RU71177U1 - AUTOMATED SYSTEM FOR COLLECTING AND PROCESSING DATA OF TERRITORIALLY DISTRIBUTED OBJECTS - Google Patents

Abstract

The invention relates to computer technology, in particular, to an automated system for collecting and processing data of geographically distributed objects, for example, data on ticket sales by geographically distributed airline agencies.

The technical result is to increase the system performance by localizing the addresses of database records by identifiers of messages received by the system from geographically distributed airline agencies.

The technical result is achieved by the fact that the system comprises a request agency identification module, a base address and sales selection module for a message transfer agency, an input message selection module, a data output channel switching module, a server database address generation module, a summary data readiness identification module, and a correlation module sales results to message receiving interval. 8 ill.

Description

The invention relates to computer technology, in particular, to an automated system for collecting and processing data from geographically distributed objects, for example, data on ticket sales by geographically distributed airline agencies.

For operational analysis and decision-making on passenger air transportation performed for any given period, as a rule, indicators such as the number of airline ticket sales on the corresponding flights and, accordingly, the income attributable to each flight are used.

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

In this regard, the task of collecting and processing data on ticket sales by geographically distributed airline agencies for relevant flights and identifying the most appropriate aircraft layout for obtaining the greatest effect on their use becomes especially urgent.

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

The first of the known systems contains 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 online updating of data stored in memory in the form of relevant documents in real time.

Another system is known, containing a telecommunication network of data processing units, the information inputs of which are connected to data and control units, and the outputs are connected to the first group of memory units, the central processor, the inputs of which are connected to the outputs of the memory units of the first group and data processing units, and the outputs are connected to the inputs of the memory blocks of the second group and data display blocks [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 procedure for updating the data collected by the system from geographically distributed objects of the system via a telecommunication data transmission network is implemented through the procedure of their search in the entire volume of the system database with the subsequent processing of the updated data by the central processor that with large amounts of data the database system inevitably leads to a large investment of time.

The purpose of the invention is to improve the system’s speed by localizing the addresses of database records by identifiers of messages received by the system from geographically distributed airline agencies.

This goal is achieved by the fact that in a known system containing a module for generating a server database address, the information output of which is an address output of the system designed to provide a read (write) address to the address input of a database server, a readiness identification module for summary data, whose information output is it is the first signal output of the system intended for issuing on the display panel of the system information about the number of airline agencies that sent their summary data, and synchronously The enabling output of the aggregate readiness identification module is the second signal output of the system intended for issuing a signal on the readiness of consolidated data from all agencies of the airline, the module for switching data output channels, the group information outputs of which are information outputs of the system group, intended for issuing the number of airline ticket sales per business user place, a request agency identification module has been introduced, the information input of which is the first information input of the system we, designed to receive request codograms from the workstations of users of the system, the first synchronizing input of the request agency identification module is the first synchronizing input of the system designed to receive the synchronization signals of entering request codograms from the workstations of the system users into the request agency identification module, the first information output the request agency identification module is connected to the first information input of the switching module to data delivery analogs, the second information output of the request agency identification module is connected to the first information input of the server database address generation module, the first and second synchronizing outputs of the request agency identification module are connected to the first and second

the synchronizing inputs of the switching module of the channels for issuing data, respectively, and the first and second control outputs of the identification module of the request agency are connected to the first and second control inputs of the switching module of the channels for issuing data, respectively, the selection module of the base address of the message transfer agency, the information input of which is the second information input of the system, designed to receive data on airline ticket sales results from workstations of airline agencies, sync the input of the selection module of the base address of the message transfer agency is the second synchronization input of the system designed to receive the synchronization signals of entering data on the results of airline ticket sales from workstations of airline agencies into the selection module of the base address of the message transfer agency, the first information output of the module of selection of the base address of the transmission agency messages are connected to the second information input of the module for switching data output channels, the second inf the output of the selection module of the base address of the message transfer agency is connected to the second information input of the module for generating the address of the server database, and the first synchronizing output of the module of the base address of the message transfer agency is connected to the first control input of the identification module of the request agency, the module for correlating sales results to the message receiving interval, the first information input of which is the third information input of the system intended for receiving records is read output from the server database, the second information input of the module for correlating sales results to the message receiving interval is connected to the third information output of the module for selecting the base address of the message sending agency, the synchronizing input of the module for correlating sales results to the message receiving interval is the third synchronizing input of the system intended for receiving from the server signals for entering records read from the server database into the module for correlating sales results to the interval ma

messages, the control input of the module for correlating sales results to the message receiving interval is connected to the third control output of the request agency identification module, the first information output of the module for correlating sales results to the message receiving interval is the first information output of the system for issuing airline ticket sales results data, the second information output the module for correlating sales results to the message receiving interval is connected to the third information to the input of the module for switching data output channels, the third information output of the module for correlating sales results to the message receiving interval is connected to the third information input of the module for generating the server database address, the first synchronizing output of the module for correlating sales results for the message receiving interval is connected to the second synchronizing input of the request agency identification module, the second synchronizing output of the module for correlating sales results to the message receiving interval, connected to the second the control input of the request agency identification module, connected to the first synchronizing input of the server database address generation module, and the first and second control outputs of the sales results correlation module of the message receiving interval are connected to the first and second control inputs of the server database address generation module, respectively, the selection module input messages, the information input of which is connected to the fourth information output of the selection module of the base address of the message transfer agency , the first synchronizing input of the input message selection module is connected to the third synchronizing output of the request agency identification module, the second synchronizing input of the input message selection module is connected to the second synchronizing output of the selection module of the base address of the message transfer agency, the third synchronizing input of the input message selection module is connected to the third synchronizing output fourth module for correlating sales results to the message receiving interval, fourth

the synchronizing input of the input message selection module is connected to the synchronizing output of the server database address generation unit, the fifth synchronizing input of the input message selection module is connected to the fourth synchronizing output of the sales result correlation module of the message receiving interval, the first synchronizing output of the input message selection module is the first synchronizing output of the system, designed to issue a read control signal database server, the second synchronizing the first output of the input message selection module, connected to the counting input of the summary readiness identification module, is the second synchronizing output of the system intended for issuing recording control signals to the database server, the third synchronizing output of the input message selection module is connected to the second synchronizing input of the database address generation module server, the fourth clock output of the input message selection module is connected to the third clock input of the formation module I am the address of the server database, while the fifth information output of the selection module of the base address of the message transfer agency is the second information output of the system, intended for issuing airline ticket sales results data by airline agencies.

The invention is illustrated by drawings, in which Fig. 1 shows a structural diagram of a system, Fig. 2 shows an example of a structural embodiment of a request agency identification module, Fig. 3 shows an example of a specific construction of a module for selecting a base address and sales results of a message transfer agency, Fig. .4 - an example of a specific structural embodiment of the input message selection module, FIG. 5 is an example of a specific structural embodiment of a module for switching data output channels, and FIG. 6 is an example of a conc etnogo constructive execution of the module forming a database server address, 7 - an example of a concrete structural embodiment of ready identification module

summary data, Fig. 8 is an example of a specific structural embodiment of a module for correlating sales results to a message receiving interval.

The system (Fig. 1) contains a request agency identification module 1, a base address and sales results selection module of a message transfer agency, an input message selection module 3, a data output channel switching module 4, a server database address generation module 5, a readiness identification module 6 summary data, module 7 correlation of sales results to the interval receiving messages.

Figure 1 shows the first 11, second 12 and third 13 information inputs of the system, the first 14, second 15 and third 16 synchronizing inputs of the system, as well as address 20, first 21 and second 22 information outputs of the system, the first 23 and second 24 synchronizing outputs systems, information outputs 25-27 of the system group, the first 28 and second 29 signal outputs of the system.

The request agency identification module 1 (Fig. 2) contains a memory unit 30 made in the form of read-only memory, a decoder 31, a register 32, triggers 33-34, elements 35-40 AND, element 41 OR, elements 42-44 delays.

The drawing shows information 11, synchronizing 14, 46 and control inputs 47-48, as well as information 49-50, synchronizing 51-53 and control outputs 54-56 module.

Module 2 of the selection of the base address and sales results of the message transfer agency (Fig. 3) contains a memory block 60 made in the form of read-only memory, a decoder 61, a register 62, an adder 63, a trigger 64, elements 65-68 AND, element 69 OR, delay element 70.

The drawing shows information 12 and synchronizing 15 inputs, as well as information 71-75 and synchronizing 76-77 outputs of the module.

The input message selection module 3 (FIG. 4) comprises a decoder 82, OR elements 83-85, AND elements 86-87, delay elements 88-92. In the drawing

Information 93 and synchronizing 94-98 inputs are shown, as well as module 99-102 synchronizing outputs.

Module 4 switching channels for issuing data (Fig. 5) contains a decoder 131, groups 132-136 of AND elements, group 137 of OR elements, element 138 OR. The drawing shows information 141-143, synchronizing 144-145 and controlling inputs 146-147 of the module, as well as information outputs 25-27 of the group of outputs of the module.

Module 5 for generating the server database address (Fig. 6) contains an adder 110, registers 111-112, groups 113-114 of AND elements, groups 115-116 of OR elements, delay element 117.

The drawing shows information 120-122, synchronizing 123-125, controlling 126-127 inputs, as well as address 20 and synchronizing 128 outputs of the module.

Module 6 identification readiness summary data (Fig.7) contains a comparator 150, counter 151, register 152, element 153 delay.

The drawing shows a synchronizing input 155, as well as information 28 and synchronizing 29 outputs of the module.

Module 7 for correlating sales results to the message reception interval (Fig. 8) contains an adder 160, a first counter 161, a second counter 162, a first register 163, a second register 164, a comparator 165, a trigger 166, a group of 167-169 elements of And, an element of 170 And, a group of 171 OR elements, delay elements 172-176.

The drawing shows information 13, 184, synchronizing 16 and controlling 185 inputs, as well as information 21, 186, 187, synchronizing 188-191 and controlling 192-193 outputs of the module.

In this system, geographically distributed airline agencies act as sources of data on the number of tickets sold for a certain time interval.

Messages about the number of tickets sold for the corresponding flights for a certain period of time are transmitted for a certain

regulations, according to which airline agencies transmit the final information on the number of tickets sold at certain points in time, for example, at the beginning of each hour.

We will consider the operation of the system by the example of solving the basic functional problems related to both receiving and processing data on the number of tickets sold for the corresponding flights, and obtaining final data on the results of sales in all territorially distributed agencies of the airline.

When solving the task of collecting and processing data on the number of tickets sold for information input 12 of the system from each agency of the airline in accordance with the established regulations on the data transmission path, messages (codograms) are sequentially received, having the following structure:

the code the code the code the code Sign of input message Airline Agency Id The total number of sales for a given time interval Other sales attributes, including data on the number of seats sold on the corresponding flights of the airline

The code of the agency codogram from the information input 12 of the system is entered into the register 62 of the module 2 for selecting the base address and sales results of the message transmission agency with a synchronizing pulse from the input 15 of the system, which passes to the synchronizing input of the register 62 through the 65 And element, which is open at the second input with a high potential from inverse the output of the trigger 64, which is in the initial state prior to the arrival of the first codogram.

The sign code of the input message from the output 80 of the register 62 passes to the output 74 of the module 2 and enters the input 93 of the module 3, from where it is fed to the input of the decoder 82, which decrypts the sign code of the input message and, in this case, opens the AND element 87 via one input.

In parallel with this, from the output of 81 register 62, the code of the identifier of the agency that sent the message arrives at the information input of the decoder 61, which decrypts the received code, giving out one of its outputs with high potential. For definiteness, we assume that a high potential is received at one input of element 68 I.

At this time, the synchronizing pulse from the output of element 65 AND is delayed by element 70 for the duration of receiving the input message code in register 62 and operation of the decoder 61 and beyond, firstly, it arrives at the single input of trigger 64 and sets it to a single state, in which the output of the trigger 64 to one input of the element 65 And a low potential will be issued blocking the reception of the next message from the information input 12 of the system to the register 62 until the processing of the received message is complete.

Secondly, the same synchronizing pulse from the output of the delay element 70 is supplied to the synchronizing input of the accumulating adder 63. Based on this pulse, the adder 63 generates at its output 71 an cumulative total of the number of ticket sales throughout the airline by sequentially entering register 62 into it from the output 78 code of each total number of sales by the agency that sent the message being processed.

In addition, each code that came with the codogram for the total number of agency sales from the output 72 of module 2 is fed to the input 184 of module 7 and through elements 167 AND of the group that are open at one input with high potential from the inverse output 193 of the trigger 166, which is in the initial state, and through elements 171 OR groups issued to the information output 21 of the system.

The same code for the total number of agency sales from input 184 of module 7 is supplied to one of the inputs of adder 160 of module 7.

Thirdly, the same synchronizing pulse from the output of the delay element 70 passes to the output 76 of the module 2 and through the control input 48 of the module 1 is fed to the zero input of the trigger 33, resetting it to the zero state, in which the low potential from its single output will be closed by one input as an element 35 And blocking the receipt of requests from the information input 11 of the system, and element 36 I, blocking the operation of the module 4 at the input 144 when processing the current message received from the information input 12 of the system.

Fourthly, the same synchronizing pulse from the output of the delay element 70 goes to the interrogation of the state of the elements 66-68 AND,

Considering the fact that only element 68 I will be open at one input, then, having passed this element I, the clock pulse arrives, firstly, at the read input of a fixed memory cell of the permanent storage device 60, where the base address of the server database memory cell is stored, assigned to this agency, and reads its contents through the output of 75 module 2 to the input 121 of module 5.

From the input 121 of module 5, the code of the base address of the agency that sent the input message passes through the elements 115 OR groups to the information inputs of registers 111 and 112.

Secondly, the same pulse of reading the code of the base address of the agency from the output of the 68 element And passes through the 69 element OR to the output 77 of the module 2 and then goes to the input 94 of the module 3, where it is delayed by the delay element 88 for the time of reading the contents of the fixed cell ROM 60, passes through the AND element 87 opened by the decoder 82, and then, firstly, it passes through the OR element 83 to the output 99 of the module 3 and then through the input 123 of the module 5 it goes to the synchronizing input of the register 111, fixing in it the base address of the server database memory cell fixed for this agency.

The same pulse from the output of element 87 And, secondly, passes to the output 100 of module 3, is sent to the input 124 of module 5, and fed to the synchronizing input of register 112, also fixing in it the base address of the memory cell of the server database assigned to this agency .

The same pulse from the output of element 87 AND, thirdly, is delayed by element 90 for the time the agency’s base address is entered in registers 111 and 112 and then through element 84 OR and output 101 of module 3 is issued to the output 23 of the system and then to the input of the first interrupt channel server (not shown in the drawing).

By this signal, the server goes to the database content polling routine at the agency’s base address, which, from the output of register 111, passes through elements 113 AND of the group that are open by high potential arriving at input 126 of module 5 from inverse output 193 of trigger 166 of module 7, located in the original state, and through elements 116 OR groups issued to the address output 20 of the system.

The contents of the base address of the identified agency is read from the server database and through the information input 13 of the system goes to the information input of the register 163 of module 7, where it is entered by the synchronizing pulse of the server fed to the synchronizing input 16 of the system.

It should be noted that before the system started to work, all its nodes and blocks were set to the initial state, and the contents of the server database cells were reset. Therefore, with the arrival of the first message from the identified agency, when reading the contents of its base address to the input of register 163 of module 7, a zero code will be read and, therefore, register 163 will remain in its original state.

The contents of the base address of the identified agency (in this case, it is zero) from the output of the register 163 of module 7, firstly, it is sent to the output of 186 module 7 and then sent to input 143 of module 4, passes through elements 133 AND groups open at input 147 high potential from the inverse output of the trigger 34 of module 1, which is in the initial state, and through the elements 137 OR groups, it goes to the same inputs of the elements 134-136 AND groups.

Secondly, the contents of the base address of the identified agency from the output of the register 163 of module 7 passes through the elements 169 And the groups open at the input 185 with high potential coming to this input through the output 56 of the module 1 from the inverse output of the trigger 33 of the module 1, which is in the initial state , and is fed to one of the inputs of the adder 160, at the other inputs of which is the code of the number of ticket sales according to the agency that sent the message being processed.

The pulse of entering the code into the register 163 from the input 16 of the system is delayed by the delay element 172 for the time the code is entered into the register 163, passes through the element 170 And, also open at the second input with a high potential from the input 185, and arrives at the synchronizing input of the adder 160.

By this impulse, the codes arriving at its inputs are added to the existing adder code. Since at the moment in question the initial codes of adder 160 and register 163 are equal to zero, only the code of the number of ticket sales according to the agency that sent the message to be processed will be entered into adder 160. In the next step, the code for the number of ticket sales according to another agency will be added to this code, and so on, until all airline agencies are interviewed.

Thus, the adder 160 generates the total amount of ticket sales made by all agencies of the airline in a single time interval.

Prior to completing a survey of all airline agencies in a single time interval, only the code of the number of ticket sales according to the agency that sent the current message to be processed is issued for the system information output 21 in each exchange session.

From the information output of the system 21, the code of the number of ticket sales of the identified agency goes to the information input of the server, at the address entrance of which is the base address of this agency from the address output of the system 20.

The resulting total amount of airline ticket sales from the output of adder 160 passes to the information output 21 of the system only if all airline agencies send their messages. This moment is fixed by setting the trigger 166 of module 7 in a single state, in which the high potential from its direct output 192 opens the And 168 elements of the group and passes the total amount of ticket sales, which, after passing through the 17 OR elements of the group, goes to the information output 21 of the system.

The trigger 166 is switched to a single state when the survey of all agencies of the airline, fixed by the comparator 165 of module 7, is completed. For this, the pulse from the output 170 And, delayed by the delay element 173 while the adder 160 operates, is fed to the counting input of the counter 161 of module 7, counting the number of agencies airlines that sent messages in a given time interval.

The same pulse from the output of the delay element 173 is delayed by the delay element 175 for the response time of the counter 161 and is transmitted to the synchronizing input of the comparator 165. By this signal, the comparator 165 compares the number of airline agencies that sent messages and recorded in the counter 161 with the total number specified in the register 164 airline agencies that must send their messages.

The same pulse from the output of the delay element 173 passes to the installation input of the trigger 166, confirming its initial zero state, in which a high potential from the inverse output 193 of the trigger 166 is applied to one of the inputs of the elements 167 AND of the group, thereby passing the code of the number of sales of the identified agency from the input 184 module 7 to the information output 21 of the system.

If the number of agencies that sent messages is less than the specified number stored in the register 164, then a signal is generated at the output of the comparator 165, which passes through the output 191 of the module 7 to the input 96 of the module 3, the OR element passes 85, and from the output 102 of the module 3 24 system output.

From system output 24, a data recording control pulse is fed to the input of the second server interrupt channel. Based on this signal, the server goes to the recording subroutine and writes the sales codes for the given time of day in this agency at the base address on the system address 20 issued by the system to information outputs 21 and 22 (the code for the rest of the agency’s sales attributes is issued from the output 73 modules 2).

The sales codes of another agency, received and allocated from each next received message, will be issued in exactly the same way to the information outputs 21 and 22 of the system and recorded at its base address, identified and issued to the address output 20 of the system. Moreover, each time the sales code according to the agency that sent the message being processed is not only issued to the information output 21 of the system, but is also added to the contents of the adder 160 of module 7.

This spacing of sales codes of agencies at their base addresses and accumulation of sales codes in the adder 160 of module 7 will continue until messages from all agencies of the airline are received and processed.

As soon as the system records the completion of the survey of all agencies of the airline, the information on the system’s output 21 will first be issued the amount of the agency’s sales, the last message in the interval under consideration, and then the total amount of ticket sales accumulated in the adder 160 of module 7 will be issued for all agencies of the airline, obtained in this time interval.

However, the total amount of sales of the time interval from the information output of the system 21 will not be recorded at the base address of the final agency of the interval, but at the so-called modified base address of this agency, also issued to the address output of the system 20.

An agency’s modified base address is the sum of its base address with some offset. The shift number is the sequence number of the interval within which the considered total amount of ticket sales for all airline agencies was obtained.

At the same time, each interval number uniquely corresponds to a digital value of the content code of the counter 162 of module 7. This correspondence is established after the completion of the survey of all agencies at the moment when the content of the counter 162 increases by 1 (incremented).

The described procedure for recording sales codes from a received message at the base addresses of their agencies is carried out in the same way for all airline agencies in each time interval for receiving messages. The completion of the recording procedure in each time interval is controlled by the contents of the register 164 of the module 7 and is fixed when the contents of the counter 161 of the module 7 becomes equal to the contents of the register 164.

Moreover, each time interval, starting from the first, is uniquely determined by the digital correspondence of the contents of the counter 162 of module 7. The transition from the interval to the interval is carried out at the moment of coincidence of the readings of the counter 161 and the register 164 of module 7.

At the moment in question, the contents of the counter are zero and, therefore, the system is in the initial (first) time interval for receiving messages from airline agencies. As soon as the readings of the counter 161 and the register 164 are compared, the comparator 165 generates a signal at its output 201 by the clock pulse from the output of the delay element 175.

This signal, firstly, immediately arrives at the counting input of the counter 162 and increases its content by one, thereby defining for the airline agencies a specific time interval for receiving messages, during which a new total amount of ticket sales was received at the output of adder 160 of module 7 .

In this case, the first unit was entered in counter 162 and, therefore, the value “1” is assigned to the time interval after the first survey of all airline agencies.

This signal, secondly, from the output 190 of module 7 is sent to the input 98 of module 3, the OR element 85 passes and from the output 102 of module 3 is sent to the output 24 of the system.

From system output 24, a data recording control pulse is fed to the input of the second server interrupt channel. By this signal, the server goes to the recording subroutine and writes the sales code of the final agency of the interval from the information outputs 21 and 22 of the system at the base address on the address output 20 of the system, i.e. in this case, the agency’s sales codes will be recorded, sending the last message in the considered interval.

This signal, thirdly, after a delay by the element 174 at the time of operation of the counter 162, it enters the installation input of the counter 161 and returns the counter 161 to its initial state, preparing it for the next next cycle of receiving messages.

The same signal, fourthly, from the output of the delay element 174 is sent to the output 189 of the module 7 and then is sent both to the input 47 of the module 1, setting the trigger 33 of the module 1 in a single state, and to the synchronizing input 125 of the adder 110 of the module 5.

With high potential from its direct output, trigger 33 of module 1 opens one input to elements 35, 36 AND of module 1, and low potential from inverse output 56 of module 1 blocks the operation of module 7 at input 185.

Opening element 35 And one input removes the blocking of receiving messages from airline agencies from the information input 11 of the system to register 32 of module 1 by a synchronizing pulse from input 14 of the system, and opening element 36 And one input removes the blocking of the clock from the input 16 of the system to input 144 of module 4.

Fifthly, the same signal is delayed by the delay element 176 for the time of recording the sales agency codes of the final agency of the interval from the system output 21 to its base address at the system output 20 and goes to the single input of the trigger 166, switching it to a single state, in which the output 192 of the trigger 166 will be high potential, and the inverse output 193 of the trigger 166 will be low.

With a low potential from the inverse output 193 of the trigger 166, elements 113 AND of the module 5 group are closed at one input, thereby blocking the connection of the output of the register 111 of the module 5 to the address output 20 of the system, and, conversely, with a high potential from the direct output 192, the trigger 166 opens the elements 114 AND groups of one input, thereby connecting the output of the adder 110 to the address output 20 of the system.

In addition, with high potential from direct output 192, trigger 166 opens elements 168 And groups one input at a time, passing to the information output 21 of the system from the output of adder 160 the total amount of ticket sales received from all airline agencies in the considered time interval, and low potential from inverse exit 193 closes the elements 167 And the groups of one input, thereby blocking the passage from the input 184 of module 7 to the output 21 of the system of the amount of sales according to some one agency.

The server clock from the input 16 of the system passes to the output 188 of the module 7, is sent to the input 46 of the module 1, is delayed by the delay element 42 for the time the trigger 33 of the module 1 switches to the single state, the 36 And element is open, open at the other input with high potential from the direct output of the trigger 33, and from the output 53 of the module 1 is sent to the input 144 of the module 4.

With the arrival of each pulse at the synchronizing input 125 of the adder 110 of the module 5, the modified base address of the agency is formed at the output of the adder 110 by adding to its base address supplied to one input of the adder from the output of the register 112, a certain offset in the form of the contents of the counter 162 of the module 7 supplied to adder input 122 from output 187 of module 7.

The offset is added to the base address of the agency, the last message from which in the considered time interval was received by the system. The registration of this agency in the counter 161 of module 5 compared the readings of the counter 161 with the data of register 164, which led to the generation of a signal at the output 201 of the comparator 165 of module 5, by which the trigger 166 switched to a single state, and the contents of the counter 162 increased by one.

The adder 110 of module 5 performs the function of modifying the base addresses of agencies in order to bind them to specific values of time intervals within which airline agencies report new data. The formation of modified base addresses is intended for the orderly documentation of all received messages issued by agencies, right in the process of receiving messages.

Since after the first survey of all airline agencies the content of counter 162 is “1”, the modified base address of the agency that sent the final message about the amount of tickets sold is obtained by adding “1” to its base address code.

The received code of the modified base address of this agency from the output of the adder 110 of module 5 passes elements 114 AND groups that are open at the input 127 of module 5 with high potential from the direct output 192 of the trigger 166 of module 7, which is in a single state, elements 116 OR groups and go to the address output 20 systems.

In addition, the clock pulse of the adder 110 of the module 5 from the input 125 of the module 5 is delayed by the delay element 117 for the duration of the operation of the adder 110 and is sent to the input 97 of the module 3 through the output 128 of the module 5, the OR element passes 85, and the output 24 of the module 3 is output 24 system.

From system output 24, a data recording control pulse is fed to the input of the second server interrupt channel. By this signal, the server switches to the subroutine for recording the code for the total amount of ticket sales for all airline agencies of a single time interval from the information outputs of the system 21 to the modified base address at the address output of the system 20.

Thus, all messages sent by each agency of the airline will be sequentially documented with a strict link to its base address, and the contents of the base address of this agency will be the accumulated amount of the number of sales performed at this time in this agency.

In a similar way, the system also works when solving the functional problem of receiving consolidated ticket sales data from all airline agencies, transmitted at a given time, for example, at 00 o’clock of the next day.

When solving this functional problem, the information input 12 of the system in accordance with the established regulations on the data transmission path consistently receives messages (codograms) from airline agencies having the following structure:

The code the code The code The code Sign of input message Airline Agency Id Total sales Other sales attributes, including data on the number of seats sold on the corresponding flights of the airline

The code of the agency codogram from the information input 12 of the system is entered into the register 62 of the module 2 for selecting the base address and sales results of the message transmission agency with a synchronizing pulse from the input 15 of the system, which passes to the synchronizing input of the register 62 through the 65 And element, which is open at the second input with a high potential from inverse the output of the trigger 64, which is in the initial state prior to the arrival of the first codogram.

The sign code of the input message from the output 80 of the register 62 passes to the output 74 of the module 2 and goes to the input 93 of the module 3, from where it is fed to the input of the decoder 82, which decrypts the sign code of the input message and, in this case, opens the AND element 86 via one input.

In parallel with this, from the output of 81 register 62, the code of the identifier of the agency that sent the message arrives at the information input of the decoder 61, which decrypts the received code, giving out one of its outputs with high potential. For definiteness, we assume that a high potential is received at one input of element 66 I.

At this time, the synchronizing pulse from the output of element 65 AND is delayed by element 70 for the time that the input message code is received in register 62 and the decoder 61 is triggered and then, firstly, it arrives at the single input of trigger 64 and sets it to a single state, in which the output of the trigger 64 to one input of the element 65 And a low potential will be issued blocking the reception of the next message from the information input 12 of the system to the register 62 until the processing of the received message is complete.

Secondly, the same synchronizing pulse from the output of the delay element 70 is fed to the synchronizing input of the accumulating adder 63. Based on this pulse, the adder 63 generates on its output 71 an cumulative total of the number of ticket sales throughout the airline by sequentially entering register 62 into it from the output 78 code of each total number of sales by the agency that sent the message being processed.

In addition, each code received with the codogram of the code for the total number of agency sales from the output 72 of module 2 is fed to the input 184 of module 7 and through elements 167 AND of the group, open at one input with high potential from the inverse output 193 of the trigger 166, which is in the initial state, and through elements 171 OR groups issued to the information output 21 of the system. The same code for the total number of agency sales from input 184 of module 7 is supplied to one of the inputs of adder 160 of module 7.

Thirdly, the same synchronizing pulse from the output of the delay element 70 passes to the output 76 of the module 2 and through the control input 48 of the module 1 is fed to the zero input of the trigger 33, resetting it to the zero state, in which the low potential from its single output will be closed by one input as an element 35 And blocking the receipt of requests from the information input 11 of the system, and element 36 I, blocking the operation of module 4 at the input 144 when processing the current message received from the information input 12 of the system.

Fourthly, the same synchronizing pulse from the output of the delay element 70 goes to the interrogation of the state of the elements 66-68 AND,

Given the fact that only element And will be open at one input, then, having passed this element And, the clock pulse arrives, firstly, at the read input of a fixed memory cell of the permanent storage device 60, where the base address of the memory cell of the server database is stored, assigned to this agency, and reads its contents through the output of 75 module 2 to the input 121 of module 5.

From the input 121 of module 5, the code of the base address of the agency that sent the input message passes through the elements 115 OR groups to the information inputs of registers 111 and 112.

Secondly, the same pulse of reading the code of the base address of the agency from the output of element 66 AND passes through element 69 OR to the output 77 of module 2 and then goes to the input 94 of module 3, where it is delayed by the delay element 88 for the duration of reading the contents of the fixed cell ROM 60, passes through the AND element 86 opened by the decoder 82, and then, firstly, it passes through the OR element 83 to the output 99 of the module 3 and then through the input 123 of the module 5 it goes to the synchronizing input of the register 111, fixing in it the base address of the server database memory cell fixed for this agency.

The same pulse from the output of element 86 AND module 3, thirdly, is delayed by element 92 while the agency's base address is entered in register 111 and then through element 85 OR and output 102 of module 3 is output to system output 24 as a data recording control pulse.

The control pulse of the data recording is fed to the input of the second channel of the server interrupt. By this signal, the server goes to the recording subroutine and writes the contents of the summary data from the specified agency, issued by the system to the information outputs 21 and 22, at the base address on the address output 20 of the system.

In addition, each synchronizing pulse of writing the summary data to the database from the output 102 of module 3 is fed to the input 155 of module 6, from where it is fed to the counting input of the counter 151, fixing the number of final data sent by agencies. A register of 152 includes a working number of airline agencies. The readings of the counter 151 through the signal output 28 of the system are displayed on the display panel.

Each synchronizing pulse received at the input 155 of module 6 is delayed by the element 153 for the time of operation of the counter 151 and is fed to the synchronizing input of the comparator 150, which compares a given number of agencies with the number of agencies recorded by the counter 151.

As soon as the readings of the counter 151 and the register 152 are equal, a signal about the readiness of the summary data from all agencies of the airline to summarize the final results will be issued to the second signal output 29 of the system.

As noted above, the end of the operation of receiving messages from all agencies of the airline in a single time interval is fixed by generating a signal at the output 201 of the comparator 165 of module 7. This signal from the output 189 of module 7 is fed to the control 47 input of module 1 and sets the trigger 33 mode to single a state in which the low potential from the inverse output 56 of this trigger is supplied to the input 185 of the module 7 and blocks the operation of the elements 169 And group and element 170 I.

In addition, the high potential from the direct output of the trigger 33 of the module 1 opens the elements 35 and 36 And on one input. This allows the system to go into the mode of issuing certificates on the final data.

The structure of the codogram of the request for relevant certificates has the following form:

THE CODE THE CODE Data Request Workplace Id Type of data requested: - the number of sales performed by the request agency, - the number of sales performed by all airline agencies

The request code from the workplace of the user of the system goes to the information input 11 of module 1, from where it goes to the information inputs of register 32. At the same time, the input 14 of module 1 receives a synchronizing pulse, which, having passed through an element 35 And opened through one input, goes to the synchronizing input of register 32 by entering the request code into it.

The request type code from the output 58 of the register 32 of the module 1 is fed to the input of the decoder 31, which decrypts the type of user request, giving one of its outputs a high potential. For definiteness, we assume that a high potential is received at one input of element 39 I.

In parallel with this, the synchronizing pulse from the output of the 35 And element, delayed by the delay element 43 for the response time of the register 32 and the decoder 31, interrogates the state of the elements 37-40 I.

Considering the fact that only the And element 39 will be open at one input, then, having passed this And element, the clock pulse, firstly, is fed to the read input of a fixed memory cell of a read-only memory device (ROM) 30, where the base address of the memory cell is stored, assigned to the agency whose reference data is requested.

The base address code from the output 50 of module 1 is fed to the input 120 of module 5 and then, having passed the elements of 115 AND groups, it is fed to the inputs of registers 111 and 112.

Secondly, the same read pulse from the output of element 39 AND passes through element 41 OR of module 1 and is fed through input 51 of module 1 to input 95 of module 3, where it is delayed by delay element 89 while reading the contents of a fixed cell in ROM 30.

The same read pulse from the output of the delay element 89 of the module 3, firstly, the OR element 83 passes and the output 99 of the module 3 goes to the input 123 of the module 5 and enters the code of the base address of the request agency in the register 111 of the module 5.

Secondly, the same read pulse from the output of the delay element 89 is delayed by the delay element 91 for the time the code of the base address of the request agency is entered into the register 111, the OR element passes 84, and through the output 101 of the module 3 it goes to the output 23 of the system and then to the input of the first channel server interruptions.

At this signal, the server goes to the subroutine for reading the contents of its database at the base address of the request agency, which passes elements 113 from the output of register 111 of module 5 And the groups open at input 126 with high potential from inverse output 193 of trigger 166 in the initial state, elements 116 OR group and issued to the address output 20 of the system.

The contents of the base address of the requested agency is read from the server database and through the information input 13 of the system goes to the information input of the register 163 of module 7, where it is entered by the server synchronization pulse from the input 16 of module 7.

In addition, the synchronization pulse from the input 16 of the module 7 passes to the output 188 of the module 7 and is sent to the input 46 of the module 1, where it is delayed by the element 42 while the data are entered into the register 163 of the module 7, and then, after passing through the element 36 AND, open high potential with direct output of the register 33 of the module 1, in a single state, is issued to the output 53 of the module 1 as a synchronization pulse issuing a response to a user request.

This pulse from the output 53 of module 1 is supplied to the synchronizing input 144 of module 4, the OR element 138 passes, and then it rewrites the contents of the base address of the requested agency from the output of 186 module 7 through elements 133 AND of the group open at the input 147 with high potential from the inverse output of the trigger 34 of the module 1, in the initial state, elements 137 OR groups and elements And one of the groups 134-136 to the workplace of the user of the system that sent the request through one of the outputs 25-27 of the system.

For this, in parallel with the described process, the code of the identifier of the workplace of the user of the system from the output 49 of module 1 is fed to the input 141 of the module 4 and then to the inputs of the decoder 131 of the module 4, which opens one of the groups 134-136 corresponding to the selected workstation of the user of the system.

The contents of the base address of the requested agency from the output of the register 163 of module 7 is sent to the output of 186 module 7, from where it enters the input 143 of module 4 and then through elements 133 AND groups open at the second input with high potential from the inverse output 55 of trigger 34 of module 1 located in the initial state supplied through the input 147 of the module 4 passes through the elements 137 OR groups and then goes to the inputs of the groups of elements 134-136 I.

After issuing a certificate to the appropriate workstation of the system user, all nodes and elements of the system are initialized by the same pulse from the output of the OR element 138, delayed by the time data was issued (not shown in the drawing to simplify the drawing of the circuit for setting the nodes and blocks of the system in the drawing) .

If the system receives a request of the second type, according to which the user asks for the total amount of sales by all agencies, then the decoder 31 of module 1 in this case opens the 40 AND element one input, and the synchronizing pulse from the output of the delay element 43 passes through the 40 AND element to the single input of the trigger 34, setting it to a single state.

With high potential from the output 54 of module 1, which enters the input 146 of module 4, elements 132 And groups will be open, and elements 133 And groups will be closed. In this case, the output 71 of the adder 63 of the module 2 through the input 142 of the module 4 will be connected to the channel for issuing data to the workplace of the user who sent the request.

The synchronizing pulse from the output of the element 40 AND module 1 is delayed by the delay element 44 for the duration of the trigger 34 and the connection of the output of the adder 63 to the data output channel to the user's workstation and from the output 52 of the module 1, it enters the input 145 of the module 4, the OR element 138 passes, and to the synchronizing input of elements 134-136 AND groups, providing the issuance of the requested data.

Thus, the introduction of new nodes and blocks and new structural connections has significantly improved system performance by eliminating the time costs associated with performing procedures for preliminary recording all the information received in the database, its subsequent search and processing.

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. 05129083, M. cl. G06F 12/00, 15/40, 1992 (prototype).

Claims (1)

An automated system for collecting and processing data of geographically distributed objects, containing a module for generating the server database address, the information output of which is an address output of the system designed to provide a read (write) address to the address input of the database server, a module for identifying the preparedness of summary data, information output which is the first signal output of the system, designed to display on the display panel a system of information about the number of airline agencies, sent your own aggregate data, and the synchronizing output of the aggregate readiness identification module is the second signal output of the system, intended for issuing a signal on the readiness of consolidated data from all airline agencies, the module for switching data output channels, the group information outputs of which are information outputs of the system group, intended for issuing the number of airline ticket sales to a user's workplace, characterized in that it contains a request agency identification module, information the input of which is the first information input of the system intended for receiving request codograms from workstations of users of the system, the first synchronizing input of the identification module of the request agency is the first synchronizing input of the system intended for receiving synchronizing signals of entering request codograms from workstations of system users into the module request agency identification, the first information output of the request agency identification module It is connected to the first information input of the switching module of the data output channels, the second information output of the request agency identification module is connected to the first information input of the server database address generation module, the first and second synchronizing outputs of the request agency identification module are connected to the first and second synchronizing inputs of the issuing channel switching module data, respectively, and the first and second control outputs of the request agency identification module are connected to the first and second to the control inputs of the switching module of the data transmission channels, respectively, the selection module of the base address of the message transfer agency, the information input of which is the second information input of the system, designed to receive data on the results of airline sales from workstations of airline agencies, synchronizing the input of the selection module of the base address of the message transfer agency is the second synchronizing input of the system, intended for receiving synchronizing signals of entry data on the results of the sale of airline tickets from workstations of airline agencies to the selection module of the base address of the message transfer agency, the first information output of the selection module of the base address of the message transmission agency is connected to the second information input of the switching module of the data channels, the second information output of the selection module of the base address of the transmission agency messages is connected to the second information input of the server database address generation module, and the first is synchronized the output of the selection module of the base address of the message transfer agency is connected to the first control input of the request agency identification module, the module for correlating sales results to the message receiving interval, the first information input of which is the third information input of the system designed to receive records read from the server database, the second information the input of the module for correlating sales results to the message receiving interval is connected to the third information output of the base selection module the message sending agency’s synchronizing input of the module for correlating sales results to the message receiving interval is the third synchronizing input of the system intended for receiving from the server synchronizing signals for recording entries read from the server database into the module for correlating sales results with the message receiving interval, the control input of the results correlation module the sales interval for receiving messages is connected to the third control output of the request agency identification module, the first inform the output of the module for correlating sales results to the interval for receiving messages is the first information output of the system intended for the issuance of data of the results of sales of airline tickets by airline agencies, the second information output of the module for correlating sales results for the interval for receiving messages is connected to the third information input of the module for switching the channels for issuing data, the third information output for the module correlation of sales results to the message receiving interval is connected to the third information input the server database address generation module, the first synchronizing output of the sales results correlation module of the message receiving interval is connected to the second synchronizing input of the request agency identification module, the second synchronizing output of the sales results correlation module of the message receiving interval, connected to the second control input of the request agency identification module the first synchronizing input of the server database address generation module, and the first and second control output The modules for correlating sales results to the message reception interval are connected to the first and second control inputs of the server database address generation module, respectively, the input message selection module, the information input of which is connected to the fourth information output of the base address agency of the message sending selection module, the first synchronizing input of the input selection module messages connected to the third synchronizing output of the request agency identification module, the second synchronizing input of the module the selection of input messages is connected to the second synchronizing output of the selection module of the base address of the message transfer agency, the third synchronizing input of the module of selection of input messages is connected to the third synchronizing output of the module for correlating sales results to the message receiving interval, the fourth synchronizing input of the module for selecting input messages is connected to the synchronizing output of the address generation module server database, fifth synchronizing input of input message selection module n with the fourth synchronizing output of the module for correlating sales results to the message receiving interval, the first synchronizing output of the input message selection module is the first synchronizing output of the system intended for issuing read control signals to the database server, the second synchronizing output of the input message selection module is connected to the counting input of the identification module readiness of summary data is the second synchronizing system output intended for issuing to the database server of the recording control signals, the third clock output of the input message selection module is connected to the second clock input of the server database address generation module, the fourth clock output of the input message selection module is connected to the third clock input of the server database address generation module, while the fifth information output of the selection module the base address of the messaging agency is the second information output of the system designed to issue data Ultat airline ticket sales by airline agencies.