RU166653U1 - TECHNOLOGICAL PLATFORM OF INTERDEPARTMENTAL ELECTRONIC INTERACTION OF TERRITORIAL DISTRIBUTED OBJECTS - Google Patents

Abstract

The technological platform of interdepartmental electronic interaction of geographically distributed objects, containing a selection block of input message sections, the information and synchronizing inputs of which are the first information and synchronizing inputs of the technological platform, respectively, while the first information input of the technological platform is designed to receive messages from objects, and the first synchronizing input of the technological platforms designed for receiving synchronizing signals entering messages of objects into the block of selection of message sections, and the control outputs of the group of block of selection of message sections are connected to the corresponding control inputs of switching blocks of input and output messages, respectively, a memory block whose output is connected to the information input of switching block of output messages, the outputs of which are information outputs of the group technological platform, a unit for generating signals for reading and writing data, the clock input of which is connected to the first synchronizer the input of the technological platform, the first synchronizing output of the unit for generating signals for reading and writing data is connected to the input for controlling the reading of the data of the memory unit, the second synchronizing output for the unit for generating signals for reading and writing data is connected to the synchronizing input for the switching unit for output messages, and the third synchronizing output for the unit for generating signals reading and writing data is connected to the input control data recording of the memory block, while the information inputs of the group block

Description

The utility model relates to computer technology, in particular to the technological platform of interagency electronic interaction of geographically distributed objects in the provision of public services.

In carrying out activities related to the performance of public functions and the provision of public services, public authorities and other organizations involved in this activity carry out interagency information interaction aimed at meeting the information needs arising from the exercise of these state powers.

In order to carry out interdepartmental electronic interaction in electronic form, in accordance with the Decree of the Government of the Russian Federation of June 8, 2011 No. 451, a federal state information system was created - an interdepartmental electronic interaction system (hereinafter referred to as SMEV). At the same time, as a result of the operation of the system, it was revealed that the automation of interagency cooperation is mainly aimed at providing public services to citizens and organizations / representatives of the business community, and the problems of counteracting illegal financial transactions remained unresolved.

The main ones include:

- lack of a single protected information exchange circuit with an access level “for official use”;

- lack of a single data exchange format;

- lack of a single access point and a single reporting point;

- the lack of a uniform procedure for accessing data;

- lack of general reference information and universal identifiers.

To solve these problems, it is necessary to create a unified transport service, taking into account the fullest possible use of the existing infrastructure, providing information and technological interaction of information systems, including interdepartmental electronic interaction systems.

A single transport service should play the role of a single dispatcher and router of unified requests of federal executive authorities to ensure interaction in the framework of countering illegal financial transactions.

At the same time, a single transport service should be a single entry point for requests and providing information by sending requests for the required data to the appropriate department to form a unified response based on its database.

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

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

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

Another system is known that contains data processing units, the information inputs of which are connected to the data reception 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 with 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 is that it cannot provide reliable delimitation of user access to various sections of current messages that are received in response to relevant requests.

The purpose of the utility model is to increase the reliability of restricting user access to sections of relevant messages by securing department identifiers to those sections of messages that were received in response to requests.

This goal is achieved by the fact that in a known system containing a block for selecting sections of input messages, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, respectively, while the first information input of the system is designed to receive messages of system objects, and the first synchronizing input of the system is intended for receiving synchronizing signals for entering messages of system objects into the block for selecting message sections, and control outputs of the group of blocks the selection of message sections is connected to the corresponding control inputs of the input and output message switching blocks, respectively, the memory block, the output of which is connected to the information input of the output message switching block, the outputs of which are the information outputs of the system group, the read and write signal generation block, whose clock input connected to the first synchronizing input of the system, the first synchronizing output of the unit for generating read and write data signals to the input of the data reading control unit of the memory unit, the second synchronizing output of the unit for generating signals for reading and writing data is connected to the synchronizing input of the unit for switching output signals, and the third synchronizing output of the unit for generating signals for reading and writing data is connected to the control input for writing data of the memory unit, the inputs of the group of the input message switching unit are the information inputs of the system group, and the output of the input message switching unit is connected to by the memory block input, a message section address selection block has been introduced, the information input of which is the second information input of the system intended for receiving a text message section code from a user's workstation, the first synchronizing input of the message section address selection block is connected to the first synchronizing system input, the address the output of the address selection section of the message sections is connected to the address input of the memory block, and the synchronizing output of the address selection block ow of the message sections is connected to the synchronizing input of the block for generating signals for reading and writing data, the message section identification block, one information input of which is connected to the information output of the message section selection block, the other information input of the message section identification block is connected to the information output of the message section address selection block, the first synchronizing input of the message section identification block is connected to the synchronizing output of the message section selection block openings, and the clock input of the unit for identifying message sections is connected to the clock output of the unit for generating signals for reading and writing data, and the unit for determining the time intervals of identification, the clock input of which is the second clock input of the system, designed to receive shear pulses, one clock input of the block for determining time intervals the identification is connected to the first output of the message section identification block, another synchronizing input of the time identification block of the identification intervals is connected to the second output of the identification section of the message sections, the first output of the identification of time intervals for identification is the signal output of the system designed to give signals about attempts to unauthorized access to the message sections, the second output of the identification of time intervals for identification of messages is connected to the second synchronization input of the identification section messages, and the third output of the identification time interval determination unit is connected to the control input shift detecting unit identification message sections, wherein the third identification messages output block sections connected to the second input of the synchronizing unit selection section addresses messages.

The essence of the utility model is illustrated by drawings, where in FIG. 1 is a structural diagram of a technological platform; FIG. 2 is a block diagram of a message section selection block; FIG. 3 is a block diagram of a message section identification unit; FIG. 4 is a block diagram of an identification time interval determination unit; FIG. 5 is a block diagram of a selection of addresses of message sections; FIG. 6 is a structural diagram of a unit for generating read and write data signals; FIG. 7 is a block diagram of an input data switching unit; FIG. 8 is a block diagram of an output data switching unit; FIG. 9 illustrates an example implementation of a particular system architecture; FIG. 10 shows an example of connecting information systems of departments to a data center, FIG. 11 is a diagram of an electronic message transmitted to SMEV taking into account unified blocks.

The structural diagram of the technological platform (Fig. 1) contains a block 1 for selecting message sections, a block 2 for identifying message sections, a block 3 for determining time intervals for identification, a block 4 for selecting addresses of message sections, a block 5 for generating read and write signals, a memory block 6, a block 7 switching input messages and block 8 switching output messages.

In FIG. 1 shows the first 11 and second 12 information inputs of a technology platform, a group of 13-15 information inputs of a technology platform, synchronizing 16 and clocking 17 inputs, as well as a group of 19-21 information outputs, and a signal 22 output of the technology platform.

Block 1 (Fig. 2) contains a register 25, a decoder 26, a memory block 27, made in the form of read-only memory (ROM), elements 28-30 And, elements 31-32 delay. The drawing shows information 11, synchronizing 16 inputs, as well as information 34, synchronizing 35 and a group of 36-38 control outputs.

Block 2 (Fig. 3) contains a register 40, a comparator 41, elements 42-43 OR. The drawing also shows the first 45 and second 46 information inputs, the first 47 and second 48 clock inputs, the shift control input 49, the clock input 50, as well as the first 52, second 53 and third 54 outputs.

Block 3 (Fig. 4) contains counters 56-57, trigger 58, AND element 59, and OR element 60. The drawing shows a clock input 17, synchronizing 62 and installation 63 inputs, as well as signal 22, first 65 and second 66 synchronization outputs.

Block 4 (Fig. 5) contains registers 70-71, a decoder 72, a memory block 73 made in the form of read-only memory (ROM), elements 74-76 AND, elements 77-78 delay. The drawing also shows information 12, first 79 and second 80 synchronization inputs, as well as information 81, address 82 and synchronizing 83 outputs.

Block 5 (Fig. 6) contains triggers 85-86, elements 87-89 AND, elements 90-91 delay. The drawing also shows the timing 93 and timing 94 inputs, as well as timing 95, first 96, second 97 and third 98 timing outputs.

Block 6 (Fig. 1) is made in the form of random access memory having an address 100 and information 101 inputs, a data reading control input 102 and a data recording control input 103, as well as an information output 104.

Block 7 (Fig. 7) contains a group of 105-107 AND elements, as well as a group of 108 OR elements. The drawing also shows a group of 13-15 information inputs of the block, a group of 110 - 112 synchronizing inputs of the block, as well as information 113 output.

Block 8 (Fig. 8) contains a group of 115-117 elements I. The drawing also shows the information input 120 of the block, the group 121-122 of the control inputs of the block, synchronizing 124 the input of the block, and also the group 19-21 of the information outputs of the block.

The technology platform works as follows.

The system of interdepartmental electronic interaction (SMEV) connects geographically dispersed objects that are heterogeneous in terms of technical characteristics: information systems of departments participating in the interaction, a public services portal, multifunctional centers for the provision of public services to the public, and information systems of other participants.

To illustrate in FIG. Figure 9 shows the architecture of an interdepartmental electronic interaction (SMEV) system. It includes the following components: a universal transport medium, a register of identification codes matching, ensuring the interaction of various systems using different identification systems, a service calculator (receiving data on benefits provided to each citizen), an electronic appointment record, a smart-based applicants identification system -cards, actually an interdepartmental system of interaction, providing automatic access to departmental systems, a certification center, a personal account the user's Internet, which provides information on the results of the service, an analytics and reporting system and an information security system.

In FIG. 10 shows an example of connecting participants to the SMEV secure data network, and FIG. 11 shows an example of an electronic message transmitted to the SMEV taking into account the unified blocks.

In a distributed data processing information network, a group of performers from various departments is working on the creation and transmission of messages of various messages in the formation of electronic documents provided as a public service, forming the corresponding messages in the data processing center. A fundamental requirement for such an organization of user work is strict confidentiality, in which each contractor should have access only to those sections of messages that he is charged with processing.

To this end, during the work of the performers, the identification code of the performer (user) is received in the register 25 of block 1 from the information input 11 of the technology platform by a clock pulse from the input 16 of the system.

At the same time, in the register 70 of block 4 from the information input 12 of the technological platform, the code of the document section with which the user is to work is received through the input 79 of block 4 by the same synchronizing signal from the input 16 of the technological platform.

In addition, the synchronizing pulse from the input 16 of the technological platform enters the input 94 of block 5 and then enters both the single input of the trigger 85 and one input of the element 87 I.

Considering the fact that before the arrival of this pulse, trigger 85 was in the initial state, in which a low potential was formed at the unit output, which closes the 87 And element at one input, then the synchronizing pulse from input 94 through the 87 And element will not pass. Thus, under the influence of the first synchronizing pulse, the trigger 85 is set to a single state.

In parallel, from the output of the register 25 of block 1, the user identification code is sent to the information input of the decoder 26, and the synchronizing pulse from the input 16 of the technological platform is delayed by the delay element 31 for the time the user identification code is entered into the register 25 and the decoder 26 operates and then goes to the inputs elements 28-30 I.

The decoder 26 decrypts the incoming code and prepares the signal path from the output of the delay element 31, opening one of the elements 28-30 I. For definiteness, we assume that a high potential is received at one input of the element 30 I.

In parallel with this, the synchronizing pulse from the output of element 31 of block 1 interrogates the state of elements 28-30 I.

Given the fact that only element 30 And will be open at one input, then passing this element And, the clock pulse from the input 16 of the platform goes, firstly, to the read input of a fixed memory cell of a read-only memory 27, where a set of sequential numbers of sections of the document, presented in the form of binary decimal codes, access to editing the contents of which is allowed to the user with this identification number.

The code of consecutive numbers of sections of the document, presented in the form of binary decimal codes, access to editing the contents of which is allowed to the user with this identification number, is read from the memory of block 27 and from output 34 goes to the information input 45 of block 2.

Secondly, the same read pulse from the output of the delay element 31 is delayed by the element 32 for the duration of reading the contents of the fixed cell ROM 27 and then from the output 35 of the block 2 is fed to the clock input 47 of the block 2.

Further, this pulse from the synchronizing input 47 of block 2 is fed to the synchronizing input of the shift register 40, entering into it the code of sequential numbers of sections of the document, presented in the form of binary-decimal codes, access to editing of the contents of which is allowed to the user with this identification number.

From the output of the shift register 40, the first of the codes represented in the upper bits of the shift register 40 is fed to one information input of the comparator 41, the other information input of which 46 from the output 81 of block 4 receives the section number code removed from the output of the register 70 of block 4, requested for processing and also represented in binary decimal.

To synchronize the process of comparing codes in the comparator 41, a pulse is used from the input 47 of block 2, which, passing through the OR element 42, is fed to the synchronizing input of the comparator 41.

If the codes of register 70 of block 4 and the upper bits of shift register 40 are the same, then a signal is generated at the output 53 of comparator 41, which, firstly, passes to the input 63 of block 3 and then to the installation input of counter 57, confirming its initial state, and, secondly, the OR element 43 passes and from the output 54 of the block 2 enters the input 80 of the block 4.

At this point in time, the decoder 72 decrypts the code of the number of the requested section, stored in the register 70 of block 4 and fed to the input of the decoder 72, giving out one of its outputs a high potential, opening one input from one of the elements 74-75 I. For definiteness, put that high potential entered one input of element 75 I.

As a result of this, the clock pulse from the input 80 of block 4 passes through the element 75 AND to the read input of a fixed memory cell (ROM) 73 of block 4 and reads its contents into register 71, where the read code is entered by the clock pulse from the clock input 80 of block 4, the delayed element 77 delays on the time of reading the code from a fixed cell ROM 73.

In a fixed cell ROM 73 is stored the address code of the section of the document, which calls the user to edit.

After entering the code of the address of the document section in the register 71, this code from the output 82 of block 4 is fed to the address input 100 of block 6 of the memory.

In parallel with this, the pulse from the output of the delay element 77, delayed by the delay element 78 for the time the address code is entered in the register 71, from the output 83 of block 4 passes through the input 93 of block 5 through the element 88 AND, open at the other input with a high potential from the inverse output of the trigger 86 , the output 96 of block 5 and then goes to the input 102 of the data reading control at the address set on the address 100 input of the block 6.

From the output 104 of block 6, the read section of the document through the input 120 of block 8 is fed to one of the inputs of the elements And groups 115, 116 and 117, the other inputs of which are connected to the corresponding outputs of the decoder 26 of block 1. Given that in our example, the decoder 26 gave a high potential to Since the first output 36 is connected to the And element 28 and to the input 121 of the And elements of group 115, then the And elements of group 115 will be open.

In parallel with this, the synchronizing pulse from the output of element 88 AND block 5 is delayed by the delay element 91 while reading a section of the document from block 6, and then from the output 97 of block 5 through the input 124 of block 8 it goes to the third input of the elements AND of group 115, rewriting the contents of the document section through the exit 19 of block 8 to the automated workstation (AWP) of the user who begins to process it.

After the editing process of the corresponding section of the document is completed, the user again sends the identification code of the user through the information input 11 of the platform to register 25 of block 1 and the code of the section of the processed document through the information input 12 of the platform to register 70 from the workstation as described above, using the synchronizing pulse at the synchronizing input 16 of the platform block 4.

The only difference is that now the synchronizing pulse from the synchronizing input 16 of the platform, arriving at the synchronizing input 94 of block 5, immediately passes element 87 And, open at the other input with high potential from the direct output of the trigger 85, which is in a single state, and, firstly, it arrives at the single input of trigger 86, setting it to a single state, in which element 88 And will be closed one at a low potential from the inverse output of trigger 86, and element 89 And will be opened with high potential from the direct output t iggera 86.

At this point in time, the contents of the processed section of the document were also received from the user's workstation via the corresponding information input 13-15 of the platform.

For definiteness, suppose that such an information input is platform input 13, and the contents of the processed section of the document through the AND elements of group 105 of block 7, open at the other input with high potential from the output 36 of block 1, comes through the OR elements of group 108 and the output 113 of block 7 to information input unit 6 memory.

Secondly, the pulse from the output of element 87 AND through the output 95 of block 5 goes to the input 50 of block 2, where the OR element 43 passes, and from the output 54 of block 2 it again goes to the input 80 of block 4.

At this point in time, the decoder 72 decrypts the code of the requested partition number, stored in the register 70 of block 4 and fed to the input of the decoder 72, giving out one of its outputs a high potential, opening one input of one of the elements 74-75 I. In our example, high the potential entered one input of element 75 I.

As a result of this, the synchronizing pulse from the input 80 of block 4 passes through the element 75 AND to the read input of the fixed memory cell of the ROM 73 and reads its contents into the register 71, where the read code is entered by the synchronizing pulse delayed by the element 77 during the reading of the code from the ROM 73.

In a fixed cell ROM 73 is stored the address code of the section of the document that the user calls. After entering the code of the address of the document section in the register 71, this code from the output 82 of the block 4 is supplied to the address input 100 of the memory block 6, and the pulse from the output of the element 77, delayed by the delay element 78 for the time the address code is entered into the register 71, from the output 83 of block 4 through the input 93 of block 5 now passes through the element 89 AND, open at the other input with a high potential from the direct output of the trigger 86, to the output 98 of block 5 and then goes to the input 103 to control the recording of data coming from the input 101 at the address set on address 100 block inlet 6.

In addition, the synchronizing pulse from the output of the 89 And element is delayed by the delay element 90 while recording the processed section of the document in the memory unit 6 and is supplied both to the installation inputs of the triggers 85 and 86, returning them to their original state, and to the installation inputs of the registers and counters of the system (platforms).

To simplify the drawing, the installation circuits of the registers and platform counters are not shown in the drawing (Fig. 1).

If during the comparison by the comparator 41 of block 2, the input codes from the inputs 45 and 46 of block 2 did not match, then the comparator 41 generates a signal at the output 52, which, through the input 62 of block 3, goes to the single input of trigger 58 and sets it to a single state, when in which the trigger 58 with a high potential from the direct output opens the element 59 And, the input of which from the input 17 of the system is constantly supplied with shear pulses.

The shift pulses begin to flow through element 59 And, firstly, to the output 66 of block 3 and then to the input 49 of the shift register 40 of block 2, where the code in the register 40 is bitwise shifted.

Secondly, the shear pulses from the output of the element 59 AND are counted by the counter 56. The size of the counter 56 is selected based on the dimension of the binary-decimal representation of the numbering of document sections in such a way that after counting the specified number of shifts, as a result of which one section number is in the upper register bits 40 of the shift is replaced by the next one in order, at the output of the transfer of the counter 56 an impulse appears, fixing the fact of presenting the next message section number.

This pulse, firstly, through the OR element 60 is supplied to the installation input of the trigger 58, returning it to its original state and thereby blocking the further passage of shear pulses through the element 59 I.

Secondly, the transfer pulse from the output of the counter 56 is fed to the counting input of the counter 57, counting the number of presented document section numbers.

And finally, thirdly, the transfer pulse from the output of the counter 56 enters through the output 66 of block 3 to the input 48 of block 2, where the OR element 42 passes, and is again fed to the synchronizing input of the comparator 41, which compares the code from the input 45 of block 2 with the next code is the section number of the document from input 46.

If the codes being compared coincided, then an impulse appears at the output 53 of the comparator 41 of block 2 and the process of the technological platform is repeated as described above.

If the code of the section number of the document from input 45 of block 2 and the next code in the upper bits of register 70 from input 46 of block 2 did not match again, then the pulse 52 appears again at the output 52 of block 2. This pulse through the input 62 of block 3 again sets the trigger 58 in a single state, in which the trigger 58 opens the element 59 And, and allows the passage of the pulse pulses from input 17 to output 66 and counter 56. As a result, the described process of comparing codes from inputs 45 and 46 is repeated.

If the section of the document requested by the user is not among the sections to which he was admitted, then after comparing all the codes that were in shift register 40, the counter 57, counting the number of permitted sections of the document presented, will record the fact that the codes do not match by issuing an impulse carry on your way out.

This pulse, firstly, through the output 22 of the technological platform is issued as a signal of an attempt to unauthorized access to the corresponding section of the message.

Secondly, through the OR element 60, it enters the installation input of the trigger 58, returning it to its original state and blocking, thereby, the passage of shear pulses through the element 59 I.

Thus, unlike well-known technical solutions, this technological platform provides reliable delimitation of user access to various sections of messages.

Information sources:

1. Patent WO 2005/029312 (03/31/2005).

2. Patent WO 2005/015424 (02.17.2005) (prototype).

Claims (1)

A technological platform for interdepartmental electronic interaction of geographically distributed objects, containing a selection block of input message sections, the information and synchronizing inputs of which are the first information and synchronizing inputs of the technological platform, respectively, while the first information input of the technological platform is designed to receive messages from objects, and the first synchronizing input of the technological platforms designed for receiving synchronizing signals entering messages of objects into the block of selection of message sections, and the control outputs of the group of block of selection of message sections are connected to the corresponding control inputs of switching blocks of input and output messages, respectively, a memory block whose output is connected to the information input of switching block of output messages, the outputs of which are information outputs of the group technological platform, a unit for generating signals for reading and writing data, the clock input of which is connected to the first synchronizer the input of the technological platform, the first synchronizing output of the unit for generating signals for reading and writing data is connected to the input for controlling the reading of the data of the memory unit, the second synchronizing output for the unit for generating signals for reading and writing data is connected to the synchronizing input for the switching unit for output messages, and the third synchronizing output for the unit for generating signals reading and writing data is connected to the control input of data recording of the memory block, while the information inputs of the group of the block com Utilities of input messages are information inputs of the technology platform group, and the output of the input message switching unit is connected to the information input of the memory unit, characterized in that the technology platform contains a block for selecting addresses of message sections, the information input of which is the second information input of the technology platform for receiving a code section of a text message from workstations of users of objects, the first synchronizing input of the block the message section addresses section is connected to the first synchronizing input of the technological platform, the address output of the message section address selection block is connected to the address input of the memory unit, and the synchronizing output of the message section address selection block is connected to the synchronizing input of the read and write signal generation block, message section identification block , one information input of which is connected to the information output of the block for selecting message sections, another information input of the block the message section identification block is connected to the information output of the message section identification block, the first synchronizing input of the message section identification block is connected to the synchronizing output of the message section selection block, and the clock input of the message section identification block is connected to the clock output of the read and write signal generation block, and the block determination of identification time intervals, the clock input of which is the second synchronizing input of the technological of the first platform intended for receiving shear pulses, one synchronizing input of the identification time interval determination unit is connected to the first output of the message section identification unit, the other synchronizing input of the identification time interval determination unit is connected to the second output of the message section identification unit, the first output of the identification time interval determination unit It is a signal output of a technological platform intended for issuing signals of unsanctioned attempts access to the message sections, the second output of the identification time interval determination unit is connected to the second synchronizing input of the message section identification unit, and the third output of the identification time interval determination unit is connected to a shift control input of the message section identification unit, while the third output of the message section identification unit is connected with the second synchronizing input of the message section address selection block.

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