RU2559725C1 - System of modelling of virtual community of users - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: system comprises a module of appraisal of results of execution of input transactions, a module of fixing of process of transaction execution, a module of simulated execution of transactions, a module of identification of data flows executable by the transaction, a module of selection of data processing cycles, a module of determining the quantitative parameters of transactions, a module of selection of the intervals of simulated transactions receiving, and a module of the database control.

EFFECT: improving the system performance by localising the addresses of recording the input transactions on identifiers of simulated messages, formation of cumulative sum of the results of transaction processing in real time.

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Description

The invention relates to computing, in particular, to a system for modeling a virtual community of users of the information environment.

The emergence of the phenomenon of network communities is due to the transition from an industrial society to a post-industrial society. One of the key criteria for this transition is the transition to social networks as one of the dominant means of organizing social space. The network structure is a system with a decentralized hierarchy, a wide range of responsibilities, formal relations in which fade into the background.

The Internet space represents not just computer networks and, accordingly, information integration, but, first of all, people who are interconnected and actively communicate in this space together with the information products of their activity, often formed under the influence of requests, needs and interests in virtual interaction.

In the network space, a certain social reality of a new order is being constructed, which includes not only formally existing groups, but also the interaction of social and professional norms and values, the reproduction of the organizational structure of online communities (including the organizational production of professional communities, the definition of professional statuses, and the development of processes intra-group structuring).

Another important feature of network communities is that its participants are not only people, but also software agents whose functions are usually to quickly find and provide the necessary information; performing routine operations, such as sending messages in the absence of the owner; Answers to frequently asked questions; interaction with other software agents.

The study of network communities, their modeling and the development of algorithms for managing them are currently a very urgent task, the difficulty of solving which is associated with the impossibility of directly controlling the behavior of members of the network community and the large number of various relationships between them.

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

The first known system includes means for displaying images of virtual space, means for generating a signal inducing the direction of the user's field of view, means for generating signals for images of virtual space, and a unit for constructing a mathematical model of three-dimensional space and the user in this space (1).

The disadvantage of this system is its limited functionality that does not allow real-time data processing.

Another system is also known, which contains a group of servers that implement, using special software and various means of generating, converting virtual space and displaying it to the user, as well as storing and publishing virtual models of certain locations, virtual infrastructure objects, virtual workplaces, offices, virtual advertising objects , models of people and vehicles (2).

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

Its drawback lies in the structural complexity due to the fact that for each data stream represented by one program, the system is forced to contain a separate data processing channel.

The purpose of the invention is to simplify the system by localizing the addresses of records of parallel programs by identifiers of simulated messages and forming a cumulative total of the results of processing programs in real time.

This goal is achieved by the fact that in a system containing a module for evaluating the results of performing input transactions, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, and the control input of the module for evaluating the results of performing input transactions is the managing input of the system, while the information input of the evaluating module the results of the execution of input transactions is intended to receive parameters for evaluating the performance of input transactions, and the mode synchronizing input For evaluating the results of performing input transactions, it is intended for receiving synchronizing signals of entering parameters for evaluating the performance of input transactions into the module for evaluating the results of performing input transactions, the module for determining the quantitative parameters of transactions, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, while the information input of the determining module quantitative transaction parameters designed to receive server database records, and the synchronization input of the module for determining the quantitative parameters of transactions is designed to receive synchronizing signals for recording server database entries in the module for determining the quantitative parameters of transactions, the information output of the module for determining the quantitative parameters of transactions is the second information output of the system, the module for the simulation of transactions, the synchronizing input of which is connected to the synchronizing output module for evaluating the results of input transactions, and the first and the second information outputs of the simulated transaction execution module are the first and second information outputs of the system, designed to provide the number of simulated messages and their contents to the first information input of the database server, respectively, the database management module, the address output of which is the address output of the system, and one synchronizes the output of the database management module is the first synchronizing output of the system, characterized in that the system contains a module for fixing the process and a transaction execution, the clock input of which is connected to the clock output of the module for evaluating the input transaction results, the control input of the transaction execution fixation module is connected to the control output of the simulation transaction execution module, the information output of the transaction execution fixation module is the fourth information output of the system, the address output of the module fixing the transaction execution process is the second address output of the system, one synchronizing output m The module for fixing the process of transaction execution is the second synchronizing output of the system, and the other synchronizing output of the module for fixing the process of transaction execution is connected to the installation input of the module for simulating transaction execution, the module for identifying data streams of executed transactions, one information input of which is connected to the third information output of the module for simulating transaction another information input of the module for identifying data flows of executable transactions is connected to the fourth information output of the simulation transaction execution module, and the synchronization input of the transactional data flow identification module is connected to the synchronization output of the transactional simulation data module, while one information output of the transactional data flow identification module is connected to the first information input of the database management module, the information output of the module identification of data flows of executable transactions is connected to the second information input m the database management module, one synchronizing output of the executable transaction data stream identification module is the third synchronizing output of the system, and the other synchronizing output of the executing transaction data stream identification module is connected to the first synchronizing input of the database management module, the module for selecting intervals for receiving simulated transactions, the input of which is connected with the second synchronizing input of the system, the first output of the module for selecting intervals for receiving simulated transactions sub it is connected to the second synchronizing input of the module for determining the quantitative parameters of transactions, the other information input of which is connected to the fifth information output of the module for simulating transaction execution, the second output of the module for selecting data processing cycles is the fourth synchronizing output of the system connected to the synchronizing input of the module for fixing the transaction process, and the third the output of the data processing cycle selection module is connected to the installation input of the data stream identification module executable transactions, and a module for selecting intervals for receiving simulated transactions, one synchronizing input of which is connected to the fourth output of the module for selecting cycles of data processing, another synchronizing input of the module for selecting intervals for receiving simulated transactions is connected to the second synchronizing output of the database management module, while the information output of the selection module intervals of reception of simulated transactions connected to the third information input of the database management module, synchronizing in The output of the module for selecting intervals for receiving simulated transactions is connected to the second synchronizing input of the database management module, and the signal output of the module for selecting intervals for receiving simulated transactions is the signal output of the system.

The invention is illustrated by drawings, where Fig. 1 shows a conceptual model of a system, Fig. 2 shows a structural diagram of a system, Fig. 3 shows an example of a specific structural embodiment of a module for evaluating the results of input transactions, Fig. 4 is an example of a specific structural embodiment of a module fixing the transaction execution process, in Fig. 5 is an example of a specific constructive execution of a module of simulated transaction execution, in Fig. 6 is an example of a specific constructive execution of a mode I identify the data flows of executable transactions, Fig. 7 is an example of a specific constructive module for selecting data processing cycles, Fig. 8 is an example of a specific constructive module for determining quantitative parameters of transactions, Fig. 9 is an example of a concrete constructive module for selecting reception intervals simulated transactions, figure 10 is an example of a specific constructive implementation of the database management module.

The system (figure 2) contains a module 1 for evaluating the results of the execution of input transactions, a module 2 for fixing the process of executing transactions, a module 3 for simulating the execution of transactions, a module 4 for identifying data flows of executed transactions, a module 5 for selecting data processing cycles, a module 6 for determining quantitative parameters of transactions, module 7 selection intervals receiving simulated transactions and module 8 database management.

The drawing (figure 2) shows the first 15 and second 16 information inputs of the system, the first 17 and second 18 synchronizing and control 19 inputs of the system, the first 21, second 22, third 23 and fourth 24 information outputs of the system, the first 25 and second 26 address system outputs, as well as the first 27, second 28, third 29 and fourth 30 synchronizing system outputs, and signal 31 system output.

Module 1 (FIG. 3) contains a pulse generator 40, first 41 and second 42 counters, first 43 and second 44 registers, first 45 and second 46 decoders, comparator 47, trigger 48, elements 49-53, element 54 OR, element 55 delays. The drawing shows information 15, synchronizing 17 and controlling 19 inputs, as well as synchronizing 57 and timing 58 outputs.

Module 2 (figure 4) contains the first 76 and second 77 counters, register 78, comparator 79, AND element 80, OR elements 81, 82, delay elements 83, 84. The drawing shows the first 86 and second 87 clock inputs, and a control 88 input, as well as information 89 and address 90 outputs, and the first 91 and second 92 clock outputs.

Module 3 (FIG. 5) comprises a memory unit 60 made in the form of random access memory, a register 61, a counter 62, a trigger 63, an AND element 64, delay elements 65, 66. The drawing shows the synchronizing 67 and installation 68 inputs, as well as the address 69 output of the block, the first 70, second 71, third 72 and fourth 73 information outputs of the block, synchronizing 74 and control output 75 of the block.

Module 4 (FIG. 6) contains a memory unit 95 made in the form of read-only memory, a decoder 96, a counter 97, a trigger 98, AND elements 100-104, OR element 105, delay elements 106-108, and a memory unit 160 made in in the form of read-only memory, a decoder 161, a register 162, AND elements 163-165, delay elements 166, 167. The drawing shows information 110-111, synchronizing 112 and installation 113 inputs, as well as information 115, 116 and synchronizing 114, 117 outputs.

Module 5 (FIG. 7) contains an OR element 139, first 140 and second 141 comparators, first 142 and second 143 counters, first 144 and second 145 registers, delay elements 146-148. The drawing shows the clock input 149, as well as the first 150, second 151, third 152 and fourth 153 clock outputs.

Module 6 (Fig. 8) contains an adder 13 and a register 14. The drawing shows synchronizing 204, 205 and information inputs 206, 207, as well as information output 23.

Module 7 (Fig. 9) contains a counter 175, a register 176, a comparator 177, an OR element 178 and a delay element 179, a decoder 190, a memory unit 191 made in the form of read-only memory, a register 192, AND elements 193-195, elements 196 197 delay. The drawing shows the first 180 and second 181 clock inputs, as well as information 201 and clock 200, 201 inputs, as well as information 200 and clock 201 outputs.

Module 8 (Fig. 10) contains triggers 120-121, groups 122-124 of AND elements, group 125 of OR elements, OR element 126, delay elements 127, 128. The drawing shows information 130-132, synchronizing 133-134 and installation 135 inputs, as well as address 25 output, the first 27 and second 136 synchronization outputs.

All nodes and elements of the system are made on standard potential-impulse elements. To simplify the drawing, the chains of the initial installation of the nodes and blocks of the system in the initial state are not shown.

Distinctive features of the system (figure 1) is the implementation of two areas in which the activities of participants in public consultations on the Internet can be built:

- Improving a structured document - creating your own versions of the source text;

- the generation and selection of ideas that respond to the problem.

Agents operating in the system can belong to different groups and play the roles of administrators, moderators, facilitators, experts and authors of proposals and versions. Authors can contribute by creating ideas aimed at solving the proposed problems, or by creating versions of fragments of the document placed in the system.

Modern technologies allow all participants in joint activities to create their own versions of the text fragment. These versions can be evaluated by other participants, and based on these ratings, the most successful and socially-approved versions can be selected.

The selection process of digital objects (texts) is based on the voting of participants. All votes must be counted, but the impact of each vote depends on the contribution of the participant and how this contribution has been evaluated by the community. The larger the participant’s contribution and the assessment of this contribution by the community, the greater the influence of the participant’s voice within the community.

In the developed system, each participant is given the opportunity to create their own personal versions of small semantic blocks - paragraphs from which articles, chapters and the entire final text of the document are collected. The use of such personalized blocks, which can be discussed and evaluated by the community, and based on these ratings can be embedded in the final version of the finalized draft public document, is a key distinguishing feature of the proposed approach.

Project participants are treated with the text of the document, as with the designer, consisting of items - cubes, which can be discussed, evaluated and modified. Each item presented can be evaluated using the Pro / Cons system, as well as add your own comment.

If the participant believes that the item should be changed and improved, then he can create his own version of this item, which in turn becomes an object for evaluation and comment by other members of the community, and based on this, it can be further developed by its author.

Document modification activities are described by the following sequence of actions:

- experts (representatives of the customer) create the basic version of the document or outline the main sections on which the collection of proposals from participants will take place;

- organizers of joint network activities (facilitators) break the document into fragments - chapters, articles and paragraphs;

- project participants modify paragraphs of the document, offering their own versions;

- project participants evaluate the proposed versions by voting “For / Against”;

- in the final part there is an automatic selection of the versions that have received the highest rating.

The role of users as co-authors and the first testers of a socially significant document at the stage of its writing is difficult to overestimate. Citizens evaluate how much the proposed text will be working, how applicable it is to those life situations in which they exist, and here such testers can be much more useful than official experts who have lost contact with society. Citizens acting as testers and co-authors can offer their own version, which, with the support of other participants, may fall into the new official release of the document.

The system operates as follows.

Setting the parameters for evaluating the solution of the problem is carried out using register 43 of module 1, into which, before starting the system from the workstation of the system administrator, the code value of the attribute of the evaluation parameter is entered, which, from input 15, is entered into register 43 by the synchronizing pulse supplied to input 17 .

In addition, the value of the time period allocated for network discussion and decision making is set in register 44.

The system is started by the start pulse from the control input, which goes to the direct input of trigger 48 of module 1, as a result of which the trigger 48 is set to a single state and with high potential from the direct output opens elements 49, 50 I one input.

A pulse generator 40 is connected to another input of element 49 AND, the pulses from the output of which through element 49 And begin to flow to the counter input of counter 41, the bit-transfer outputs of which are connected to the inputs of the corresponding elements 51-53 AND, the other inputs of which are connected to the corresponding outputs of the decoder 45 whose state is determined by the value of the code in register 43.

The decoder 45 decodes the value of the code of the register 43 and opens the corresponding element 51-53. As a result of this, pulses from the various outputs of the counter 41 pass through the outputs 54 of the OR element 54 to the output 57 of the module 1 and then go to the input 67 of the module 3 through the outputs of the corresponding elements 51-53.

At the same time, from the output of the sensor 46 through the element 50 And the time pulses arrive at the counting input of the counter 42, which counts the operating time of the system. The readings of the counter 42 go to one input of the comparator 47, to the other information input of which the specified code of the simulated time period is supplied from the output of the register 44.

In addition, from the output of element 50 AND, each pulse of the time pulse sensor is delayed by the delay element 55 for the time of operation of the counter 42 and arrives at the synchronizing input of the comparator 47. Based on this pulse, the comparator 47 compares the input codes and only at the moment of their equality generates a signal to stop the system from issuing pulse to the installation input of the trigger 48, returning it to its original state, and thereby closing the element 49 I.

From the output 57 of module 1, synchronizing pulses, which specify the frequency of arrival of simulated data of input transactions that correspond to the conditions of a given risk attribute, pass through input 67 of module 3 to one input of element 64 AND, the other input of which has high potential from the inverse output of trigger 63, which opens the element 64 And one entry.

The synchronizing pulses pass through the And element 64, and, firstly, they arrive at the counting input of the counter 62, which counts the number of simulated input transactions. The arrival of each input pulse, starting from the first to the input of the counter 62, forms the next read address of the next codogram of data of the input transaction stored in the memory of block 60.

Secondly, each synchronizing pulse from the output of element 64 AND is delayed by element 65 for the duration of the counter 62 operation, and is fed to the read input of the memory unit 60, in which simulated encodograms of data from input transactions are stored.

The next codogram of data of the input transaction is read from the memory cell, the next address of which is formed by the counter 62, to the input of the register 61, where it is entered by the synchronizing pulse from the output of the delay element 66.

The simulated message contains the following structure:

Transaction ID Operation Transaction ID The time to complete this operation

From the output 70 of the register 61 of module 3, the entire contents of the register 61 is output 23 for subsequent documentation of the entries in the system database.

From the output 71 of module 1, the identifier of the executed transaction goes to the input 110 of module 4 and then is fed to the input of the decoder 96, which decrypts the code of the transaction identifier and opens one of the elements 100-102 AND one input.

For definiteness, we assume that a high potential is received at one input of element 100 I. At this time, a synchronizing pulse from output 74 of module 3 is supplied to input 111 of module 4 and then to the inputs of elements 103 and 104 I. By this time, trigger 98 is in the original state and at its inverse output there will be a high potential, opening element 104 AND at one input.

As a result of this, the synchronizing pulse from the input 111 of the module 4 passes through the element 104 AND, is delayed by the element 106 while receiving the code of the input transaction in the register 61 of the module 3 and the operation of the decoder 96 of the module 4 and then goes to the interrogation of the state of the elements 100-102 I.

Given the fact that only one element AND will be open at one input, then passing this element AND, the clock pulse arrives, firstly, arrives at the read input of the fixed memory cell of the permanent storage device 95, where the base address of the memory cell is stored in the server database assigned to this transaction, and reads it to the input of the counter 97.

In addition, the same pulse of reading the code of the base address of the program from the output of element 106 is delayed by element 107 for the duration of reading the contents of a fixed ROM cell and arrives at the clock input of the counter 97, fixing in it the base address of the memory cell assigned to this transaction.

The code from the output of the counter 97 through the output 115 is issued to the input 130 of the module 8 and then goes to one of the inputs of elements 122 And groups, the other inputs of which at this point in time from the inverse outputs of the triggers 120 and 121 are high potentials, since both triggers are in the original condition. The base address code through elements 122 AND groups and through elements 125 OR groups is issued to the address output 25 of the system.

In parallel with this, the read pulse from the output of element 107 passes through the OR element 105, then it is delayed by the element 108 while the transaction base address is entered into the counter 97, and then, firstly, from the output of the delay element 108, it is output to the trigger input 98 by setting it is in a single state, in which the 103 And element will be open, and the And element 104 is closed, and, secondly, from the output 114 it is output to the system output 29 and then to the input of the first server interrupt channel (not shown in the drawing).

Based on this signal, the server switches to the subroutine for documenting the first codogram from output 22 to the base address of the transaction, which from the output of counter 97 is issued to address 25 of the system output.

In parallel with the process of documenting the first codogram to the system database, the same synchronizing write pulse from the output of the delay element 108 is supplied to the inputs of the elements 163-165 And, the state of which is determined by the decoder 161, the information input 111 of which receives the identifier code of the transaction operation being performed from the output of the module 72 3. The received code is decrypted by the decoder 161 and opens one input of one of the elements 163-165 I through one input. For definiteness, we assume that a high potential is received at one input of the element 165 I.

At the same time, the synchronizing pulse arrives at the polling of the state of the elements 163-165 I. Given the fact that only one And 165 element will be open on one input, then, having passed this And element, the clock pulse arrives, firstly, at the read input of a fixed cell memory of the permanent storage device 160, where the address of the memory cell is stored in the server database assigned to this transaction, and reads its contents to the information input of the register 162.

Secondly, the same pulse of reading the code of the address of the memory cell in the server database assigned to this transaction is delayed by the delay element 166 for the time it takes to read the contents of the fixed ROM cell, it arrives at the synchronizing input of the register 162, fixing the memory address of this transaction from it first entry of the input message.

The code from the output of the register 162 through the output 16 of the module 4 is fed to the input 131 of the module 8 and then to one of the inputs of the 123 And group 123 elements, the other inputs of which are supplied with potentials from the direct output of trigger 120 and the inverse output of trigger 121.

In parallel with this process, the synchronizing pulse from the output of element 166 is delayed by element 167 for the time the memory address assigned to this transaction is entered from the first record of the input message into register 162, and then from output 117 of module 4 it goes to input 133 of module 8, from where it firstly, it immediately enters the direct input of the trigger 120, setting it to a single state, in which the high potential from the direct output of the trigger 120 opens the elements 123 And groups, and the low potential from the inverse output of the trigger 120 closes elements 122 of group I.

Thus, the elements And 123 of the group will be open, since high potentials come from their direct output from the trigger 120 and from the inverse output of the trigger 121. Due to this, the code of the address of the memory cell assigned to this transaction passes through the elements 123 And groups and elements 125 OR groups to address output 25 of the system.

Secondly, simultaneously with this process, the synchronizing pulse from input 133 passes through the OR element 126, is delayed by the element 127 for the duration of the trigger 120 and the code of the address of the memory cell assigned to this transaction, to the address output 25, and then through the system output 27 to the input of the second channel of the server interrupt (not shown in the drawing).

By this signal, the server switches to the subroutine for reading the contents of the memory cell assigned to this transaction from the input message, which stores the time required to complete this transaction.

The contents of the address of the memory cell assigned to this transaction from the input message is read from the server database and through the information input 16 of the system goes to the information input of the register 14 of module 6, where it is entered by the synchronizing pulse of the server, arriving at the synchronizing input 18.

In addition, the synchronizing pulse from the output of element 127 is delayed by element 128 for the duration of reading the contents of the memory cell, and is supplied to the installation input of trigger 120, returning it to its original state, when it with high potential from the inverse output again opens the elements of the And group 122, connecting the output counter 97 to the address output 25 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 memory cells of the server database assigned to each of the transactions were reset. In this regard, when reading the contents of the database memory cell assigned to the first transaction, a zero code will be read to the input of register 14, and therefore, register 14 will remain in its original state.

The contents of register 14 (in this case, it is equal to zero) goes to the input of the adder 13. At the other input 206 of the adder 13 from the output 73 of module 3, the time code spent on performing such transactions is submitted.

At the same time, the synchronizing server pulse from the input 18 of the system enters the input 149 of module 6, where it is delayed by the element 146 for the time the code is entered into register 14 and then fed to the synchronizing input of the comparator 140, to the information inputs of which codes from the outputs of the counter 142 and the register are supplied 144.

In the register 102 is entered the code of the number of codograms that each of the users of the system must transmit to the data center.

According to the synchronizing pulse from the output of the delay element 146, the comparator 140 compares the input codes, and, given that the number of received records is much less than the number of records to be transmitted during the execution of transactions, a pulse is generated at the output 155 of the comparator 140, which arrives at the synchronizing input of the adder 13, summarizing the temporal performance indicators of the respective transactions.

At the same time, the pulse from the output 155 of the comparator 140 is delayed by the delay element 147 for the response time of the adder 13, and, firstly, from the output 151 of the module 6 is issued to the output 30 of the system and then to the input of the third channel of the server interrupt. By this signal, the server goes to the subroutine for recording the indicator of the elapsed time for the transaction from output 23 of the system to the address of the memory cell assigned to the first operation from address output 25, and issuing a signal to simulate the next input codogram, which is output from output 151 of module 6 87 modules 2.

Secondly, the same pulse from the output of the delay element 147 enters the counting input of the counter 142, fixing the fact of recording in the duration of the time interval, in the system database.

The signal for receiving the next codogram from the input 87 of module 2 is fed to the synchronizing input of the comparator 79, which compares the readings of the counter 76 and the register 78 from this signal. The counting input of the counter 76 through the And 80 element and the input 86 of the module 2 is connected through the output 58 of the module 1 to the pulse sensor time 46. Element 80 And opens with the high potential of trigger 63 of module 3 at the time of the start of the simulation of the first input message from executable transactions.

Therefore, the counter 76 of module 2 measures the time interval that the system spends on processing simulated input messages by counting time pulses that fall in the interval from the moment the simulated input message arrives at the system input until a signal is received about the end of its processing. From the output 89 of module 2, the readings of the counter 79 are output 24.

Before starting the system, the set value of the time interval is set in the register 78, during which the simulated input codogram must be processed by the means of the system, the operation of which is also simulated in real time.

According to the synchronizing pulse from the input 87 of module 2, the comparator 79 compares the input codes, and if the value of the measured time period in the counter 76 is less than or equal to the set value of the register 78, then a pulse is generated at the first output of the comparator 79, which, firstly, through the element 81 OR goes to the installation input of the counter 76 and resets it to its original state.

Secondly, the same pulse passes through the element 82 OR to the output 92 of the module 2 and then through the input 68 of the module 3 it goes to the installation input of the trigger 63, setting it to its original state, returning to which the trigger 63 with a high potential from the inverse output opens the element 64 And, allowing the passage of the next clock pulse from the input 67 to the counting input of the counter 62. The counter 62 generates the next read address of the simulated input codogram, and further operation of the system continues as described above.

If, as a result of comparing the input codes, the comparator 79 records the fact that the processing time of the input messages in the counter 76 is exceeded, then the generated pulse from its other output goes to the counter input of the counter 77, which forms the recording address of the content of the input message, the processing time of which did not fit into the specified limits. The write address code from the output of the counter 77 is issued to the address 26 output. In parallel with this, the synchronizing pulse from the second output of the comparator 79 is delayed by the element 83 for the duration of the formation of the recording address and from the output 91 through the output 28 it enters the input of the fourth channel of the database server interrupt.

By this signal, the database server goes to the subroutine for recording the readings of the counter 76 of module 2 from output 24 and the readings of the register 61 of module 3 from output 21 to the address generated at output 26 of the stand, thereby documenting the occurrence of a malfunction of the system.

The described process continues until the comparator 140 of module 6 fixes the fact that the number of counter entries 142 is equal to the number of operations stored in the register 144.

At this point in time, a signal is generated at the output 156 of the comparator 140, indicating that all records from the input message from the corresponding program are entered in the corresponding memory cells assigned to the corresponding transaction operations. The pulse from the output 156 of the comparator 140, firstly, through the output 152 of the module 6 is fed to the input 112 of the module 4 and then to the installation input of the trigger 98, setting it to its original state, in which the high potential from the inverse output of the trigger 98 opens the element 104 And, and prepares the passage of the synchronizing pulse from the input 111 through the element 103 I.

Secondly, the pulse from the output 156 of the comparator is supplied to the counting input of the counter 143, which counts the number of incoming transactions from users of the system.

In this case, the counter 143 will record the fact of receiving a message from the first transaction. In the register 145, the number of transactions that must send their messages about the results of execution is constantly stored.

In addition, the synchronizing pulse from the output 156 is delayed by the delay element 148 for the response time of the counter 143 and then goes to the synchronizing input of the comparator 141, which compares the readings of the counter 143 and the register 145.

Considering the fact that counter 143 recorded only one transaction that sent its results, its readings at this point in time will be less than the total number of transactions recorded in register 145.

As a result of this, at the first output of the comparator 141, a signal is generated to start simulating the input data of the next transaction, which is transmitted through the OR element 139 to the output 151 of module 6 and then goes to the input 87 of module 2.

The reception of simulated messages of input transactions and their processing as described above continues until the comparator 141 of module 6 fixes the fact of equality of the readings of the counter 143 and register 145 by the formation of a pulse at the output 153.

The appearance of this impulse indicates that the messages of all transactions are documented, and the temporary performance indicators of each of them are summed up, recorded in allocated memory cells assigned to the corresponding transactions, and are ready for display and printing on the display board.

To this end, the pulse from the output 153 of the module 6 is fed to the input 180 of the module 7, where the OR element 178 passes and then fed to the counting input of the counter 175, which records the fact of reading and issuing the final data. In this case, the counter 175 recorded the first unit and its readings are sent to the input of the decoder 190. The number of parallel programs is entered in the register 176 of module 7.

In addition, the pulse from the output of the OR element 178 is delayed by the element 179 for the response time of the counter 175 and is supplied to the synchronizing input of the comparator 177, which compares the readings of the counter 175 and the register 176 by the synchronizing signal.

Considering the fact that counter 175 recorded only one transaction, the execution results of which are to be issued, its readings at this point in time will be less than the total number of transactions recorded in register 176.

As a result of this, at the output of the comparator 177, a signal is generated to start issuing the final data of the first transaction, which is sent to the polling of the state of the elements 193-195 I. The state of these elements is determined by the decoder 190, which decrypts the input code and opens the corresponding element 193-194 I. Suppose that such an element is element 195 I.

First, the synchronization pulse passes through the element 195 AND, and is fed to the read input of a fixed memory cell of the permanent storage device 191, where the address of the memory cell is stored in the server database assigned to the first of the transactions and reads it to the input of register 192. In addition to Moreover, the same pulse is delayed by element 196 for the duration of reading the contents of a fixed ROM cell and arrives at the synchronizing input of register 192, fixing in it the address of the memory cell assigned to the first transaction. The code from the output of the register 192 through the output 201 of the module 7 is issued to the input 132 of the module 8 and then goes to one of the inputs of the elements 124 And groups.

In parallel with this, the pulse from the output of element 196 is delayed by element 197 for the time the memory address is entered into register 192 and then from output 200 it is output to the trigger input 121 via input 134 of module 8, setting it to a single state, in which elements 124 And groups and element 129 And will be open, and elements 122, 123 And of groups will be closed.

Simultaneously with this process, the synchronizing pulse from input 134 is delayed by element 127 for the duration of trigger 121 and the issuance of the address code of the memory cell assigned to the first transaction to address output 25 through elements 124 AND groups and elements 125 OR groups, and then through output 27 the system is issued to the input of the third channel of the server interrupt (not shown in the drawing).

By this signal, the server switches to the subroutine for reading the contents of the memory cell assigned to the first transaction, in which the final performance indicators are stored, and issuing these indicators on the display and print board (not shown in the drawing).

In addition, the same output pulse from the output of element 127 is delayed by element 128 for the duration of the program for reading the final data and issuing them to the display and printing board, and then from the output 136 of module 8 it enters the input 181 of module 7, where OR element 178 passes and then it goes back to the counting input of the counter 175, increasing its readings by one. The new counter 175 reads the input to the decoder 190.

In addition, the pulse from the output of the OR element 178 is delayed by the element 175 for the duration of the counter 175 operation and again goes to the synchronizing input of the comparator 177, which compares the readings of the counter 175 and the register 176 by the synchronizing signal.

Considering the fact that counter 175 has now recorded the second transaction, the execution results of which are to be issued, its readings at this point in time will be less than the total number of transactions recorded in register 176.

As a result of this, at the output of the comparator 177, a signal is generated to start issuing the final execution data of the next transaction, which is sent to the polling of the state of elements 193-195 I.

The state of these elements is determined by the decoder 190, which decrypts the incoming code and opens the corresponding element 193-195 I. Suppose that this element is now element 193 I.

First, the synchronizing pulse passes through the element 193 AND and is fed to the read input of the fixed cell of the permanent storage device 191, where the address of the memory cell is stored in the server database assigned to the next transaction, and reads it to the input of the register 192.

In addition, the same pulse is delayed by element 196 for the duration of reading the contents of a fixed ROM cell and arrives at the synchronizing input of register 192, fixing in it the address of the memory cell assigned to the next transaction. The code from the output of the register 192 through the output 201 of the module 7 is issued to the input 132 of the module 8 and then appears on one of the inputs of the elements 124 And groups.

In parallel with this, the pulse from the output of element 196 is delayed by element 197 for the time the memory cell address is entered into register 192 and then from output 200 of module 7, it is output to module trigger input 121 via input 134 of module 8, confirming its single state, in which elements 124 AND groups and element 129 And will be open, and elements 122, 123 And of groups will be closed.

Simultaneously with this process, the synchronizing pulse from input 134 is delayed by element 127 for the duration of trigger 121 and the issuance of the address code of the memory cell assigned to the next transaction to the address input 25 of the system through elements 124 AND groups and elements 125 OR groups, and then through the output 27 of the system again goes to the input of the fourth channel of the server interrupt (not shown in the drawing).

By this signal, the server again switches to the subroutine for reading the contents of the memory cell assigned to the next transaction, which stores the final performance indicators, on the display panel and print (not shown in the drawing).

In addition, the same data output pulse from the output of element 127 is delayed by element 128 for the duration of the program for reading the final data and outputting them to the display and printing board and then from the output 136 of module 8 is again fed to the input 181 of module 7.

This process continues until the readings of the counter 175 become equal to the readings of the register 176. This moment will be fixed by the comparator 177 by issuing a pulse to output 199, from which this synchronizing pulse is firstly output to the system output 31 as an end signal the output of the final data, and, secondly, it goes to the installation input of the trigger 121 and returns it to its original state.

Thus, the introduction of new modules and new constructive connections made it possible to significantly simplify the system by localizing the addresses of records of input transactions by identifiers of simulated messages and forming an accumulating result of transaction processing results in real time.

Information sources

1. RF patent No. 2106695, 08/14/1996

2. Patent WO No. 200830135 A1, September 4, 2006.

Claims (1)

A system for modeling a virtual community of users, containing a module for evaluating the results of performing input transactions, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, and the control input of the module for evaluating the results of performing input transactions is the managing input of the system, while the information input of the module for evaluating the results of performing input transaction is designed to receive parameters for evaluating the performance of input transactions, and synchronize The input input of the module for evaluating the results of the execution of input transactions is intended for receiving synchronizing signals for entering the parameters for evaluating the performance of the input transactions in the module for evaluating the results of the execution of input transactions, the module for determining the quantitative parameters of transactions, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, while the information input module for determining the quantitative parameters of transactions is designed to receive records of the database server, and the synchronizing input of the module for determining the quantitative parameters of transactions is designed to receive synchronizing signals for recording server database entries in the module for determining the quantitative parameters of transactions, the information output of the module for determining the quantitative parameters of transactions is the second information output of the system, the module for the simulation of transactions, the synchronizing input of which is connected with the synchronizing output of the module for evaluating the results of the input trans functions, and the first and second information outputs of the transaction simulation module are the first and second information outputs of the system, designed to provide the number of simulated messages and their contents to the first information input of the database server, respectively, the database management module, the address output of which is the address output of the system and one synchronizing output of the database management module is the first synchronizing output of the system, characterized in that the system contains a phi module of the transaction execution process, the clock input of which is connected to the clock output of the module for evaluating the input transaction results, the control input of the transaction execution process fixation module is connected to the control output of the simulation transaction execution module, the information output of the transaction execution process fixation module is the fourth information output of the system, address output transaction fixation module is the second address output of the system, one synchronization The output output of the transaction execution fixation module is the second synchronizing output of the system, and the other synchronization output of the transaction execution fixation module is connected to the installation input of the simulation transaction execution module, the identification module of the data flows of executed transactions, one information input of which is connected to the third information output of the simulation execution module transactions, another information input of the module for identifying data flows of executed transactions connected to the fourth information output of the transaction simulation module, and the synchronizing input of the transaction execution data identification module is connected to the synchronization output of the transaction simulation data module, while one information output of the executed transaction data identification module is connected to the first information input of the database management module, information the output of the module for identifying data flows of executable transactions is connected to the second information to the input of the database management module, one synchronizing output of the module for identifying executable transaction data streams is the third synchronizing output of the system, and the other synchronizing output of the module for identifying executing transaction data streams is connected to the first synchronizing input of the database management module, module for selecting intervals for receiving simulated transactions, input which is connected to the second synchronizing input of the system, the first output of the module for selecting intervals of reception of simulated The transaction is connected to the second synchronizing input of the module for determining the quantitative parameters of transactions, the other information input of which is connected to the fifth information output of the module for simulating transaction execution, the second output of the module for selecting data processing cycles is the fourth synchronizing output of the system connected to the synchronizing input of the module for fixing the transaction process, and the third output of the data processing cycle selection module is connected to the installation input of the identification module p of data flows of executed transactions, and a module for selecting intervals for receiving simulated transactions, one synchronizing input of which is connected to the fourth output of the module for selecting cycles of data processing, another synchronizing input of module for selecting intervals for receiving simulated transactions is connected to the second synchronizing output of the database management module, while the information output the module for selecting intervals for receiving simulated transactions is connected to the third information input of the database management module, sync the output of the module for selecting intervals for receiving simulated transactions is connected to the second synchronizing input of the module for managing the database, and the signal output of the module for selecting intervals for receiving simulated transactions is the signal output of the system.

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