval identification module, one information input of which is connected to another information output of the memory module, another information the input of the analysis time interval identification module is connected to the fifth information output of the read base address identification module, and the synchronization input of the analysis time interval identification module is connected to the synchronization output of the memory module, while one output of the analysis time interval identification module is connected to the counting input of the read base address identification module and the other output of the analysis time interval identification module is connected to the installation input of the memory module, to to the input input of the flight selection module and to another installation input of the identification module of the base reading address.