RU70015U1 - AUTHORIZED JUDICIAL BUSINESS SYSTEM OF THE SUPREME COURT - Google Patents

Abstract

The utility model relates to computer technology, in particular, to the automated system of judicial proceedings of the Supreme Court. The technical result is to increase the speed of the system by excluding the search for updated data on the entire database of court records management and localizing the search only by the temporary and distinctive features of the identifiers of the courts. The technical result is achieved by the fact that the system comprises a module for identifying reference addresses of database records, a module for generating addresses for reading database data, a module for managing writing and reading database data, a module for selecting addresses for reading database data, a module for addressing data management, a source address identification module data request, and a module for issuing data to user workstations. 8 ill.

Description

The utility model relates to computer technology, in particular, to the automated system of judicial proceedings of the Supreme Court of the Russian Federation.

The automated system of judicial proceedings of the Supreme Court is a geographically distributed automated information system designed to create a single information space for courts of general jurisdiction and the system of the Judicial Department under the Supreme Court of the Russian Federation, providing information and technological support for court proceedings on the principles of maintaining the required balance between the needs of citizens, society and states in a free exchange of information and is necessary E restrictions on the dissemination of information.

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 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, comprising a central processing unit, the inputs of which are connected to the memory blocks and to the data preparation and input units, and the outputs are connected to the corresponding memory blocks, the data processing unit, the information inputs of which are connected to the outputs of the corresponding memory blocks, the synchronizing inputs are connected to control outputs of the central processing unit, and the output of the block is the information output of the system (2).

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

Its disadvantage lies in the low speed of the system, due to the fact that the execution of procedures for issuing certificates at the request of users is carried out by searching for information on the requested court cases throughout the database, which, with large amounts of data that the database contains

court cases, inevitably leads to unreasonably large costs of time to obtain the required information.

The purpose of the utility model is to increase the speed of the system by eliminating the search for court data across the entire server database and localizing the search only by the temporal and distinguishing features of the court identifier.

This goal is achieved by the fact that in a known system containing a module for identifying reference addresses of database records, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, and one information output of the module for identifying reference addresses of database records is an information output of the system, the selection module read addresses of the database data, the information and synchronization inputs of which are the second information and synchronization inputs and systems, a module for issuing data to automated workstations of users, the information and synchronizing inputs of which are the third information and synchronizing inputs of the system, and the outputs are the information outputs of the system group, the module for managing the recording and reading of database data, whose address output is the address output of the system, and the synchronizing outputs of writing and reading are the first and second synchronizing outputs of the system, respectively, the address generation module is introduced reading data from a database whose information inputs of the group are connected to the corresponding information outputs of the group of the identification module of the reference addresses of the database records, the synchronizing input of the address generation module

the database data reader is connected to the synchronizing output of the database record reference address identification module, the information output of the database data reading address generation module is connected to one information input of the database data writing and reading control module, and the synchronizing output of the database data reading address generation module is connected to the first synchronizing input of the control module for writing and reading database data, while the other information input of the module For writing and reading database data, it is connected to the first information output of the database data read address selection module, and the second synchronizing input of the database data write and read control module is connected to the synchronizing output of the database data read address selection module, the data addressing control module, the first and the second control inputs of which are the first and second control inputs of the system, the information input of the data addressing control module is connected to the second the information output of the module for selecting addresses for reading database data, the synchronizing input of the module for controlling addresses of data is connected to the synchronizing output for the module for selecting addresses for reading database data, and the outputs of the module for controlling addresses for data are connected to the first and second control inputs of the module for controlling writing and reading database data , and the identification module of the address of the data request source, the information input of which is connected to the third information output of the address selection module s database read data, and a clock input connected to the third

synchronizing input of the system, while the information output of the identification module for the address of the data request source is connected to another information input of the module for issuing the data to the user workstations, and the synchronizing output of the module for identifying the address of the data request source is connected to the other synchronizing input of the data issuing module for the user workstations .

The essence of the utility model is illustrated by drawings, in which Fig. 1 shows a structural diagram of a system, Fig. 2 shows an example of a specific constructive implementation of a module for identifying reference addresses of database records, Fig. 3 shows an example of a specific constructive implementation of a module for generating database read addresses 4, an example of a specific constructive implementation of a control module for writing and reading database data, FIG. 5 is an example of a specific constructive implementation of a village module section of the read addresses of the database data, Fig. 6 shows an example of a specific constructive implementation of the data addressing control module, Fig. 7 illustrates an example of a specific constructive implementation of the identification module of the address of the data request source, Fig. data on user workstations.

The system (Fig. 1) comprises a module 1 for identifying reference addresses of database records, a module 2 for generating addresses for reading data from a database, a module 3 for controlling writing and reading database data, a module 4 for address selection

reading data from a database, a module 5 for managing data addressing, a module 6 for identifying the address of the source of the data request, and a module 7 for issuing data to the user's workstations.

Figure 1 shows the first 15, second 16 and third 17 information inputs of the system, the first 18, second 19 and third 20 synchronizing inputs of the system, the first 21 and second 22 control inputs of the system, information 23 and address 24 system outputs, the first 31 and second 32 synchronizing system outputs, and a group of information 33-35 system outputs.

The module 1 identifies the reference addresses of database records (Fig. 2) contains a register 40, a memory unit 41 made in the form of read-only memory, a decoder 42, a register 43, elements 44-49 AND, counters 50-52, groups 53-55 elements And, the group of elements is 56 OR. The drawing shows information 15 and synchronizing 18 inputs, as well as information 23, 65-68 outputs, and synchronizing 66 outputs.

The module 2 for generating addresses for reading database data (Fig. 3) comprises a memory unit 110 made in the form of read-only memory, a decoder 111, a register 112, elements 113-115 And, elements 116, 117 delay, the first 118 and second 119 adders On the drawing also shows information 101, address 102, 103 and synchronizing 104 inputs, as well as information 105 and synchronizing 106 outputs.

The database data writing and reading control module 3 (Fig. 4) contains a reversible counter 140, a trigger 141, groups 144 - 145 AND elements, a group 146 OR elements, elements 142-143 AND, elements 147-148 OR, and elements 149-151

delays. The drawing shows information 152, 153 inputs, synchronizing 154, 155 inputs, the first 156 and second 157 counting inputs, as well as information 158 output and outputs of the record 159 and read 160.

The database data reading address selection address selection module 4 (FIG. 5) comprises a register 63, a memory block 64 configured as read-only memory, a decoder 65, AND elements 66-68, OR element 69, and a delay element 70. The drawing also shows information 16 and synchronizing 19 inputs of the block, as well as synchronizing 73 and information 74, 75 outputs.

The data addressing control module 5 (FIG. 6) comprises a register 122, a counter 123, comparators 124, 125, first 126, second 127 and third 128 OR elements, first 129, second 130 and third 131 delay elements, as well as OR element 138 . The drawing also shows the information 132 and synchronizing 133 inputs of the block, the first 134 and second 135 control inputs of the block, as well as the control outputs 136 and 137 of the block.

The data request source identification module 6 (Fig. 7) contains a memory unit 76 made in the form of read-only memory, a decoder 77, AND elements 78-80, OR element 81, and delay elements 82-83. The drawing also shows information 84 and synchronizing 20 inputs, as well as information 85 and synchronizing 86 outputs.

The module 7 for issuing data to user workstations (Fig. 8) contains registers 160, 161, a decoder 162, a first 163, a second 164 and a third 165 of a group of And elements, a delay element 166. The drawing also shows information 17 and 167

inputs synchronizing 20 and 169 inputs, as well as information outputs 170-173 outputs of the group of module outputs.

We consider the operation of the system as an example of fulfilling user requests for viewing and retrieving court records.

In the process of conducting judicial proceedings, each court of the corresponding instance sends a codogram to the address of a higher court, having the following structure:

THE CODE THE CODE THE CODE Identifier start date ATTRIBUTES and trial judicial CONTENT clerical work Affairs

After the receipt of this codogram at the information input 15, this codogram is entered into the register 40 by a synchronizing pulse supplied to the synchronizing input 18 of the system. From the first output 61 of register 1, the full content of the codogram is issued to the information output 23 of the system.

From the second output 62 of the register 40, the code of the court identifier is fed to the information input of the decoder 42, which decrypts the code of the court identifier and gives one of its outputs a high potential, which goes to the corresponding inputs of elements 44-49 I.

For definiteness, suppose that the high potential from the first output of the decoder 42 will open the elements 44 and 47 And, and in addition, the high potential from the first output of the decoder will be issued to the input of the elements 53 And group.

The clock pulse from the input 18 of the system, delayed by the element 57 during the operation of the decoder 42, is supplied, firstly, through the element 44 AND to the input of the fixed cell ROM 41, which stores the reference address of the database memory area allocated for recording all cases received from this court, and reads its contents to the input of the register 43.

Secondly, the same pulse delayed by element 58 while reading the base address from ROM 41 is fed to the clock input of register 43 and enters the code of the base address, which from the output 65 of register 43 goes to the input 102 of module 2. To another input 101 of module 2 from the output 68 of module 1, a code arrives from the output of the counter 50 through 53 I elements open at the second output with high potential from the first output of the decoder 42.

The same synchronizing pulse delayed by element 59 while the base address code was entered in register 43, firstly, through the output 66 of module 1, it arrives at the synchronizing input 104 of module 2, providing a summation of the reference address and counter code 50. Considering, however, that Since the counter 50 was in its initial state and its readings are equal to zero, as a result of summing, the code of the reference address at the output of adder 118 of module 2 will remain unchanged and will go to one input of adder 119.

Secondly, the synchronizing pulse from the output of the element 59 of module 1 is delayed by the element 60 for the duration of the operation of the adder 118, and then, after passing the element 47 And, it enters the counting input of the counter 50, increasing its readings by one and thereby forming the readings of the counter 50 k the next cycle of work.

In parallel with the process described above, the code for the date of transfer of the case from the output 68 of the register 40 goes to the information input 101 of the module 2 and then goes to the input of the decoder 111, which decrypts the date code and gives out one of its outputs a high potential coming to the corresponding inputs of the elements 113-115 AND.

For definiteness, let us assume that element 113 I will be opened with high potential from the first output of decoder 111.

The synchronizing pulse from the output 66 of module 1 is supplied, firstly, to the input 104 of module 2 and then through element 113 and fed to the input of a fixed cell ROM 110, which stores the address of the memory zone of the database allocated for recording all cases in a specified period of time , and reads its contents to the input of register 112.

Secondly, the clock pulse from the input 104 of module 2 is delayed by the element 116 for the time of reading the code of the time period and goes to the clock input of the register 112 and enters the code of the time period, which from the output of the register 112 goes to another information input of the adder 119. Recall that at the first input of the adder 119 from the output of the adder 118 receives the code of the reference address of the court.

The synchronizing pulse from the output of element 116, delayed by element 117 for the time the code of the time period is entered into register 112, is transmitted to the synchronizing input of adder 119, fixing the total address of the record, which from the output 105 of module 2 is supplied to the input 152 of module 3. In addition, the synchronizing pulse the output 106 of module 2 is supplied to the synchronizing input 154 of module 3.

From the input 152 of module 3, the generated write address is supplied to one of the inputs of the 144 And elements of the first group, which will be opened by high potential from the inverse output of the trigger 141. The state of the trigger 141 is determined by the synchronizing write pulses supplied to the input 154 of the module 3, and the synchronizing read pulses received input 155 of module 3.

Considering that at the given time, the input 154 of module 3 received a synchronizing write pulse, then passing to the installation input of trigger 141, this pulse will confirm it to its original state, in which high potential from the inverse output of trigger 141 will be opened as elements 144 And groups, so is element 142 I.

The code of the recording address from the output of the 144 AND group elements passes through the OR elements 146 of the group to the information input of the counter 140, to the synchronizing input of which there is a pulse from the input 154 of module 3, which has passed through the chain: the OR element 147 and the delay element 149, delaying the pulse for the time adder 119.

In addition, the same pulse from the output of the delay element 149 passes through the And element 142, is delayed by the element 150 for the time the address code is entered into the counter 140, and then from the output 159 through the system output 31 it enters the input of the first channel of the database server interrupt.

With the arrival of this signal, the database server switches to the routine for recording the readings of register 40 of module 1 from output 23 of the system at the address generated at output 24 of the system.

The procedure for recording subsequent codograms of court cases from the exits of other geographically distributed courts to the entrance of this court is carried out in a similar way.

To obtain relevant information from the server database, each user who has access to the relevant sections of the court case database, forms a request codogram at his automated workstation and presses the "View" button.

The structure of the codogram formed at the user's workstations has the following structure:

THE CODE THE CODE Court ID, in Arm ID office work which user the requested case is located

In this case, the codes of the vessel identifier and the user workstation identifier through the input 16 enter the register 63 of the module 4, where they are entered by the synchronizing pulse from the input 19. From the first output of the register 63, the code of the vessel identifier is input to the decoder 65.

The decoder 65 decrypts the code of the identifier of the vessel, giving out one of its outputs high potential. For definiteness, we assume that a high potential is received at one input of element 67 I.

In parallel with this, the synchronizing pulse from input 19 is delayed by element 70 for the time the code is entered in register 2 and the decoder 65 is triggered, and then it polls the states of elements 66-68 I.

Given the fact that only one element And will be open at one input, then passing through this element And, the clock pulse arrives, firstly, at the read input of a fixed memory cell of read-only memory 64.

In a fixed memory cell, the code of the reference address of the first memory cell of the court is stored in the server database and the code of the number of case records in the server database sent by this court.

The structure of the codogram in the memory cell has the following structure:

THE CODE THE CODE Reference Address Code Record Number Code first memory cell this court in the database selected court in the database server server

The code of the reference address of the first memory cell and the code of the number of records of the cases of this court are read from the fixed memory cell and fed to the outputs 74, 75 of module 4, respectively.

In parallel with this, the readout pulse of the fixed memory cell of module 4, passing through the element 69 OR, immediately from the output 73 of module 4 goes through the input 155 of module 3 to the single input of trigger 141 and sets it to a single state, in which it opens one input of elements 145 And groups, as well as element 143 And, while at the same time closing low-potential elements 144 And groups together with element 142 I from their inverse output.

The code of the reference address of the first memory cell from the output 74 of the module 4 through the input 153 of the module 3 and the elements 145 And, as well as the elements 146 OR group is fed to the information input of the reverse counter 140.

The same clock pulse from the input 155 of module 3 passes through the OR element 147, is delayed by the delay element 149 for the time it takes to read the code from the memory block 64 and the trigger 141 fires, and enters the clock input of the reverse counter 140, fixing the reference address code of the first memory cell in the counter of this seller in the server database.

In addition, the same pulse from the output of the delay element 149 passes through the AND element 143, the OR element 148, and is delayed by the delay element 151 for the time that the reference address code was entered into the counter 140 and, through the system output 32, it is fed to the input of the second server interrupt channel.

According to this signal, the server goes to the subprogram for interrogating the contents of the memory cell at the address generated on the address output of the system 24 and issuing the read data through the system input 17 to the information input of the register 160 of module 7, where they are entered by the server clock input to the system input 20.

Simultaneously with this process, the code of the number of case records of the selected court from the output 75 of module 4 is fed through the input 132 of the module 5 to the information input of the register 122, where it is also entered by the pulse from the output 73 of the module 4 through the input 133.

In parallel with this, the user workstation identifier code from the output 76 of the register 63 of the module 4 is fed through the input 84 of the module 6 to the input of the decoder 77.

The decoder 77 decodes the user ID code of the user workstation, giving out one of its outputs high potential.

For definiteness, we assume that a high potential is received at one input of element 78 I. In parallel with this, the synchronizing pulse from input 20 is delayed by element 82 for the duration of operation of the decoder 77, and then it polls the states of elements 78-80 I.

Considering the fact that only the And element 78 will be open at one input, then passing through this And element, the clock pulse arrives, firstly, at the read input of a fixed memory cell of the permanent storage device 76, where the address code of the user workstation is stored, and reads it through the output 85 of module 6 to the information input 167 of module 7.

Secondly, the same read pulse, having passed the OR element 81, is delayed by the delay element 83 for the reading time of the contents of the fixed ROM cell. Further, from the output 86 of module 6, this pulse enters through the input 169 of module 7 to the synchronizing input of register 161, fixing the address code of the user's workstation in the register.

The decoder 162 decrypts the address code of the user's workstation and with high potential at one of its outputs opens the And elements of one of the groups 163-165. At the same time, the pulse from the input 169 of the module 7, the delayed delay element 166 for the duration of the decoder 162, the code of the first read from the output of the register 160, passing through the corresponding group of elements And 163-165, through the corresponding output 170-173 of the module 7 and, respectively outputs 35-37 of the system are issued to the user's workstation.

The user is given the opportunity to view all the records of the cases of the selected court in the server database and get the information he needs.

To do this, the user uses the "Forward" and "Back" keys, the signals from which are fed to the control inputs 21, 22 of the system, respectively.

When you press the “Forward” key, the pulse from the input 21 of the system passes through the input 134 of module 5 to the counting input of the counter 123, fixing the number of views of records. This number of views of case records is compared by comparator 124 with the number of case records of this court recorded in register 122, by the signal from the output of delay element 129, which delays the pulse from input 134 for the duration of counter 123 operation.

If the number of views is less than the specified number of court records in the register 122, then the output 175 of the comparator 124 generates a pulse transmitted through the element 127 OR to the output 136 of the module 5 and then through the input 156 of block 3 to the summing input of the reversing counter 140, forming the next read address output 24.

In addition, the same pulse, passing through the OR element 148 and the delay element 151, delaying this pulse for the duration of the operation of the reverse counter, passes to the output of module 3 3 and then to output 32 and again goes to the input of the second channel of the server interrupt.

By this signal, the server again switches to the subprogram for polling the contents of the memory cell at the address generated on the address output of the system 24 and issuing the read data through the input 17 of the system to the information input of module 7, where they are entered by the synchronizing pulse of the server to the input 20 of the system.

The described process of reading court records from the server database and issuing them to the user's workstation continues until the number of records in register 122 of module 5 is equal to the number of case records read from the database recorded by counter 123. The indicated moment will be recorded issuing a pulse at the output of 176 comparator 124.

The pulse from the output 176 of the comparator 124, firstly, through the element 128 OR enters the output 137 of the module 11 and then to the subtracting input 157 of the counter 140, reducing its readings by one. In addition, the same pulse passing through the OR element 148 and the delay element 151, delaying this pulse for the duration of the operation of the reverse counter, passes to the output 32 of the system and then again goes to the input of the second channel of the server interrupt.

By this signal, the server again switches to the subprogram for polling the contents of the memory cell at the address generated on the address output of the system 24 and issuing the read data through the input 17 of the system to the information input of module 7, where they are entered by the synchronizing pulse of the server to the input 20 of the system.

Secondly, the same pulse from the output 176 of the comparator 124 is delayed by the delay element 130 for the duration of the pulse and through the OR element 126 is fed to the subtracting input of the counter 111, reducing its readings.

After that, the user can switch to the reverse view of court records by pressing the "Back" button.

The pulse from the input 22 through the input 135 and the OR element 126, firstly, enters the subtracting input of the counter 123, and, secondly, after the passage of the OR element 138 and the delay by the element 131 for the duration of the counter 123 operation, it arrives at the synchronizing input of the comparator 125.

At this signal, the comparator 125 compares the readings of the counter 123 with "zero". If the counter 123 is greater than zero, then a signal is generated at the output 177 of the comparator 125, which, through the OR element 128, is output to the output 137 of the block 11 and then to the subtracting input of the reverse counter 140.

If the readings of the counter 123 are equal to zero, then a pulse is generated at the output 178 of the comparator 125, which, through the OR element 127, is similar to the output 136 of the module 5.

Then, the same pulse through the input 156 of module 3 is fed to the summing input of the reverse counter 140, putting the user in direct viewing of court records in the server database.

Thus, the introduction of new nodes and blocks made it possible to significantly increase the speed of the system by eliminating the search for court cases across the entire server database and localizing the search only by the temporary and distinctive features of the court identifier.

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

1. Japan patent No. 4-38021 M.cl., 11/30, 13/14 from 06.23.92

2. US Patent No. 5136708 M.C. G06F 15/16 from 08/04/92 (prototype)

Claims (1)

An automated court clerical system of the Supreme Court containing a module for identifying the reference addresses of database records, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, and one information output of the module for identifying the reference addresses of database records is an information output of the system, a module for selecting address read data databases, information and synchronization inputs of which are the second information and synchronization system inputs, a module for issuing data to automated workstations of users, the information and synchronizing inputs of which are the third information and synchronizing inputs of the system, and the outputs are information outputs of the system group, the module for writing and reading data from the database, whose address output is the address output of the system and the clock outputs of the write and read are the first and second clock outputs of the system, respectively, characterized in that the system contains a module for generating addresses for reading database data, information inputs of a group of which are connected to the corresponding information outputs of a group for a module for identifying reference addresses of database records, a synchronizing input for a module for generating addresses for reading database data is connected to a synchronizing output of a module for identifying reference addresses for database records, information the output of the module for generating addresses for reading database data is connected to one information input of the module control of writing and reading database data, and the synchronizing output of the module for generating addresses for reading database data is connected to the first synchronizing input of the module for writing and reading database data, while the other information input of the module for writing and reading database data is connected to the first information output a module for selecting addresses for reading database data, and the second clock input of the module for writing and reading database data is connected to the synchronizing output of the database data reading address selection address selection module, the data addressing control module, the first and second control inputs of which are the first and second control inputs of the system, the information address of the data addressing control module is connected to the second information output of the database data reading address selection module, the data addressing control module is connected to the synchronizing output of the database data read address selection module, and the outputs of the module Data addressing connections are connected to the first and second control inputs of the database data recording and reading control module, and a data request source identification module, the information input of which is connected to the third information output of the database data reading addresses selection module, and the synchronizing input is connected to the third synchronizing system input, while the information output of the identification module of the address of the data request source is connected to another information input of the issuing module OF DATA on automated user workstations, and a synchronizing output data request identifying the source address of the module is connected to another input of the synchronizing unit of data output to automated user workstations.