RU77466U1 - AUTOMATED SCENARIO FORECASTING SYSTEM FOR THE DEVELOPMENT OF THE AIRLINE - Google Patents

Abstract

The utility model relates to computer technology, in particular, to an automated airline forecasting system.

The technical result is to increase the system performance by excluding data search for forecasting over the entire database and localizing the search only by the temporary and distinctive signs of the identifiers of signs of the corresponding indicators.

The technical result is achieved by the fact that the system contains a module for selecting base addresses of prediction indicators in the server database, a module for identifying the boundaries of forecasting time cycles, a module for current addressing of records in the server database, a module for selecting attributes of the initial forecasting data, a module for selecting numerical values of specified forecast parameters, RAM module for numerical values of time series; module for identifying the boundaries of the forecast range. 9 ill.

Description

The utility model relates to computer technology, in particular, to an automated airline forecasting system.

Despite the fact that the definition of the demand function, income, expenses and other indicators of an airline’s activity is a fairly rich source of information, this is still not enough to predict the future activities of the airline.

To do this, it is necessary to predict the mutual influence of each variable on each other using a predictive model that takes into account all parameters, as well as possible ways to assess the mutual influence of these parameters in the process of their evolution. Such an approach will make it possible to predict the airline’s passenger traffic, as well as a vector of indicators characterizing its financial health, with 20-25 year lead horizons.

A similar approach allows predicting the activity of the airline in terms of traffic, aircraft fleet,

the number of employees is just as successful as in terms of revenues, costs, and unit revenues, reflecting the average cost of tickets.

Hypotheses about annual changes in average income rates (tariffs), productivity indicators, seat occupancy rates, etc. are allowed as initial ones, and passenger turnover (RPK) values, fleet sizes, required personnel resources, expected profits are determined as output forecasts.

All information on airline performance indicators is contained in the database, which includes data on income and expenses, as well as on production indicators (RPK, ASK, etc.) for the base year under consideration. The database also stores indicators of the elasticity of demand for passenger transportation in the form of coupling coefficients between the number of passengers and influencing variables of an economic and demographic nature.

If the model has all the necessary input data, the range of necessary forecasts about the state of the airline can be set by an expert, taking into account each hypothesis regarding the annual variations of the variables in question. In other words, each accepted hypothesis defines a scenario for modeling the future state of the airline.

This model has flexibility, because it allows you to choose either the mode of determining the required profit for each year (or several years) of forecasting, in which case the model will select the profitable rate or Yield in order to ensure the required level of profit; either a mode of fixed changes in the yield rate or Yield for each year (or several years) of forecasting, then the model will determine their effect on demand and,

therefore, on the projected financial results of the airline.

The model provides forecasts provided that only correct hypotheses and scenarios are set, for example, the model will not be able to find solutions for cases of not real increase in profit, or the airline’s profit rate.

To solve the modeling problem, the following variables can be used:

1. Input data on expenses:

• flight crew costs per bl. hour;

• cost of aircraft on a flight day;

• the cost of ground equipment on a flight day;

• cost of service for each bl. hour;

• other indirect costs for each seat.

2. Production performance:

• liters per block hour (fuel consumption);

• aircraft capacity (number of seats);

• flight hours (Bl.hour) per day (aircraft utilization factor);

• ASK / flying hours.

3. Personnel performance indicators:

• flight hours / number of flight crew;

• flying hours / number of ground personnel.

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

The first of the known systems contains modules for receiving and storing data connected to control and data processing modules,

search and selection modules connected to data storage and display modules, the synchronizing inputs of which are connected to the outputs of the control module (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, 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 invention is to increase the system performance by excluding data search for decision-making throughout the database

server data and search localization only by temporal and distinguishing features of identifiers of economic indicators.

This goal is achieved by the fact that in a known system containing a module for selecting base addresses of forecasting indicators in the server database, the information input of which is the first information input of the system designed to receive a numerical value of annual intervals of forecasting, synchronizing the input of the module for selecting base addresses of forecasting indicators in the database server data is the first synchronizing input of the system, intended for receiving synchronizing signals of entering numbers the new value of the annual prediction intervals in the selection module for the base addresses of forecast indicators in the server database, the module for the current addressing of entries in the server database, the information input of which is connected to the first information output of the module for selection of the base addresses of forecast indicators in the server database, synchronizing the input of the module for the current addressing records in the server database is connected to the synchronizing output of the selection module of the base addresses of the prediction indicators in the database Rver, the address output of the module for the current addressing of records in the server database is the address output of the system intended for issuing the addresses for reading data to the address input of the database server, and the synchronizing output of the module for the current addressing of records in the server database is the first synchronizing output of the system for issuing control signals to the input of the first channel of the database server interrupt, the module for selecting attributes of the source data

prediction, the first and second information inputs of which are the second and third information inputs of the system, intended for receiving server database records, the first synchronizing input of the selection module of attributes of the initial data of forecasting is connected to the first synchronizing input of the system, and the second synchronizing input of the module of selection of attributes of the source of forecasting data is the second synchronizing input of the system, intended for receiving synchronizing signals for recording records of the base d server data into the selection module of attributes of the initial data of forecasting, and the module of random access memory of the numerical values of time series, the information outputs of the group of which are the information outputs of the system group, intended for the output of the initial data of forecasting to the information inputs of the server group, the module of the selection of numerical values of the specified forecast parameters is introduced, the first and second information inputs of which are connected to the first and second information outputs of the attribute selection module ref one forecasting data, the third information output of which is the information output of the system, intended for the output of the specified values of the initial forecasting data to the information input of the database server, and the synchronizing input of the selection module of the numerical values of the specified forecasting parameters is connected to the synchronizing output of the selection module of the attributes of the initial forecasting data, module identifying the boundaries of time prediction cycles, the information input of which is connected to the second formation output of the module for selecting base addresses of forecasting indicators in the server database, first

the synchronizing input is connected to the synchronizing output of the selection module of the base addresses of the prediction indicators in the server database, the installation input of the module identifying the boundaries of the time series of forecasting is connected to the synchronizing output of the module memory of the numerical values of the time series, the second and third synchronizing inputs of the module identifying the boundaries of the time cycles of forecasting are connected to the first and second clock outputs of the selection module of the numerical values of the specified forecast parameters Accordingly, in this case, the first output of the module for identifying the boundaries of the time cycles of forecasting is connected to the counting input of the module for the current addressing of records in the server database, and the second output of the module for identifying the boundaries of the time cycles of forecasting is connected to the clock input of the memory module of the numerical values of time series, and the first clock the output of the module for selecting the numerical values of the specified forecasting parameters is connected to the counting input of the RAM module of the numerical values of the time rows, and a prediction range boundary identification module, one information input of which is the third information input of the system intended for setting the current value of the forecasting variable, another information input of the forecast range boundary identification module is connected to the information output of the random access memory module of numerical values of time series, and a synchronization input the prediction range boundary identification module is connected to the synchronizing output of the operational module th memory numeric time series values, with one output of the module

identifying the boundaries of the forecast range is the second synchronizing output of the system, intended for issuing control signals to the input of the second interrupt channel of the database server, and connected to the installation input of the module for identifying the boundaries of the time cycles of forecasting and to the counting input of the selection module of the base addresses of the prediction indicators in the server database, and the other output of the prediction range boundary identification module is connected to the installation inputs of the random access memory module number s values of time series and forecasting module selection of basic indicators of addresses in the server database.

The invention is illustrated by drawings, where Fig. 1 shows a structural diagram of a system, Fig. 2 shows an example of a specific structural implementation of a module for selecting base addresses of modeling indicators in a server database, Fig. 3 shows an example of a specific constructive implementation of a module for identifying time boundaries forecasting cycles, Fig. 4 shows an example of a specific constructive implementation of the module for the current addressing of records in the server database, Fig. 5 shows an example of a specific constructive rea 6, an example of a specific constructive implementation of the random access memory of numerical values of time series, Fig. 7 shows a scenario forecasting scheme, Fig. 8 shows a diagram of an interconnected scenario forecasting model, and Fig. 9 shows an example of results forecasting scenario 2.

The system (figure 1) contains a module 1 selection of base addresses of prediction indicators in the server database, module 2

identifying the boundaries of forecasting time cycles, module 3 for the current addressing of records in the server database, module 4 for selecting attributes of the initial forecasting data, module 5 for selecting numerical values of predetermined forecast parameters, module 6 for random access memory for numerical values of time series, module 7 for identifying the boundaries of the forecasting range.

Figure 1 shows the first 10, second 12, third 13 information inputs of the system, the first 14 and second 15 synchronizing inputs of the system, as well as address 16 and information 17 outputs of the system, a group of 18-20 information outputs of the system, the first 21 and second 22 synchronizing system outputs.

The identification module 1 of the reference address for reading the server database data (Fig. 2) contains a counter 25, a decoder 26, a memory unit 27 made in the form of read-only memory, elements 28-30 AND, element 31 OR, elements 32-33 delay. The drawing shows information 34, synchronizing 35, counting 36 and installation 37 inputs, as well as the first 38 and second 39 information and synchronizing 40 outputs.

Module 2 (FIG. 3) comprises a register 41, a counter 42, a comparator 43 and an OR element 44 and a delay element 54. The drawing shows information 45, synchronizing 46, the first installation 47, the second 48 and third 49 synchronization inputs and the second 50 installation inputs, as well as the first 51 and second 52 outputs.

Module 3 (FIG. 4) comprises a counter 55, an OR element 56, and a delay element 57. The drawing shows information 58, synchronizing 59 and counting 60 inputs, as well as information 61 and synchronizing 62 outputs.

Module 4 (FIG. 5) contains registers 65, 66, a decoder 67, groups of 68-70 AND elements, a group of 71 OR elements, a delay element 72. The drawing also shows the first 74 and second 75 information, the first 76 and second 77 clock inputs, as well as the first 78, second 79 and third 80 information and clock 81 outputs.

Module 5 (figure 1) is made in the form of a comparator, having the first 82 and second 83 information, synchronizing 84 inputs, as well as the first 85 and second 86 outputs.

Module 6 (Fig.6) contains counters 90, 91, a decoder 92, registers 93-95, elements 96-98 AND, elements 99, 100 delay. The drawing also shows a counting 101, synchronizing 102 and installation 103 inputs, as well as information output 104, information outputs of the group 105-107 and sync 108 output.

The module (Fig. 7) is made in the form of a comparator having the first 110 and second 111 information and synchronizing 112 inputs, as well as the first 113 and second 114 outputs.

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

The system operates as follows.

When creating a scenario, you must determine the estimated annual changes to the variables. In this system, this is easily accomplished by introducing for the same period changes in the selected variables.

In general, the expert enters the average ticket prices (the average income rate indicator is used instead), the average flight duration, the average delay time, the seat occupancy rate, and the average aircraft flight per day, and determines new levels of RPK, ASK, and aircraft values.

For this purpose, an expert can use the following sections of the system database:

- A database of social statistics (DB SS), which contains information on past and expected indicators of demographic growth, unemployment, population income, GDP, etc.

- database of operational statistics (DB SS), which contains operational information on completed flights;

- competitor database (competitor database), which is a database containing information about the activities of competing airlines;

- cost database (cost database), which contains information on line-by-line costs of completed flights.

The general calculation cycle includes the following main steps:

1. Using information from statistical databases, the expected level of RPK for the forecast period is determined. Multiplying the RPK score by the value of the expected return rate, you can get the airline’s income level.

2. Using the RPK value obtained in the previous step, as well as the annual change in the load factor (LF), the ASK level estimate for each year of the forecast period is calculated

3. The level of costs associated with passengers is directly determined by the RPK value.

4. Knowing the average flight time, average delay time and the expected number of flights, the total flight hours required to meet the expected demand are calculated.

5. Using the flight hours calculated in the previous step and the average flight time per aircraft per day, the required number of aircraft is calculated.

6. Knowing the flying hours are calculated the cost of the flight crew.

7. The cost of air navigation is also determined by the total flight hours.

8. Based on the cost of fuel in the base year and taking into account the growth specified in the scenario, the average expected cost of a ton of kerosene is determined.

9. Fuel and lubricant costs are calculated based on flight hours, fuel cost, fuel consumption per flight hour and ASK / bl.hour value.

10. The cost of maintenance is determined by the standards for aircraft maintenance, as well as the projected ASK and the total flight hours.

11. Using the value of indirect costs in the base year and taking into account the level of their growth, the level is determined; the level of indirect costs for the forecast period is determined.

12. The scheme for determining administrative costs is similar to the algorithm for determining indirect costs.

Summing up the cost value for all articles for each year, the forecast value of the total costs of the airline is calculated.

Knowing the expected income allows you to determine the expected financial results of the airline in the forecast period.

The following economic indicators can act as flight attributes:

№№ Flight Attributes one Route name 2. The number of completed flights of this route for a given period 3. Income per flight on this route four. Passenger Kilometer Income 5. Average flight return rate 6. Average revenue rate for each booking class 7. Complete flight revenue for a given period 8. Percentage of seat occupancy on flight 9. Number of passengers carried 10. Million passenger kilometers eleven. Million Wheel Kilometers

To solve the problem at the workplace of the system’s experts, requests are generated that indicate the type of data attribute to be selected, for example, the flight attribute as a variable of the mismatch vector, the year the time interval begins, from which the data needed to make a decision will be analyzed, and the quantity periods (years) in the time interval that will be used to analyze economic indicators.

To illustrate the operation of the system, as the variable of the mismatch vector, we choose the average income per flight.

Thus, the generated codogram of the expert’s request will have the following structure:

Type of Year amount data variable variable mismatch vector the beginning of the time interval from which data will be analyzed periods (years) in the time interval The numerical value of the indicator (average income) The code of the selected characteristic is entered Enter the numerical value of the year Interval value is entered Enter the numerical value of the indicator

In this case, the code of the selected characteristic and its numerical value from the information input 11 of the system through the information 74 of module 4 is supplied to the information input of the register 65, the digital value of the year from the information input 10 of the system through the information input 34 of module 1 is sent to the information input of the counter 25, and the digital value interval from the information input 12 of the system through the information input 75 of module 4 is fed to the information input of the register 66.

The arrival of the request codogram is accompanied by a synchronizing pulse received at system input 14, from where it is fed through input 76 to the synchronizing input of register 65, entering the input code into register 65, and through input 35 of module 1 to the synchronizing input of counter 25, entering the digital value of the year .

In addition, the same clock pulse from the input 35 of module 1 passes through the OR element 31, is delayed by the element 32 while the code is entered into the counter 25 and the decoder 26 is activated, and the state of the OR elements 28-30 is interrogated.

The decoder 26 decrypts the digital value of the year, giving out one of its outputs high potential and thereby revealing one of the elements 28-30 I.

Given the fact that only one of the 28-30 I elements will be open at one input, then, after passing the corresponding And element, the clock pulse goes to the read input of a fixed memory cell of the permanent storage device 27, where the base address of the server memory section is stored (in the drawing shown), starting from which in this section of memory all flight records are stored, and the code for the total number of flight records made in a given year.

The structure of the read code from a fixed memory cell ROM 27 has the following form:

The code The code base address of the database server memory partition total number of flight records made in a given year

The code of the base address of the memory partition of the database server from the output 38 of module 1 is output to the input 58 of module 3, and the code of the total number of flight records from the output 39 of module 1 is output to the information input 45 of the register 41 of module 2.

In parallel, the clock from the output of element 32 of module 1 is delayed by element 33 for the duration of reading data from ROM 27 and arrives from output 40 of module 1 both to synchronization input 59 of module 3, ensuring that the base address code is entered into counter 55 and to the synchronization input 46 registers 41 of module 2, providing the entry in it of the code of the total number of flight records.

At the output 61 of module 3 and, accordingly, at the output 16 of the system, the base address of the year of data reading will be generated.

In addition, the same clock pulse from the input 59 of the module 59 passes through the OR element 56, is delayed by the element 57 for the duration of the counter 55 operation, and through the output 62 of the module 3 is issued to the output 21 of the system, from where it goes to the input of the first channel of the database server interrupt .

With the arrival of this impulse, the database server proceeds to the subroutine for polling the contents of the first cell of the base address of the current year and reads the contents of the first memory cell to the information inputs 11 and 12 of module 4 and then to information input 74 of register 65, and to information input 75 of register 66, respectively.

In the registers 65 and 66, the input data are entered by the server synchronizing pulse received at the inputs 14, 15, respectively.

At the same time, the synchronizing pulse from input 15 goes to the synchronizing input 77 of module 4, where it is delayed by element 72 for the time the recording code is entered in register 66, and then from the output 81 of module 4 it goes to the synchronizing input 84 of the comparator of module 5, to the input 82 of which a code has been given for a given characteristic, for example, income attributable to each flight.

The decoder 67 of module 4 decrypts the feature code and opens one of the groups of elements 68 - 70 And, through which the corresponding bits of codes from the output of register 66, corresponding to the attribute of the attribute of average income, pass through the elements OR 71 of the group to the output 79 of module 4 and then go to another 83 input of module 5.

If the obtained numerical value of the average income per flight is greater than or equal to the numerical value of this attribute set by the user, then an output is generated at the output 85 of the comparator of module 5, which arrives at the counting input 101 of the counter 90 of module 6, which counts the number of signs with a similar numerical value, and through the input 49 of module 2 and the element 44 OR to the counting input of the counter 42, counting progressively the total number of read records.

If the obtained numerical value of the average value of the income per flight is less than the numerical value of this attribute set by the user, then an impulse is generated at the output of 86 module 5 and through the input 48 of module 2 and then through the element 44 OR enters the counting input of the counter 42, which counts the cumulative total number of records read.

In addition, the same synchronizing pulse is delayed by the element 54 for the duration of the counter 42 operation, and then it is transmitted to the synchronizing input of the comparator 43. The comparator 43 compares the total number of records available in the database of the current year and coming from the output of the register 41 with the number of read records coming from output 42.

If the number of read and viewed records of the current year in the counter 42 is less than the specified number, then the comparator 43 generates a signal at the output 51 of module 2, which through the input 60 of module 3 is fed to the counting input of the counter 55, forming the next read address at the output 16 of the system.

In addition, the same synchronizing pulse from input 60 passes through the OR element 56, is delayed by the element 57 for the duration of the counter 55 operation, and through the output 62 of the module 3 is output to the system output 21, from where it again goes to the input of the first channel of the database server interrupt.

With the arrival of this impulse, the database server again proceeds to the subprogram for polling the contents of the next address of the current year and reads the contents of the next memory cell to the information input 12 of register 66, where the read data record is entered by the synchronizing server pulse received at the system input 15.

The process of reading the database records and counting the number of records with the selected features continues until the comparator 43 of module 2 fixes the equality of the input codes by generating a signal at the output 52 of module 2, which will indicate that all data records of the current year are viewed, and the number of flights with a given attribute is counted in the counter 90.

The signal from the output 521 of module 2, firstly, through the input 102 of module 6 passes through the element 96 AND, open at the other input with a high potential from the output of the decoder 92, to the synchronizing input of the register 93, entering into it the number of income indicators of the current reading year, fixed counter 90.

Element 96 And will be in the open state because the counter 91 of module 6 until this point in time was in the initial state, in which the decoder 92 generated a high potential coming to one input of the element 96 I.

In addition, the same clock pulse from input 102 is delayed by element 99 for the time the code is entered in register 93, and, firstly, it enters the counter input of counter 91, changing its readings by one. As a result of this, the decoder 92 will remove the high potential from the input of the 96 And element, and will give it to the input of the next element And 97, opening it and preparing the chain of passage of the synchronizing pulse in the next reading cycle.

The same clock pulse from the output of element 99 is delayed by element 100 for the duration of operation of counter 91 and from output 108 of module 6, firstly, through input 47 of module 2, it enters the installation input of register 41, setting it to its initial state.

Secondly, the same signal is fed to the synchronizing input 112 of the comparator 7, comparing the readings of the counter 91, received at the information input 111, with a given value of the viewing interval, received at the information input 13 of the system.

If the readings of the counter 91 of module 6 are less than the value of the time period selected for data analysis, then a pulse is generated at the output 113 of the comparator 7, which outputs 113 through the input 36 of module 1 to the counting input of the counter 25, increasing its readings by one, and arrives at the input of element 31 OR,

After going through the OR element 31, the synchronizing pulse is delayed by the element 32 for the duration of the counter 25 and the decoder 26 module 1 and the procedure for reading the attributes of flights of the next period and counting the numerical values of the income for each flight equal to or greater than the value set by the user in the counter 90 of module 6 with subsequent entry in the respective registers 93 - 95 will be continued as described above.

The described process of data selection from the database and their analysis will continue until the comparator 7 fixes the equality of the number of scanned periods (years) coming from the output 104 of module 6 to the information input 111, with a given number of years arriving at the information input 110 from input 13 of the system.

At this point in time, according to the synchronizing signal from the output 108 of the module 6 to the input 112 of the comparator 7, the latter generates a signal at the output 114, which, firstly, goes to the output 22 of the system and then to the input of the second channel of the database server interrupt.

With the arrival of this signal, the database server switches to the reading subroutine from outputs 18-19 of module 6, the numerical values of the number of flights in each of the scanned periods that have an average income for each flight greater than or equal to the value specified by the user and statistical processing of the received data in accordance with predetermined forecasting program.

Secondly, the signal from the output 114 of module 7 is supplied both to the installation input 103 of module 6, and from there it is fed to the installation inputs of the counter 90, 91, returning them to their original state, and to the installation input of the counter 25 of module 1, preparing them for the next cycle of work.

The effectiveness of the application of the considered approach to long-term forecasting can be illustrated by the following scenarios.

Base scenario. When compiling the script, the following parameters were used:

• Duration of the forecast 7 years (2004-2010)

• Growth of the income level of the population 5-7% per year

• Reduced unemployment rate by 1% per year

• Growth in the number of potential buyers 1% per year

• Load factor increases by 0.7% per year

• The average flight duration will be 3 hours 20 minutes

• The average delay time is 25 minutes

• The growth of indirect and administrative costs will be 1% per year

• The average raid per aircraft will be 7 hours a day

The purpose of the scenario was to determine at what minimum rate of income on RPK (yield) incomes will exceed expenses.

The change in all values is given as a percentage of the "base" year 2003. Using the values contained in the schedule and the estimated capacity (ASK), as well as the estimated load factor (LF), an estimate of passenger demand RPK was obtained. The scenario suggests a favorable direction for the development of the air transportation market, demand will increase by 4%. Since for the base year the cost coverage of revenues was -8%, and the scenario assumes a balance of costs and revenues, revenues will be 109%, and costs 93% of the base level, with an increase of Yield by 3%.

Scenario 1. The highest growth is observed in the costs of variable salaries for flight personnel, + 43%, which is due to a significant increase in raid. For the same reason, air navigation costs will increase significantly.

The costs associated with the flight increase according to the growth of ASK, that is, with its growth by + 4%, this cost item will increase by + 1%. The cost of maintaining the air fleet depends on the size of the air fleet and flight hours, compared with the base year, the change in these costs will be 99%.

Scenario 2. The second scenario adds to these assumptions an increase in the cost of fuel and lubricants by 1% per year.

Total revenues and expenses increased by 4.1% and 3.8% compared to the base year. The growth in fuel and lubricant costs amounted to 137%, which is 16% more than in the baseline scenario. Under given conditions, the yield will increase by 5% compared to the base year. The results of applying the scenario are shown in comparison with the base scenario in FIG. 10

Thus, the introduction of new nodes and blocks and new structural connections has significantly improved the system’s speed by eliminating the search for data necessary for decision-making throughout the system’s database.

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

1. US Patent No. 0,005,651 M. cl. G06F 13/40, 13/38, 1992

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

Claims (1)

An automated airline development forecasting system containing a module for selecting base addresses of forecasting indicators in the server database, the information input of which is the first information input of the system designed to receive a numerical value of annual forecasting intervals, the synchronizing input of the module for selecting base addresses of forecasting indicators in the server database is the first the system synchronization input for receiving synchronization signals the numerical value of the annual forecasting intervals to the selection module for the base addresses of forecasting indicators in the server database, the module for the current addressing of records in the server database, the information input of which is connected to the first information output of the selection module for selecting base addresses of forecasting indicators in the server database, synchronizing the input of the module of the current addressing records in the server database is connected to the synchronizing output of the module for selecting base addresses of forecasting indicators in the database server data, the address output of the module for the current addressing of records in the server database is the address output of the system designed to provide the read addresses for the data on the address input of the database server, and the synchronizing output of the module for the current addressing of records in the server database is the first synchronizing output of the system issuing control signals to the input of the first channel of the database server interruption, a module for selecting attributes of the initial data of forecasting, the first and second information inputs of which are the second and third information inputs of the system intended for receiving server database records, the first synchronizing input of the selection module of attributes of the initial data of forecasting is connected to the first synchronizing input of the system, and the second synchronizing input of the module of selection of attributes of the source of forecasting data is the second synchronizing input of the system, intended for receiving synchronizing signals for entering server database records into the source attribute selection module prediction data, and a memory module of numerical values of time series, the information outputs of the group of which are information outputs of the system group, intended for the output of the initial forecast data to the information inputs of the server group, characterized in that the system contains a module for selecting numerical values of the specified forecast parameters, the first and the second information inputs of which are connected with the first and second information outputs of the prediction source attribute selection module the third information output of which is the information output of the system, intended for the output of the specified values of the initial forecasting data to the information input of the database server, and the synchronizing input of the selection module of the numerical values of the specified forecasting parameters is connected to the synchronizing output of the selection module of the attributes of the initial forecasting data, the boundary identification module time prediction cycles, the information input of which is connected to the second information output a module for selecting base addresses of prediction indicators in a server database, the first synchronizing input is connected to a synchronizing output of a module for selecting base addresses for forecasting indicators in a server database, a setting input of a module for identifying the boundaries of forecasting time cycles is connected to a synchronizing output of a RAM module for numerical values of time series, the second and the third clock inputs of the prediction time cycle boundary identification module are connected to the first and watts by the clock outputs of the selection module for the numerical values of the specified forecasting parameters, respectively, while the first output of the module for identifying the boundaries of the time prediction cycles is connected to the counting input of the module for the current addressing of records in the server database, and the second output of the module for identifying the boundaries of the time forecasting cycles is connected to the clock input of the operational module memory of numerical values of time series, and the first clock output of the module for selecting numerical values of specified forecast parameters of the calculation is connected to the counting input of the RAM module of the numerical values of time series, and the prediction range boundary identification module, one information input of which is the third information input of the system designed to set the current value of the forecasting variable, the other information input of the forecast range boundary identification module is connected to the information output RAM module of the numerical values of time series, and the synchronizing input of the identification module and the boundaries of the forecast range is connected to the synchronizing output of the random access memory module of numerical values of time series, while one output of the module for identifying the boundaries of the forecast range is the second synchronizing output of the system, intended for issuing control signals to the input of the second channel of the database server interrupt, and connected to the installation input a module for identifying the boundaries of time forecasting cycles and to the counting input of a module for selecting base addresses of forecast indicators in the server database, and the other output of the prediction range boundary identification module is connected to the installation inputs of the random access memory module of numerical values of time series and the selection module for the base addresses of the prediction indicators in the server database.