RU168274U1 - SYSTEM OF AVERAGE REDISTRIBUTION OF LABOR CAPACITIES OF CONTROLLED ORDERS BY THE STRUCTURAL DIVISIONS OF THE ENTERPRISE - Google Patents

Abstract

The utility model relates to computer technology, in particular, to the system of averaged redistribution of the labor costs of controlled orders by structural units of the enterprise, which implements the use of new information technologies in the distribution of the labor costs of controlled orders by structural units of the enterprise. The technical result is to increase the speed of the system by excluding data retrieval across the entire database server data and search localization only by reference (basic and relative m) database addresses, corresponding codes of executed orders, company identifiers and codes of their units. The technical result is achieved by the fact that the system contains a module for identifying the base address of the company’s labor costs for executed orders, a module for identifying the relative address of the order labor costs, a module for selecting the address of the unit labor costs, a selection module for fully controlled overloaded units, a unit for correcting values of unit labor costs, a module for identifying Awan read / write memory of the system database server mode, the control module complete the process of analysis of the array of business units, order entry module, complete the orders array analysis procedure control module, identify the average value of the free capacity of the labor-intensive units. 11 ill., 3 tablets

Description

The utility model relates to computer technology, in particular to the system of averaged redistribution of the labor costs of controlled orders by structural units of the enterprise, which implements the use of new information technologies in the distribution of the labor costs of controlled orders by structural units of the enterprise.

The structural divisions of domestic industry enterprises periodically perform certain types of work, drawn up and presented in the form of orders [3]. At the same time, the planned services of the enterprises pre-distribute the hours both for individual orders and for the structural divisions of the enterprise, thereby defining and setting thereby a table (matrix) of the planned labor costs of the enterprise’s divisions for fulfilling the received orders, the columns of which are the enterprise divisions, and the rows are the executed orders .

To assess the cost component of the work performed, a monthly network schedule (LNG) is built, in which the most important orders for the enterprise are monitored only by labor intensity in order to correlate the declared time to the actual time worked. At the same time, throughout the entire period of performance of work, the amount of actually worked time of employees at their workplaces in each structural unit should be monitored. At the end of each month, the structural units of the enterprise provide information about the total hours worked to the planned service of the enterprise.

However, the problem arises that the information presented does not display the time of the structural unit spent on each order executed by this structural unit.

In addition, due to the fact that there are no perfect planning methods, it is impossible to accurately indicate the time that will be spent on a particular job. Therefore, the problem arises of calculating the complexity of the work based on the actually worked time.

Let an enterprise with the number n divisions y _j (j = 1, ..., n) of the set Q fulfill orders x _i (i = 1, ..., m) from the set Z whose subset Z _k (Z _k ∈Z) represents controlled orders (k <m or k << m).

For each controlled order x _i from the subset Z _k, it is necessary that the sum of the required actual labor costs of this order in the enterprise units be equal to the sum of the planned labor costs of the enterprise units for this order:

where X _{i, j} is the actual actual labor input of order i in unit j, P _{i, j} is the planned labor input of unit j for order i.

Expression (1) is true when the condition:

where F _j - the actual complexity of the j-th unit.

Condition (2) shows that for each unit y _j from the set Q, it is necessary that the sum of the actual labor costs of its orders be equal to the value of the actual labor input F _{j of} this unit.

In turn, condition (2) is valid when the constraint

emphasizing that for any order x _i ∈Z (x _i ), if the planned labor intensity P _{i, j of} order i in unit j is positive, then the desired actual labor input X _{i, j of} order i in unit j must also be positive, or if if the planned labor intensity P _{i, j of} order i in unit j is 0, then the required actual labor intensity X _{i, j of} order i in unit j must also be 0.

Next, the actual labor costs are added to the cells of the planned labor costs matrix according to the data from the tables provided by the structural divisions to the enterprise’s planning service about the actually worked out total time for all orders.

Since the information of the presented information does not show the time of the structural unit spent on each executed order, the average values of the actual labor costs of this unit for controlled and uncontrolled orders are added to each cell of the column of the structural unit of the matrix of planned labor costs.

If an enterprise unit carries out only controlled orders, then one hour is set as the average value of the actual labor intensity of this unit for an uncontrolled order, and zero is set as the average value of the actual labor intensity of this unit for a controlled order.

Constraints (1) - (3) allow us to optimize the value of the actual labor intensity of each enterprise unit for an executed order by moving its planned labor intensity P _{i, j} to the corresponding units, but so that constraints (1) - (3) are fulfilled.

Further, the matrix of actual labor costs is already considered, in each cell of which two values of the actual labor intensity of the unit are indicated: one for controlled orders, the other for uncontrolled orders.

In order to control the workload of the enterprise departments when carrying out controlled orders, the so-called free capacity is used, which is equal to the difference between the actual labor costs of uncontrolled and controlled orders in each cell of the matrix of actual labor costs.

Free capacity allows you to classify the structural units of the enterprise according to their workload: overloaded, fully controlled overloaded, underloaded, fully controlled underloaded, balanced, reduced.

From the point of view of managing the workload of the company’s divisions, the most complex and difficult is the completely controlled overloaded divisions that carry out only controlled orders, in which the free capacity is negative.

Hence the task of automating congestion control of fully controlled overloaded units by averaging their free capacities.

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

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

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

Another system is known, containing a central processor module, the inputs of which are connected to the memory modules and to the data preparation and input modules, and the outputs are connected to the corresponding memory modules, the data processing module, the information inputs of which are connected to the outputs of the corresponding memory modules, the synchronizing inputs are connected to control outputs of the central processor module, and the output of the module is the information output of the system [2].

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

Its disadvantage lies in the low speed of the system, due to the fact that the implementation of analytical data processing procedures is carried out by searching the entire database, which, when the database is large, inevitably leads to unreasonably large time spent on obtaining analytical estimates.

The purpose of the utility model is to increase the system performance by excluding data search over the entire volume of the server database and localizing the search only at the reference (base and relative) database addresses, corresponding order codes, company identifiers and each of the departments of these enterprises.

This goal is achieved by the fact that in a system containing a module for identifying the base address of the enterprise’s labor costs for fulfilled orders, the information input of which is the first information input of the system designed to receive the request codogram from the workstation of the system user, synchronizing the input of the module for identifying the base address of the enterprise’s labor costs by fulfilled orders is the first synchronizing input of the system, designed to receive synchronizing with Ignals of entering the request codogram from the workstation of the user of the system into the module for identifying the base address of the labor costs of the enterprise for fulfilled orders, the module for identifying the relative address of the labor costs of the order, the first and second information inputs of which are connected to the first and second information outputs of the module for identifying the base address of the labor costs of the enterprise accordingly, one clock input of the relative address identification module is laborious order order is connected to the synchronizing output of the module for identifying the base address of the enterprise’s labor costs for fulfilled orders, one information output of the module for identifying the relative address of the labor costs of the order is the first information output of the system designed to issue the code of the processed order to the automated workstation of the user, the module for selecting the address of the labor costs of departments , one information input of which is connected to the third information output of the mod To identify the base address of the enterprise’s labor costs by fulfilling orders, another information input of the unit for identifying the address of the labor costs of units is connected to another information output of the module for identifying the address of the labor costs of the units, the synchronizing input of the module for selecting the address of labor costs of units is connected to the synchronizing output of the module for identifying the relative address of the labor of the order, information output of the module for the selection of the address of the values of labor-intensiveness units is the first address output of the system, intended for issuing the address of the values of the labor costs of the units to the address input of the database server, the synchronizing output of the selection module for the selection of the address of the values of the labor costs of the units is the first synchronizing output of the system, intended for issuing control signals to read the values of the labor costs of the units to the input of the first channel of the server interrupt databases, a selection module for fully controlled overloaded units, one infor the input of which is the second information input of the system intended for receiving codes of free capacities of labor costs of enterprise divisions read from the server database, another information input of the selection module for fully controlled overloaded divisions is connected to the fourth information output of the module for identifying the base address of the enterprise labor costs for executed orders, synchronizing input module selection fully controlled overloaded units is watts With a synchronizing system input intended for receiving synchronizing signals for entering codes of free capacities of unit labor-intensiveness, read from the server database, into a selection module for fully controlled overloaded units, the first information output of a selection module for fully controlled overloaded units is the second information output of the system intended for output to workstation user system code number of fully controlled trans loaded subunits, the second information output of the selection module of fully controlled overloaded subunits is the third information output of the system, designed to issue the code of the number of subdivisions that are not fully controllable overloaded to the computer workstation of the user, the control module for completing the analysis of the array of units of the enterprise whose information input is connected to the fifth information output of the base address identification module labor capacities of the enterprise according to orders, the first and second synchronizing inputs of the control module for completing the analysis of the array of departments of the enterprise are connected to the first and second synchronizing outputs of the selection module for the fully controlled overloaded units, respectively, one synchronizing output of the control module for completing the analysis of the array of departments of the enterprise is connected to the counting input of the module selection addresses of the values of the complexity of units, another synchronizing output The control module for completing the analysis of the array of units of the enterprise is connected to the installation input of the module for selecting the address of the unit labor costs, the module for registering orders, the information input of which is the third information input of the system, designed to receive codes of controlled orders from the workstation of the user of the system, synchronizing the input of the module for registering orders is the third clock input of the system, designed to receive sync signals for entering the codes of controlled orders from the workstation of the system user into the order registration module, the information and synchronizing outputs of the order registration module are connected to the third information and other synchronizing inputs of the identification module for identifying the relative address of the order workloads, respectively, the control module for completing the procedure for analyzing the order array, information input which is connected to the sixth information output of the base address identification module tr the cost of the enterprise for fulfilling orders, one signal output of the control module for completing the procedure for analyzing the order array is connected to one installation input of the order registration module, and this is the first signal output of the system designed to issue a request code signal for entering the next controlled order to the user workstation, another signal output of the control module for completing the analysis of the order array is connected to another installation input of the register module orders and with the installation input of the module identifying the base address of the enterprise’s labor costs for fulfilled orders and at the same time it is the second signal output of the system designed to issue a signal to the user’s automated workstation to complete the analysis of the array of controlled orders of the enterprise; the module for identifying the average value of free labor-intensive capacities has been introduced units, the first and second information inputs of which are connected to the first and third information the outputs of the selection module of the fully controlled overloaded units, respectively, and the synchronizing input of the module for identifying the average value of the free capacities of the units is connected to another synchronizing output of the control module for completing the analysis of the array of units of the enterprise, the information output of the module for identifying the average value of the free capacities of the units is the fourth information output of the system, intended for issuance of information the input of the database server is the code of the average value of the free capacities of the unit labor costs, and the synchronizing output of the module for identifying the average value of the free capacities of the enterprise units is connected to the installation input of the selection module of the fully controlled overloaded units, the unit for the correction of the unit labor costs, one information input of which is connected to the third information output module identification base address of the complexity of the enterprise by orders, the other information input of the unit labor-value correction module is connected to another information output of the unit labor-intensiveness identification module of the order, one synchronizing input of the unit labor-value correction module is connected to the synchronizing output of the unit-average value identification module of the unit labor-intensive capacities, the information output of the labor-value correction module is information units is the second address output of the system, pre assigned to provide the address of the values of the labor costs of the divisions of the enterprise to the address input of the database server, the synchronizing output of the module for correcting the values of the labor costs of the divisions is the second synchronizing output of the system, designed to issue control signals to read the values of the labor costs of the divisions of the enterprise to the input of the second channel of the interruption of the database server, the mode recognition module read / write memory of the system server database, the first information input of which is the fourth information input of the system, intended for receiving codes of free capacities of labor costs of enterprise divisions, read from the server database, and the second and third information inputs of the recognition module of the read / write mode of the database memory of the server of the system are connected to the fourth and fifth information outputs of the identification module of the base workload address enterprises for fulfilled orders, respectively, the synchronizing input of the recognition module of the read / write mode of the server database memory with The system is the fourth synchronizing input of the system, intended for receiving synchronizing signals for entering codes of free capacities of labor consuming units of the enterprise, read from the server database, into the recognition module of the read / write mode of the database memory of the system server, the first synchronizing output of the recognition module of the read / write mode of the base memory of the system server data is connected to the counting input of the unit labor input value correction module, the second synchronizing output of the module the values of the read / write mode of the memory of the system server database is connected to one installation input of the unit labor-value correction module, with the first synchronizing input of the control module for completing the order array analysis procedure, and at the same time it is the third synchronizing output of the system designed to provide control signals for recording the average free capacities of labor-intensive units for the input of the third channel for interrupting the database server, the third synchronizing output of the module recognition the read / write mode of the system server database memory is connected to another installation input of the unit labor-value correction module and to the second clock input of the control module for completing the order array analysis procedure, the fourth clock output of the system server database database read / write memory recognition module is connected to another the synchronizing input of the module for the correction of the values of the labor intensity of units and at the same time it is the fourth synchronizing output of the system, intended Designed for issuing control signals for recording the average value of the free capacities of the labor-consuming units of the units at the input of the fourth channel of the database server interrupt.

The essence of the utility model is illustrated by drawings, where in FIG. 1 is a structural diagram of a system; FIG. 2 shows an example of a specific constructive implementation of the module for identifying the base address of the enterprise’s labor costs for fulfilled orders, FIG. 3 is an example of a specific constructive implementation of the module for identifying the relative address of the complexity of the order, FIG. 4 is an example of a specific constructive implementation of a module for selecting an address for the values of unit labor costs, in FIG. 5 is an example of a specific constructive implementation of a selection module for fully controlled overloaded units, FIG. 6 is an example of a specific constructive implementation of a control module for completing an analysis procedure for an array of enterprise units, FIG. 7 is an example of a specific constructive implementation of a module for identifying an average value of free capacities of labor-consuming units, FIG. 8 is an example of a specific constructive implementation of the unit for correcting the values of the labor costs of units, FIG. 9 is an example of a specific constructive implementation of a module for recognizing a read / write mode of a system server database memory, FIG. 10 is an example of a specific constructive implementation of a control module for completing an analysis procedure for an array of orders; FIG. 11 is an example of a specific constructive implementation of an order registration module.

The system (Fig. 1) contains module 1 for identifying the base address of the enterprise’s labor costs for fulfilled orders, module 2 for identifying the relative address of the labor costs of the order, module 3 for selecting addresses of the labor costs of units, module 4 for selecting fully controlled overloaded units, module 5 for monitoring the completion of the analysis of the array of units enterprises, module 6 for identifying the average value of free capacities of labor costs of units, module 7 for correcting the values of labor costs of subdivisions tions, the module 8 recognition system read / write memory mode base data server, the control module 9 completion of the procedure of analysis of the array of orders, registration module 10 orders.

In FIG. 1 shows the first 15, second 16, third 17 and fourth 18 information inputs of the system, the first 19, second 20, third 21 and fourth 22 synchronizing inputs of the system, as well as address 23-24, information 25-28, synchronizing 29-32 and signal 33-34 system outputs.

The module 1 for identifying the base address of the enterprise’s labor costs for fulfilled orders (Fig. 2) contains a register 35, a decoder 36, a memory module 37 made in the form of read-only memory (ROM), elements 38-40 I, elements 41-42 delays. The drawing also shows information 43, synchronizing 44 and installation 45 inputs, information 52-57 and synchronizing 58 outputs.

Module 2 identifying the relative address of the complexity of the order (Fig. 3) contains a decoder 60, a memory module 61, made in the form of read-only memory (ROM), adder 62, elements 63-65 AND, element OR 66, group 67 elements OR, elements 68 -70 delay. The drawing also shows information 71-73 and synchronizing 74-75 inputs, information 76-77 and synchronizing 78 outputs.

Module 3 selection address values of the complexity of units (Fig. 4) contains a counter 80, a decoder 81, a memory module 82, made in the form of read-only memory (ROM), adder 83, elements 84-86 AND, element 87 OR, and elements 88-90 delays. The drawing also shows information 91-92, synchronizing 93, counting 94 and installation 95 inputs, information 96 and synchronizing 97 outputs.

Module 4 selection of fully controlled overloaded units (Fig. 5) contains a register 100, counters 101-102, comparator 103, adder 104, elements 105-106 AND, element 107 OR, elements 108-111 delay. The drawing also shows information 112-113, synchronizing 114 and installation 115 inputs, information 120-122 and synchronizing 123-124 outputs.

Module 5 controls the completion of the analysis procedure for the array of business units (Fig. 6) contains a counter 130, comparator 131, OR element 132, delay element 133. The drawing also shows information 134 and synchronizing 135-136 inputs, synchronizing 139-140 outputs.

Module 6 identifies the average value of the free capacities of the labor-intensive units (Fig. 7) contains a decoder 145, a memory module 146, made in the form of read-only memory (ROM), a multiplier 147, elements 148-150 I, groups 151-152 elements I, elements 153 -155 delay. The drawing also shows information 156-157 and synchronizing 158 inputs, information 159 and synchronizing 160 outputs.

Module 7 correction of the values of the complexity of units (Fig. 8) contains a counter 165, a decoder 166, a memory module 167 made in the form of read-only memory (ROM), adders 168-169, trigger 170, elements 171-173 I, elements 174-177 OR, a group of 178 elements OR, delay elements 179-184. The drawing also shows information 185-186, synchronizing 187-188, counting 189 and installation 190-191 inputs, information 192 and synchronizing 193 outputs.

The module 8 for recognizing the read / write mode of the system server database memory (Fig. 9) contains a counter 197, a register 198, comparators 199-200, elements 201-204 AND, elements 205-206 OR and a delay element 207. The figure also shows information 208-210 and synchronizing 211 inputs, synchronizing 216-219 outputs.

The control module 9 for completing the analysis procedure of the order array (Fig. 10) contains a counter 220, a comparator 221, an OR element 222, and a delay element 223. The drawing also shows information 224 and synchronizing inputs 225-226, signal outputs 229-230.

The order registration module 10 (FIG. 11) comprises a register 240, an OR element 241, and a delay element 242. The drawing also shows information 243, synchronizing 244 and installation 245-246 inputs, information 247 and synchronizing 248 outputs.

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

A remote workstation (AWP) of a system user consists of a terminal having a screen for displaying a query codegram and system signals, and a personal computer keyboard. Presentation of readable values of free capacities of labor-consuming units of the enterprise is controlled from the server (not shown in the drawing).

The system operates as follows.

To organize the storage of the values of the labor costs of enterprises for fulfilling orders, the system for each enterprise associates a certain starting address of the database memory, called the base, relative to which the storage addresses of the labor costs of the orders are shifted. In this case, the offset value corresponds to the order code.

Within the relative address of the labor costs of the executed order is information on the labor costs of the enterprise units for this order, the address of each of which is already shifted relative to the relative address of the labor costs of the order. In this case, the offset value corresponds to the code of the unit number of the enterprise. Adding the offset corresponding to the code of the unit number of the enterprise to the relative address of the complexity of the order, we obtain the relative address of the complexity of the division of the enterprise, issued to the address input of the database server of the system.

The server reads the value of the unit’s labor intensity for the requested order at the exposed address in the form of the free capacity value and sends it to the information input of the system.

The structure of the free capacity of the unit has the following form (Table 1):

In turn, each sign of congestion in the system has its own code and characterizes its type of enterprise unit (Table 2).

The processing of the readings from the database of the labor costs of the units of the enterprise for the requested order begins with the procedure for identifying fully controlled overloaded units. In this case, their quantity and the total value of their free capacities are calculated, from which the average value of the free capacitance is calculated.

At the next stage of processing, the system again sequentially reads from the database the values of the labor costs of the enterprise units for the requested order and again identifies fully controlled overloaded units. However, each identification at this stage of processing the values of labor costs of the enterprise divisions read from the database is completed by recording the average value of free capacity at the address on the address input of the database server from which the last reading of the free capacity value was performed.

If the read value does not identify a fully controlled overloaded unit, a transition to the next memory address of the server database is formed.

The described process of reading the values of free capacities of units for the current requested order, their processing with recording the average value of free capacities at the address of reading free capacities of fully controlled overloaded units is performed for all units for all orders specified by the codogram.

To start the system, the user at his workplace generates a request codogram, which indicates: the code (identifier) of the enterprise; controlled order code; code of the total number of controlled orders; code of the initial (starting) unit of the enterprise; code of the sign of fully controlled overloaded departments of the enterprise, code of the total number of departments of the enterprise performing the order (Table 3):

The generated codogram from the workstation of the user of the system is fed to the information input 15 of the system, then it goes to the information input 43 of module 1 for identifying the base address of the enterprise’s labor costs for fulfilled orders and is entered into register 35 by a synchronizing pulse supplied to synchronizing input 44 of module 1 from synchronizing input 19 system.

The code of the company identifier from the output 46 of register 35 is fed to the input of the decoder 36. The decoder 36 decrypts the code of the company identifier and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 38-40 I. For definiteness, we assume that the high potential from the output of the decoder 36 will open element 40 And one entry.

The synchronizing pulse from the input 19 of the system is supplied to the synchronizing input 44 of module 1, is delayed by the delay element 41 for the response time of the register 35 and the decoder 36, and enters through the element 40 And opened by one input and to the read input of a fixed cell of a read-only memory (ROM) 37.

In a fixed cell of the ROM 37, the code of the base address of the enterprise’s labor costs is stored, starting from which the information on the enterprise’s labor costs for all fulfilled controlled orders is stored in the system server database.

At the same time, for each controlled order, a separate memory area is allocated in the server database memory, the address of which is offset from the base address of the labor costs of the enterprise by an amount corresponding to the code of this order. To determine this bias, the order code from the information output 53 of module 1 is sent to the information input 71 of the module 2 for identifying the relative address of the order complexity, passes a group of 67 OR elements, and is fed to the input of the decoder 60. The decoder 60 decodes the order code and generates a high order on one of its outputs the potential arriving at the respective inputs of elements 63-65 I. For definiteness, let us assume that a high potential from the output of the decoder 60 will open the element 65 And at one input.

In this case, the synchronizing pulse from the output of the delay element 41 of module 1, delayed by the delay element 42 while reading the contents of the fixed cell ROM 37, and from the output 58 of the module 1 is sent to the synchronizing input 74 of the module 2, passes through the element 66 OR, is delayed by the element 68 of the delay at the time of operation of the decoder 60 and enters through the element 65 open through one input and to the read input of a fixed cell of read-only memory device (ROM) 61. In a fixed cell of ROM 61, the address offset code is stored mm of the laboriousness of the order, the code of which was submitted to the input of the decoder 60 from the information input 71 of the module 2.

The address offset code read from the ROM 61 is supplied to one information input of the adder 62, to the other information input 73 of which the code of the base address of the enterprise’s labor costs for controlled orders is output from the output 52 of module 1.

According to the synchronizing pulse from the output of the delay element 68, delayed by the delay element 69 for the time of reading the fixed cell of the ROM 61, in the adder 62, the relative address of the sum of the labor costs of the enterprise is generated by the order, the code of which was supplied to the input of the decoder 60 from the information input 71 of module 2.

The code of the start-up unit of the enterprise from the information output 54 of module 1 is sent to the information input 91 of the module 3 for selecting the address of the values of the labor costs of the units and enters the input of the decoder 81. The decoder 81 decodes the code of the start-up unit of the enterprise and generates high potential at one of its outputs, which goes to the corresponding inputs elements 84-86 I. For definiteness, suppose that high potential from the output of decoder 81 will open element 85 AND at one input.

In this case, the synchronizing pulse from the output of the delay element 69 of module 2, delayed by the delay element 70 for the duration of the operation of the adder 62 of module 2 and the decoder 81 of module 3 and applied from the output 78 of module 2 to the synchronization input 93 of module 3, passes through the element open at one input 85 And to the read input of a fixed cell of read-only memory (ROM) 82. In a fixed cell of ROM 82, a code for shifting the address of the amount of labor costs is stored by order of that unit of the enterprise, the code of which was supplied to the input of 91 decoder 81 modules 3.

The code for shifting the address of the amount of labor costs, read out from ROM 82, is ordered by the order of the considered unit of the enterprise to one information input of the adder 83, to the other information input 92 of which is the code of the relative address of the amount of labor costs of the whole company by order from the output 77 of module 2.

According to the synchronizing pulse from the synchronizing input 93, delayed by the delay element 88 for the time of reading the fixed cell of the ROM 82, the adder 83 forms the relative address of the labor costs of the enterprise unit by order, by which this amount is stored in the system server database memory.

The order address of the labor unit of the enterprise unit formed in the adder 83 is supplied to the information input of the counter 80, where it is entered by the synchronizing pulse from the output of the delay element 88, delayed by the delay element 89 for the duration of the operation of the adder 83.

The same pulse from the output of the delay element 89 passes the element 87 OR, is delayed by the element 90 of the delay at the time of entering in the counter 80 the code of the relative address of the amount of labor costs of the enterprise unit, issued from the information output 96 of module 3 to the address output 23 of the system, and comes from the output 29 of the system to the input of the first channel of the system server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 23 of the system and issuing the read data on the labor costs of the enterprise unit for the requested controlled order for the information input 16 of the system.

The unit’s labor costs read from the server’s database for the requested controlled order from the system information input 16 go to the information input 113 of the register 100 of the module 4 for selection of fully controlled overloaded units, where they are entered by the server’s synchronizing pulse received at the synchronization input 114 of the register 100 from the synchronizing input 20 system.

The code of the sign of the workload of the enterprise unit from the output 116 of the register 100 is fed to one information input of the comparator 103, to the other information input 112 of which the mask code of the fully controlled overloaded unit from the information output 55 of module 1 is supplied.

According to the clock pulse at the clock input 114, delayed by the delay element 108 for the response time of the register 100, the comparator 103 compares the codes received at its information inputs.

If the code of the sign of the workload of the unit, read from the memory of the server database and received at the information input 112 of the comparator 103, is not equal to the mask code of the overloaded fully controlled unit, then the comparator 103 does not identify the accepted unit as completely overloaded and controlled, generating a signal at its output 118 opening element 105 And on one input.

In this case, the synchronizing pulse from the output of the delay element 108, delayed by the delay element 109 for the duration of the comparator 103, passes through the element And 105, which is open at one input, and enters the counting input of the counter 101, incrementing it.

Counter 101 counts on an accrual basis the total number of business units that are not overloaded and fully controlled during the processing of the labor costs of the current controlled order.

The same signal from the output of element 105 AND is delayed by the delay element 110 for the increment time of counter 101 and from the synchronizing output 123 of module 4 is fed to the synchronizing input 135 of module 5 to control the completion of the analysis of the array of business units.

In addition, the same signal from the output of the delay element 110 passes through the OR element 107 and enters the installation input of the register 100, resets its contents to zero and thereby prepares it for a new operation cycle.

If the code of the sign of the workload of the unit, read from the memory of the server database and received at the information input 112 of the comparator 103, is equal to the mask code of the completely controlled overloaded unit, then the comparator 103 identifies the received unit as overloaded and completely controlled, and generates a signal already at its output 119, opening element 106 And at one input.

In this case, the synchronizing pulse from the output of the delay element 108, delayed by the delay element 109 for the response time of the comparator 103, passes through the I element 106 open at one input and enters both the counting input of the counter 102, incrementing it, and the synchronizing input of the adder 104, entering in it the code of the free capacity of the adopted unit of the enterprise.

Counter 102 counts on an accrual basis the total number of business units that are fully controlled and overloaded.

The same signal from the output of the element 106 AND is delayed by the delay element 111 for the increment time of the counter 102 and the operation of the adder 104, from the synchronizing output 124 of the module 4 is fed to the synchronizing input 136 of the module 5.

In addition, the same signal from the output of the delay element 111 passes through the OR element 107 and enters the installation input of the register 100, resets its contents to zero and thereby prepares it for a new operation cycle.

Each signal from the synchronizing inputs 135 and 136 passes through the OR element 132 and enters the counting input of the counter 130, incrementing it. The counter 130 counts on an accrual basis the total number of server units read from the memory of the server database and processed by the system of the enterprise units for the requested order.

The contents of the counter 130 is fed to one information input of the comparator 131, to the other information input 134 of which the code of the total number of enterprise units performing the requested controlled order is supplied from the information output 56 of module 1.

According to the synchronizing pulse from the output of the OR element 132, delayed by the delay element 133 for the increment time of the counter 130, the comparator 131 compares the codes received at its information inputs with the generation of a signal at one of its outputs.

Since so far only the first memory cell of the server database has been read and processed, the first one has been entered into the counter 130, which is a reflection of the completion of this processing. Therefore, the content of the counter, equal to 1, will be much less than the total number of departments of the enterprise performing the requested controlled order, and, therefore, the signal will be generated at the output 137 of the comparator 131.

This signal from the output 139 of the module 5 is fed to the counting input 94 of the module 3 and is fed to the counting input of the counter 80, forming the address of the next memory cell of the database server system, issued from the information output 96 of the module 3 to the address output 23 of the system.

The same signal from the counting input 94 of module 3 passes the OR element 87, is delayed by the delay element 90 for the increment time of the counter 80, and from the synchronizing output 29 of the system goes to the input of the first channel of the system server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the following address, newly formed at the address output 23 of the system, and issuing the read data of the labor costs of the next unit of the enterprise under a controlled order to the information input 16 of the system.

The described process of generating, selecting and reading out the memory addresses of the server database with the subsequent processing of their contents will continue until all departments of the enterprise that carry out the requested controlled order are processed.

In this case, the contents of the counter 130 of module 5 will be equal to the code of the total number of departments of the enterprise performing the controlled order submitted to the information input 134 of the comparator 131 from the information output 56 of the module 1, and, therefore, the signal will be generated already at the output 138 of the comparator 131. This signal Firstly, it immediately enters the installation input of the counter 130, returning it to its original state.

Secondly, this signal from the output 140 of the module 5 is fed to the installation input 95 of the module 3 and is supplied to the installation input of the counter 80, returning it to its original state.

Thirdly, this signal from the output 140 of module 5 is fed to the synchronizing input 158 of module 6 for identifying the average value of the free capacities of the labor costs of units and passes the code of the number of units that are completely controlled and overloaded from the information output through the elements of group 151 to the input of the decoder 145 122 module 4 to the information input 156 of module 6, and through the And elements of group 152 - to one information input of the multiplier 147 is the code for the sum of the free capacities of the labor-intensiveness of these units coming from information output 121 of module 4.

Decoder 145 decrypts the code of the number of units that are fully controlled and overloaded, and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 148-150 I. For definiteness, suppose that high potential 150 will open from the output of decoder 145 and 150 one entrance.

In this case, the synchronizing pulse from the synchronizing input 158 of module 6, delayed by the delay element 153 for the time the decoder 145 operates, passes through the 150 I element open to one input and to the read input of a fixed cell of a read-only memory (ROM) 146. In a fixed cell, the ROM 146 is stored the code of the return value of the number of units of the enterprise, which was submitted to the input 156 of the decoder 145.

The code of the reciprocal of the number of fully controlled and overloaded units read from the ROM is supplied to the other information input of the multiplier 147 upon the requested order.

According to the synchronizing pulse from the output of the delay element 153, delayed by the delay element 154 for the time of reading the fixed cell ROM 146 and applied to the synchronizing input of the multiplier 147, the multiplier 147 multiplies the received codes with the result in the form of a code of the average value of the free capacities of the labor-consuming units of the fully controlled overloaded business units. This code from the information output 28 of the system is issued to the information input of the database server.

The synchronizing pulse from the output of the delay element 154, delayed by the delay element 155 for the duration of the multiplier 147, is sent from the synchronizing output 160 of the module 6, firstly, to the installation input 115 of the module 4 and fed to the installation inputs of the counters 101 and 102, returning them to the original the state, secondly, is sent to the synchronizing input 187 of the module 7 correction of the values of the complexity of units.

At this point in time, the code of the first division of the enterprise, supplied from the information output 54 of module 1 to the input 185 of the decoder 166 of module 7, is decrypted by the decoder with the generation of high potential arriving at the corresponding inputs of elements 171-173 I. For definiteness, we assume that high potential from the output decoder 166 will be opened element 172 And one input.

In addition, the code of the relative address of the sum of the enterprise’s labor costs for the analyzed order from the output 77 of module 2 is already on the same information input 186 of the adder 168 of module 7.

In this case, the synchronizing pulse from the synchronizing input 187 of module 7, delayed by the delay element 179 for the response time of the decoder 166, passes through the element 172 And open to the read-only input of the fixed cell of the read-only memory (ROM) 167, from which the address offset code is read the amount of labor of the first unit of the enterprise by order, submitted to another information input of the adder 168.

According to the synchronizing pulse from the output of the delay element 179, delayed by the delay element 180 for the time of reading the fixed cell ROM 167, the adder 168 generates the relative address of the labor costs of the enterprise unit by order, which stores in the memory of the database server system the amount of labor of this unit of the enterprise for the considered to order.

The order address of the enterprise unit’s labor hours formed in adder 168 passes the group of 178 OR elements on request and enters the counter information input 165, where it is entered by the synchronizing pulse from the output of delay element 180, delayed delay element 181 for the time of operation of adder 168 and passed through OR element 176.

The same pulse from the output of the OR element 176 passes through the OR element 177, is delayed by the delay element 182 for recording the code of the relative address of the labor costs of the enterprise unit on the order 165, issued from the information output 192 of module 7 to the address output 24 of the system, and comes from the output 30 system to the input of the second channel interrupt server database system.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 24 of the system and issuing the read data on the labor costs of the enterprise unit on request for information input 17 of the system.

Read from the server database data of the work of the unit under a controlled order from the information input 17 of the system goes to the information input 210 of the register 198 of the module 8 recognition mode read / write memory of the database server of the system, where they are entered by the synchronizing pulse of the server received at the synchronizing input 211 of the register 198 from the synchronizing input 21 of the system.

The same pulse from the clock input 211 of the module 8 is supplied to the counting input of the counter 197 and increments it. Counter 197, counting on an accrual basis the number of read units of the enterprise, issued each time to one information input of the comparator 199, to the other information input 208 of which from the information output 56 of module 1 a code is supplied of the total number of company units, the labor of which is to be processed.

The code of the sign of the workload of the enterprise unit from the output of the register 198 is supplied to one information input of the comparator 200, to the other information input 209 of which the mask code of the fully controlled overloaded unit from the information output 55 of module 1 is supplied.

The pulse at the clock input 211, delayed by the delay element 207 for the response time of the register 198 and the increment of the counter 197 in the comparators 199 and 200, compares the codes received at their information inputs.

If the code of the sign of the workload of the unit, read from the memory of the server database and received at one information input of the comparator 200 from the output of the register 198, will be equal to the mask code of the fully controlled overloaded unit, then the comparator 200 will identify the received unit as completely controlled overloaded, generating a signal 214 opening the elements 202 and 203 AND on one input.

If the code of the sign of the workload of the unit, read from the memory of the server database and received to one information input of the comparator 200 from the output of the register 198, is not equal to the mask code of the fully controlled overloaded unit, then the comparator 200 does not identify the received unit as completely controlled overloaded and generates a signal at the output 215, opening the elements 201 and 204 And at one input.

If the contents of the counter 197 supplied to one information input of the comparator 199 will be less than the code of the total number of departments of the enterprise performing the controlled order submitted to its other information input 208, then the signal is generated at the output 213, which opens the elements 202 and 204 And at one input.

If the contents of the counter 197, supplied to one information input of the comparator 199, will be equal to the code of the total number of departments of the enterprise performing a controlled order, submitted to its other information input 208, then the signal is generated already at the output 212 of the comparator, opening the elements 201 and 203 And one by one the entrance.

Suppose that the code for the sign of the workload of the enterprise unit, read from the memory of the server database and received at one information input of the comparator 200 from the output of the register 198, is equal to the mask code of the fully controlled overloaded unit at its other information input. In this case, the comparator 200 identifies the received unit as fully controlled overloaded, generating a signal at the output 214 that opens the And elements 202 and 203 at one input.

Since in our case only the first unit was entered in counter 197, then, therefore, its contents will be much less than the total number of units of the enterprise performing a controlled order. In this case, the signal from the output 213 of the comparator 199 passes through the And 202 element open at one input and, firstly, the OR element 206 passes and enters the setup input of the register 198, resets its contents to zero and thereby prepares it for a new operation cycle .

The same signal from the synchronizing output 217 of module 8 is issued to the synchronizing output 31 of the system, from where it is output to the input of the third channel of the database server interrupt.

With the arrival of this impulse, the database server switches to the subroutine for recording the average value of the free capacities of labor-intensive units of the enterprise units from the information output 28 of the system at the address set on the address output 24 of the system.

In addition, the synchronizing pulse from the output 217 of the module 8 is supplied to the synchronizing input 188 of the module 7 and immediately goes to the single input of the trigger 170, setting it to a single state. Next, a unit of high potential from the direct output of the trigger 170 is fed to one information input of the adder 169, to the other information input of which the code of the relative address of labor costs of the enterprise unit is ordered from the output of the counter 165.

According to the synchronizing pulse from the input 188 of module 8, delayed by the delay element 183 for the time the trigger 170 switches to a single state, the adder 169 generates a code for the relative address of the labor costs of the next unit of the enterprise by order.

The relative address of the labor inputs of the next enterprise unit, formed in adder 169, passes by order through the OR elements of group 178 and enters the information input of the counter 165, where it is entered by the synchronizing pulse from the output of the delay element 183, delayed by the delay element 184 for the time of operation of the adder 169 and passed through the element 176 OR.

The same pulse from the output of the OR element 176 passes through the OR element 177, is delayed by the delay element 182 for the time the memory address was entered into the counter 165, issued to the address output 24 of the system, and from the synchronizing output 193 of the module 7 is supplied to the synchronizing output 30 of the system, from where issued to the input of the second channel of the system database server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 24 of the system and issuing the read data on the labor costs of the enterprise unit on request for information input 17 of the system.

If the codes do not match on the information inputs of the comparator 200, a signal is generated at its output 215, opening the elements 201 and 204 And at one input. In this case, provided that the contents of counter 199 will be less than the code for the number of all departments of the enterprise, the signal from the output 213 of comparator 199 passes through the And 204 element open at one input, passes through the OR element 206, and enters the setup input of the register 198, resets zero its contents and thereby prepares it for a new cycle of work.

Secondly, this signal from the output 219 of module 8 enters the counting input 189 of module 7, passes the OR element 174, and enters the installation input of the trigger 170, returning it to its original state.

Thirdly, the same signal from the counting input 189 of module 7 is fed to the counting input of counter 165 and, incrementing it, forms the relative address of the labor costs of the next unit of the enterprise by order, issued from the information output 192 of module 7 through the address output 24 of the system to the address server database entry.

Fourthly, the same signal from the counting input 189 of module 7 passes through the OR element 177, is delayed by the delay element 182 for recording the relative address of the labor costs of the next unit of the enterprise by order in the counter 165, issued to the address output 24 of the system, and from the synchronizing output 192 of the module 8 is supplied to the synchronizing output 30 of the system, from where it is issued to the input of the second interrupt channel of the system database server.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 24 of the system and issuing the read data on the labor costs of the next enterprise unit for the analyzed order to the information input 17 of the system.

The described sequential process of generating and retrieving the memory addresses of the system server database and reading the labor-intensiveness values from them with the recognition of fully controlled overloaded units will continue until all units performing the current controlled order are processed.

This will happen when the contents of the counter 197 of module 8 are equal to the code of the total number of all business units received at the information input 208 of the comparator 199 of module 8 from the output 56 of module 1. In this case, a signal is generated at the output 212 of the comparator 199, which opens the elements 201, 203 And on one input.

If the last unit being processed is not completely controlled overloaded, then in this case the signal from the output 215 of the comparator 200 passes through the AND element 201 open at one input, the OR element 205 passes, and enters the installation input of the counter 197, returning it to its original state, and , having passed the OR element 206, it enters the installation input of the register 198, resets its contents to zero and thereby prepares it for a new operation cycle.

The same signal from the output 216 of module 8 is supplied to the installation input 191 of module 7, passes through the OR element 175, and enters the installation input of the counter 165, returning it to its original state and thereby blocking the formation of the next address on the address output 24 of the system.

The same signal from the output 216 of module 8 is fed to the counting input 225 of module 9 for monitoring the completion of the order array analysis procedure, an OR element 222 passes and enters the counting input of the counter 220, which counts the cumulative total of the processed controlled orders executed by the enterprise.

If the last unit being processed is completely controlled overloaded, then in this case the signal from the output 212 of the comparator 199 passes through the And 203 element open at one input, the OR element 205 passes, and enters the installation input of the counter 197, returning it to its original state, and , having passed the OR element 206, it enters the installation input of the register 198, resets its contents to zero and thereby prepares it for a new operation cycle.

The same signal from the synchronizing output 218 of module 8 is issued to the synchronizing output 32 of the system, from where it is output to the input of the fourth channel for interrupting the database server.

With the arrival of this impulse, the database server switches to the subroutine for recording the average value of the free capacities of labor-intensive units of the enterprise units from the information output 28 of the system at the address set on the address output 24 of the system.

The same signal from the output 218 of module 8 is supplied to the installation input 190 of module 7 and, passing through the OR element 174, is fed to the installation input of the trigger 170 and returns to its original state.

The same signal from the input 190 of module 7 passes through the OR element 175 and enters the installation input of the counter 165 and returns it to its original state, thereby blocking the formation of the next address on the address output 24 of the system.

The same signal from the output 218 of module 8 is supplied to the counting input 226 of the module 9 for monitoring the completion of the analysis of the enterprise order array, passes OR element 222 and enters the counting input of the counter 220, which counts the total number of processed controlled orders executed by the enterprise.

For each signal arriving at the counting inputs 225 and 226 of module 9, the contents of the counter 220 are incremented each time output to one information input of the comparator 221, the other information input 224 of which is supplied from the information output 57 of module 1 with the code of the total number of monitored orders to be processed in system.

Each clock pulse from the counting inputs 225 and 226 of module 9, having passed the OR element 222, is delayed by the delay element 223 for the increment time of the counter 220, and allows the comparator 221 to compare the codes received at its information inputs.

If the contents of the counter 220 will be less than the code of the total number of orders supplied to the information input 224 of the comparator 221, then the signal is generated at the output 227 of the comparator 221. If the contents of the counter 220 will be equal to the code of the total number of orders supplied to the information input 224 of the comparator 221, then the signal generated at the output 228 of the comparator 221.

Since in our case only the first unit is entered in the counter 220, the contents of the counter will be less than the code for the total number of orders to be processed in the system (provided that the number of processed orders is more than one). In this case, a signal is generated at the output 227 of the comparator 221, which is output from the output 229 of the module 9 to the installation input 245 of the module for registration of controlled orders, passes through the OR element 241 to the installation input of the register 240, and resets its contents to zero, thereby preparing it for new work cycle.

The same signal from the output 229 of module 9 is removed in the form of a request signal “Enter the code of the next controlled order”, which is issued from the signal output 33 of the system to the user's workstation.

Having received this request, the user of the system from his workplace sends the code of the next controlled order to the information input 18 of the system.

The code of the next controlled order received from the user of the system from the information input 18 of the system is fed to the information input 243 of the register 240 of the order registration module 10, where it is entered by the synchronizing pulse supplied to the synchronizing input 244 of the module 10 from the synchronizing input 22 of the system.

The code of the next controlled order from the information output 247 of the module 10 is sent to the information input 72 of the module 2, passes through the OR elements of group 67 and goes to the input of the decoder 60. The decoder 60 decodes the code of the next controlled order and generates a high potential at one of its outputs the corresponding inputs of the elements 63-65 I. For definiteness, suppose that the high potential from the output of the decoder 60 will open the element 64 And one input.

The pulse of the start of the processing cycle of the accepted new controlled order is the synchronizing pulse coming from the system user to the synchronizing input 22 of the system. This pulse from the synchronizing input 22 of the system is supplied to the synchronizing input 244 of the module 10, is delayed by the delay element 242 for the response time of the register 240 and from the synchronizing output 248 of the module 10 is supplied to the synchronizing input 75 of the module 2, the element 66 passes OR, is delayed by the time delay element 68 the operation of the decoder 60 and enters through the element 64 open through one input and to the read input of a fixed cell of a read-only memory device (ROM) 61.

In a fixed cell of ROM 61, a code is stored for the offset of the relative workloads of the requested new controlled order, starting from which information about the workloads of all departments of the enterprise for this order is stored in the memory of the server database. This address offset code from the ROM 61 is fed back to one information input of the adder 62, to the other information input 73 of which the code of the base address of the enterprise labor costs for controlled orders is supplied.

According to the synchronizing pulse from the input 75 of module 2, passed through the OR element 66 and delayed by the delay element 68 for the time of reading the fixed cell of the ROM 61, the relative address of the labor costs of the requested new controlled order, submitted to the information input 92 of the adder 83 of the module 3, is formed in the adder 62.

According to the code of the starting first division of the enterprise, which is sent from the information output 54 of module 1 and further through the information input 91 of module 3 to the input of the decoder 81, a high potential is generated at one of the outputs of the decoder 81, which opens the 85 And one input.

In this case, the synchronizing pulse from the output of the delay element 69 of module 2, delayed by the delay element 70 for the duration of the operation of the adder 62 of module 2 and the decoder 81 of module 3 and applied from the output 78 of module 2 to the synchronization input 93 of module 3, passes through the open one input again element 85 And to the reading input of a fixed cell of read-only memory (ROM) 82. In a fixed cell of ROM 82 is stored a code for shifting the address of the first unit of the enterprise according to the requested new order submitted to other information Ion input of the adder 83.

According to the synchronizing pulse from the synchronizing input 93, delayed by the delay element 88 for the time of reading the fixed cell of the ROM 82, in the adder 83, the relative address of the labor costs of the first unit of the enterprise is generated according to the requested new order, by which this amount is stored in the system server database memory.

The labor address of the first unit of the enterprise, formed in the adder 83, by order is again fed to the information input of the counter 80, where it is entered by the synchronizing pulse from the output of the delay element 88, delayed by the delay element 89 for the duration of the operation of the adder 83.

The same pulse from the output of the delay element 89 passes the element 87 OR, is delayed by the element 90 of the delay at the time of entering in the counter 80 the code of the relative address of the amount of labor costs of the enterprise unit, issued from the information output 96 of module 3 to the address output 23 of the system, and comes from the output 29 of the system to the input of the first channel of the system server interrupt.

With the arrival of this impulse, the server again switches to the subprogram for polling the contents of its database at the address generated on the address output 23 of the system, and issuing the read data on the labor costs of the first unit of the enterprise for the requested new order for the information input 16 of the system.

The data from the server’s database of the first unit for the requested new controlled order from the information input 16 of the system again goes to the information input 113 of the register 100 of module 4, where they are entered by the synchronizing pulse of the server, which arrives at the synchronizing input 114 of the register 100 from the synchronizing input 20 of the system.

The described process of generating, selecting and reading from the database memory of the server of the system of labor input values of enterprise divisions with subsequent recognition of fully controlled overloaded divisions will continue until all enterprise divisions for all controlled orders are processed.

The process of processing the enterprise’s departments for controlled orders ends when the code of the number of accepted and processed controlled orders at the output of counter 220 of module 9 is equal to the code of the total number of controlled orders specified by the codogram of the processing request and submitted to another information input 224 of comparator 221 from module output 57 one.

In this case, the signal is generated at the output 228 of the comparator 221, which immediately goes to the installation input of the counter 220, returning it to its original state.

The same signal from the output 230 of module 9 is supplied:

- to the installation input 246 of the module 10, the OR element 241 passes and enters the installation input of the register 240, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 45 of module 1 and enters the installation input of the register 35, resets its contents to zero and thereby prepares it for a new operation cycle.

In addition, this signal is output from the output 230 of module 9, the signal "Monitoring of controlled orders of the enterprise is completed", which from the signal output 34 of the system is issued to the user's workstation.

Thus, the introduction of new nodes and modules and new structural connections has significantly improved system performance by eliminating data retrieval across the entire system server database.

Information sources

1. US patent No. 5136708, IPC G06F 15/16, 1992.

2. US Patent No. 5129083, IPC 99G06F 12/00, 15/40, 1992 (prototype).

3. Demin D.S. Heuristic algorithm for calculating the complexity of work in the enterprise according to the actual time worked. // Innovation and investment. - 2014. - No. 12. - S. 137-140.

Claims (1)

The system of averaged redistribution of the labor costs of controlled orders by structural divisions of the enterprise, containing a module for identifying the base address of the labor costs of the enterprise for executed orders, the information input of which is the first information input of the system designed to receive the request codogram from the workstation of the user of the system, synchronizing the input of the module for identifying the base address of the labor costs Fulfillment orders is the first synchro system lowering input, intended for receiving synchronization signals of entering the request codogram from the workstation of the system user into the module for identifying the base address of the enterprise labor costs for fulfilled orders, the module for identifying the relative address of the labor costs of the order, the first and second information inputs of which are connected to the first and second information outputs of the module identification of the base address of the complexity of the enterprise on the orders, respectively, one si the timing input of the identification module of the relative address of the labor input of the order is connected to the synchronizing output module of the identification of the base address of the labor input of the enterprise for fulfilled orders, one information output of the identification module of the identification of the relative address of the labor input of the order is the first information output of the system designed to issue the code of the processed order to the user workstation, module for selecting addresses of unit labor input values, one info the input of which is connected to the third information output of the identification module of the base address of the labor costs of the enterprise for fulfilling orders, the other information input of the module for selecting the address of the values of the labor costs of units is connected to the other information output of the module of identification of the address of the labor costs of the units, the synchronizing input of the selection module of the address of the labor costs of units is connected to the synchronizing the output module identification of the relative address of labor costs kaz, the information output of the selection module for the address of the unit labor costs is the first address output of the system designed to provide the address of the values of the unit labor costs to the address input of the database server, the synchronizing output of the module for the selection of the address of the unit labor costs is the first synchronizing output of the system for issuing readout control signals the values of the complexity of the units at the input of the first channel of the interruption of the database server, module lectures of fully controlled overloaded units, one information input of which is the second information input of the system intended for receiving codes of free capacities of labor costs of enterprise units read from the server database, another information input of the selection module of fully controlled overloaded units is connected to the fourth information output of the base address identification module the complexity of the enterprise according to orders, synchronizing the input of the module The section of fully controlled overloaded units is the second synchronizing input of the system, intended for receiving synchronizing signals for entering codes of free capacities of unit labor costs read from the server database into the selection module for fully controlled overloaded units, the first information output of the selection module for fully controlled overloaded units is the second information output systems designed for the issuance of an automated slave the other place of the user of the code system for the number of fully controlled overloaded units, the second information output of the selection module for the fully controlled overloaded units is the third information output of the system, intended for issuing to the automated workstation of the user of the system code the number of units that are not completely controlled overloaded, the control module for completing the analysis procedure an array of business units whose information input is connected to the fifth information output of the module identifying the base address of the enterprise’s labor costs for fulfilled orders, the first and second synchronizing inputs of the module for completing the analysis of the array of departments of the enterprise are connected to the first and second synchronizing outputs of the selection module for the fully controlled overloaded units, respectively, one synchronizing output of the module for monitoring the completion of the analysis of the array departments of the enterprise is connected to the counting input of the addr selection module the values of the unit labor costs, another synchronizing output of the control module for completing the analysis of the array of enterprise units is connected to the installation input of the module for selecting the address of the unit labor costs, the registration module, the information input of which is the third information input of the system, designed to receive codes of controlled orders from an automated workstation the system user synchronizing the input of the order registration module is the third with the system’s synchronizing input, designed to receive the synchronization signals of entering the codes of controlled orders from the workstation of the system user into the order registration module, the information and synchronizing outputs of the order registration module are connected to the third information and other synchronizing inputs of the identification module of the relative address of the order workloads, respectively, the completion control module procedures for analyzing an array of orders whose information input is connected to the sixth information output of the identification module of the base address of the enterprise’s labor costs for fulfilled orders, one signal output of the control module for completing the analysis of the order array is connected to one installation input of the order registration module and is the first signal output of the system intended for delivery to the workstation of the system user request signal for entering the code of the next controlled order, another signal output of the control module for completing the procedure ana from an array of orders is connected to another installation input of the order registration module and to the installation input of the identification module of the base address of the enterprise’s labor costs for executed orders, and at the same time it is the second signal output of the system designed to issue a signal to the user’s automated workstation for the system to complete the analysis of the array of controlled orders of the enterprise , characterized in that it contains a module for identifying the average value of free capacities of labor-intensive subsection one, the first and second information inputs of which are connected to the first and third information outputs of the selection module of fully controlled overloaded units, respectively, and the synchronizing input of the module for identifying the average value of free capacities of unit labor costs is connected to another synchronizing output of the control module for completing the analysis of the array of units of the enterprise, the information output identification module of the average value of free capacities of labor costs subsection is the fourth information output of the system, intended for outputting to the information input of the database server a code of the average value of the free capacities of the labor costs of units, and the synchronizing output of the identification module of the average value of the free capacities of the labor costs of units of the enterprise is connected to the installation input of the selection module of the fully controlled overloaded units, the value correction module the complexity of units, one information input of which is connected to the third the information output of the identification module of the base address of the labor costs of the enterprise for fulfilling orders, another information input of the module for correcting the values of the labor costs of units is connected to another information output of the module for identifying the relative address of the labor costs of the units, one clock input of the module for correcting the values of labor costs of the units is connected to the synchronizing output of the module for identifying the average value of free capacities the complexity of units, information output m the barrel for correcting the unit labor costs is the second address output of the system, intended for issuing the address of the unit labor costs for the enterprise to the address input of the database server, the synchronizing output of the unit unit for correcting the unit labor costs is the second synchronizing system output for issuing control signals for reading the unit labor costs for the enterprise units input of the second channel for interrupting the database server, the recognition module dir a system for reading / writing memory of the database of the server of the system, the first information input of which is the fourth information input of the system, intended for receiving codes of free capacities of labor-consuming divisions of the enterprise, read from the server database, and the second and third information inputs of the recognition module for reading / writing of the database the system’s server data is connected to the fourth and fifth information outputs of the module for identifying the base address of the enterprise’s labor costs for fulfilling orders, respectively In fact, the synchronizing input of the recognition module for reading / writing memory of the database of the system server is the fourth synchronizing input of the system designed to receive the synchronizing signals of entering codes of free capacity of the labor consuming units of the enterprise, read from the server database, into the recognition module of the reading / writing mode of the database memory the system server, the first synchronizing output of the recognition module of the read / write mode of the system server database memory is connected to the counting input unit for correcting the unit labor costs, the second synchronizing output of the recognition module for reading / writing the memory of the system server database is connected to one installation input of the unit for correcting the unit labor costs, with the first synchronizing input of the control module for completing the analysis of the order array and is the third synchronizing output of the system designed to issue control signals recording the average value of free capacities of labor-intensive units to the input of the third channel for interrupting the database server, the third synchronizing output of the recognition module for reading / writing the database memory of the system server is connected to another installation input of the unit for correction of unit labor costs and to the second synchronizing input of the control module for completing the analysis of the order array, the fourth synchronizing output of the module the recognition mode of reading / writing memory of the system server database memory is connected to another synchronizing input of the value correction module tr cost of units, and at the same time it is the fourth synchronizing output of the system, designed to issue control signals to record the average value of free capacities of unit labor costs to the input of the fourth channel of the database server interrupt.

Images