RU52502U1 - INFORMATION AND ANALYTICAL SYSTEM FOR FORECASTING AIR TRANSPORT REVENUE - Google Patents

Abstract

The invention relates to computer technology, in particular, to an information-analytical system for forecasting air traffic revenues.

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

The technical result is achieved in that the system contains three registers, three counters, a base reading address selection module, a feature selection module, a memory module, a database read signal generator, two comparison modules, a comparator, trend detection and prediction modules.

Description

The utility model relates to computer technology, in particular, to the information-analytical system for forecasting the profitability of air transportation.

The basis of any automated management, first of all, are management accounting and control. Management accounting records the results of passenger air transportation, and control tracks the actual results of operations in comparison with the plan.

Indeed, the route network management department, together with the departments of marketing, economics and financial planning, revenue management, and the information and analytical center of the airline’s commercial unit, are developing a plan for the implementation of passenger air transportation, and the information and analytical center of the commercial unit records data on the actual implementation of the plan (Fig. 8).

The Department of Economics and Financial Planning should be able to fix the plan and fact mismatch vector (control error vector) and manage the process of increasing the efficiency (profitability) of flights by predicting the consequences of making possible decision options.

For the operational analysis and decision-making on passenger traffic performed for any given period, as a rule, the following set of indicators is used: flight number, route name, number of completed flights of each number for a given period, income per flight, income per passenger kilometer, average return rate per flight, for each booking class, total flight income for a given period, occupancy rate of seats on the flight, number of passengers carried, million passenger kilometers, million armchair kilometers, etc.

Comparison of the dynamics of changes in these indicators in their interconnection allows us to judge with sufficient probability the potential of the operated market, the structure of passenger traffic (at the profitable rate), the effectiveness of the schedule (the correct placement of aircraft), the correct application of tariffs, etc.

In this regard, it seems advisable to create such an information-analytical system that would ensure the achievement of the highest efficiency (profitability) of flights.

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

The first known system includes data receiving and storage modules connected to data management and processing modules, search and selection modules connected to data storage modules

and mappings, 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 eliminating data search for decision making throughout the server database and localizing the search only by temporary and

distinguishing features of identifiers of economic indicators.

This goal is achieved by the fact that in a known system containing a memory module, information outputs of which are connected to the corresponding information inputs of trend detection and prediction modules, the outputs of which are information outputs of the group of information outputs of the system, the first register, the information and synchronization inputs of which are the first information and synchronizing inputs of the system, the second register, the installation input of which is connected to the installation output of the memory unit, tr this register, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, and the output of the third register is the information output of the system, the first counter, the information input of which is the third information input of the system, and the synchronizing input is connected to the first synchronizing input of the system, the driver of read signals database, the information output of which is the address output of the system, and the synchronizing output is the synchronizing you during the system, a read base address identification module is introduced, the information input of which is connected to the output of the first counter, the first clock input of the read base address identification module is connected to the first clock input of the system, one information output of the read base address identification module is connected to the information input of the base read signal generator

data, another information output of the identification base address identification module is connected to the information input of the second register, and the synchronization output of the read base address identification module is connected to the synchronization inputs of the second register and the database read signal generator, respectively, the feature selection module, the first information input of which is connected to one the output of the first register, the second information input of the feature selection module is connected to the output of the third register, and synchronously the coding input of the feature selection module is connected to the second synchronizing input of the system, the first comparison module, one information input of which is connected to another output of the first register, the other information input of the first comparison module is connected to the information output of the feature selection module, and the synchronizing input of the first comparison module is connected to the synchronizing the output of the feature selection block, the second counter, the counting input of which is connected to one output of the first comparison module, and the output of the second counter connected to the information input of the memory unit, the third counter, the counting input of which is connected to the other output of the first comparison module, the second comparison module, one information input of which is connected to the output of the second register, the other information input is connected to the output of the third counter, and the clock input of the second comparison module connected to another output of the first comparison module, while the first output of the second comparison module is connected to the counting input of the driver of the read signals of the database, and the second output connected to the control input of the memory module, and the third comparison module, one information input

which is connected to the information output of the memory unit, the other information input of the third comparison module is the fourth information input of the system, and the synchronization input is connected to the installation output of the memory module, while one output of the third comparison module is connected to the counting input of the first counter and to the second synchronization input of the identification module the base reading address, and the other output is connected to the synchronizing inputs of the trend detection and prediction modules, and to the installation inputs of the memory module The first, second and third counters.

The invention is illustrated by drawings, in which Fig. 1 shows a structural diagram of a system, Fig. 2 shows an example of a specific structural implementation of a module for identifying a base address of a reading, Fig. 3 shows an example of a specific constructive implementation of a module for selecting features, Fig. 4 - an example of a specific constructive implementation of a memory module is shown, in Fig. 5 an example of a specific constructive implementation of a database read signal generator is shown, in Fig. 6 an example of a specific constructive the implementation of the first comparison module, Fig.7 is an example of a specific structural implementation of the module of the comparison unit.

The system (Fig. 1) contains the first 1, second 2, and third 3 registers, the first 4, second 5, and third 6 counters, a base reading address identification module 7, a feature selection module 8, a memory module 9, a database read signal generator 10, the first comparison module 11, the second comparison module 12, the third 13 comparison module, made in the form

a comparator, a trend detection module 14 and a prediction module 15.

Figure 1 shows the first 21, second 22, third 23 and fourth 24 information inputs of the system, the first 25 and second 26 synchronizing inputs of the system, as well as the first 27 and second 28 information outputs of the system, a group of 29-30 information outputs of the system, and synchronizing output 31 of the system.

The reading base address identification module 7 (FIG. 2) comprises a memory module 41 made in the form of read-only memory, a decoder 42, AND elements 43-45, OR element 47, delay elements 48-49. The drawing also shows inputs 50-52 and outputs 54-56.

Module 8 selection of signs (figure 3) contains a decoder 61, a group of elements 62-64 AND, a group of elements 65 OR, an element 66 of the delay. The drawing also shows inputs 71-73 and outputs 74.75.

The memory module 9 (Fig. 4) contains elements of registers 81-83, counter 84, decoder 85, elements 86-88 AND, elements 89, 90 of the delay. The drawing also shows inputs 95-97 and outputs 100-104.

The database read signal generator 10 (FIG. 5) comprises a counter 111, OR elements 112, and a delay element 113. The drawing also shows information 114, synchronizing 115 and counting 116 inputs, information 117 and synchronizing 118 outputs.

The first comparison module 11 (FIG. 6) comprises a comparator 121, an OR element 122, and a delay element 123. The drawing also shows informational 125 and 126, and synchronizing 127 inputs, the first 128 and second 129 outputs.

The second comparison module 12 (Fig. 7) includes a comparator 131 and a delay element 132. The information 133, 134 and the synchronizing 135 inputs, and the first 136 and second 137 outputs are also shown in the drawing.

The third module 13 comparison is made in the form of a standard comparator.

The trend detection module 14 implements the trend detection function using a standard program from the Excel 2000 software library [3].

Prediction module 15 implements the prediction function using a standard program from the Excel 2000 software library [3].

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

The system operates as follows.

In the database of the system, economic indicators for each of the completed passenger flights are stored in the form of records having the following structure:

THE CODE THE CODE FLIGHT ID ATTRIBUTES OF FLIGHT

The following economic indicators can act as flight attributes:

№№ ATTRIBUTES OF FLIGHT 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 tasks of forecasting the profitability of air transportation at the workplace of users of the system, requests are generated that indicate the type of the selected flight attribute (data attribute) as a variable of the mismatch vector, the year of the beginning of the time interval from which the data needed to make a decision will be analyzed, and the number of 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 user request codogram will have the following structure:

TYPE OF YEAR QUANTITY 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 feature and its numerical value from the information input 21 of the system goes to the information input of register 1, the digital value of the year from the information input 23 of the system goes to the information input of the counter 4, and the digital value of the interval from the information input 24 of the system goes to the information input 139 comparator 13.

The arrival of the request codogram is accompanied by a synchronizing pulse arriving at the input 25 of the system, from where it is supplied to the synchronizing input of register 1, entering the input code into register 1, and to the synchronizing input of counter 4, entering the digital value of the year.

In addition, the same clock pulse through the input 51 of module 7 passes through the OR element 47, is delayed by the element 48 for the time the code is entered into the counter 7 and the decoder 42 is activated, and the state of the 43-45 OR elements is interrogated.

Decoder 42 decrypts the digital value of the year, giving out one of its outputs high potential and thereby opening one of the elements 43-45 I.

Given the fact that only one of the elements 43-45 I will be open at one input, then, having passed the corresponding element And, the clock pulse is fed to the read input of a fixed memory cell of the permanent storage device 41, 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 41 has the following form:

The base address code of the database server memory partition Code for the 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 54 of module 7 is issued to the input 114 of the shaper 10 of the read signals of the database, and the code of the total number of records of flights from the output 55 is issued to the information input of the register 2.

In parallel with this, the clock from the output of element 48 is delayed by element 49 for the duration of reading data from ROM 41 and arrives at both the synchronizing input 115 of the driver 10, ensuring the code of the base address is entered into the counter 111, and at the synchronizing input of the register 2, ensuring it is entered code for the total number of flight records.

At the output 117 of the shaper 10 and, accordingly, at the output 27 of the system, the base address of the year of data reading will be generated.

In addition, the same clock pulse from the input of the element 115 of the shaper 10 passes through the element 112 OR, is delayed by the element 113 for the duration of the counter 111 operation, and through the output 118 of the shaper 10 is issued to the output 31 of the system, from where it goes to the interrupt input of the database server.

With the arrival of this impulse, the database server proceeds to the subprogram for polling the contents of the base address of the current year and reads the contents of the first memory cell to the information input 22 of register 3, where the read data record is entered by the server synchronizing pulse received at the system input 26.

At the same time, the synchronizing pulse from input 26 goes to the synchronizing input 73 of block 8, where it is delayed by element 66 for the time the recording code is entered into register 3, and then from the output 75 of module 8 it goes to the synchronizing input 127 of the comparator 121 of module 11, to the input 125 which has a characteristic code, for example, income attributable to each flight.

The decoder 61 of module 8 decrypts the feature code and opens one of the groups of elements 62-64 AND, through which the corresponding bits of codes from the output of register 3, corresponding to the attribute of the mean value of income, pass through elements 65 OR to the output 74 of module 8 and then go to another 126 module input 11.

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 128 of the comparator 121 of module 11, which arrives both at the counting input of the counter 5, counting the number of signs with a similar numerical value, and through OR element 122 and the output 129 of the module 11 to the counting input of the counter 6, counting cumulatively the total number of read records.

In addition, the same synchronizing pulse from the output 129 of the module 11 is fed to the input 135 of the block 12, where it is delayed by the element 132 for the duration of the counter 6 operation, and then it goes to the synchronizing input 135 of the comparator 131 of the block 12. The comparator 131 compares the total number of records by this signal available in the database of the current year, entering input 133, with the number of read records entering input 134.

If the number of read and viewed records of the current year in the counter 6 is less than the specified number, then the comparator 131 generates a signal at the output 136 of the block 12, which through the input 116 of the shaper 10 enters the counting input of the counter 111, forming the next read address at the output 27 of the system.

In addition, the same synchronizing pulse from the input 116 passes through the element 112 OR, is delayed by the element 113 for the duration of the counter 111 operation, and through the output 118 of the former 10 is issued to the output 31 of the system, from where it again goes to the interrupt input of the database server.

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 22 of register 3, where the read data record is entered by the synchronizing server pulse received at the system input 26.

The process of reading the database records and counting the number of records with the selected features continues until the comparator 131 of the module 12 fixes the equality of the input codes by generating a signal at the output 137 of the module 12, which will indicate that all data records of the current year have been viewed, and the number of flights with a given attribute is counted in the counter 5.

The signal from the output 137 of the module 12, firstly, through the input 96 of the module 9 passes through the element 86 AND, open at the other input with a high potential from the output of the decoder 85, to the synchronizing input of the register 81, entering into it the number of indicators of income of the current reading year, fixed counter 5.

Element 86 And will be in the open state because the counter 84 of module 9 up to this point in time was in the initial state, in which the decoder 85 generated a high potential coming to one input of the element 86 I.

In addition, the same clock pulse from input 96 is delayed by element 89 for the time the code is entered in register 81, and, firstly, it enters the counting input of counter 84, changing its readings by one. As a result, the decoder 85 will remove the high potential from the input of the And 86 element, and will give it to the input of the next And 87 element, opening it and preparing the passage of the synchronizing pulse in the next reading cycle.

The same clock pulse from the output of the element 89 is delayed by the element 90 for the duration of the counter 84 and from the output 104 of the module 9, firstly, it enters the installation input of the register 2, setting it to its original state. Secondly, the same signal is fed to the synchronizing input 140 of the comparator 13, comparing the readings of the counter 84, received at the information input 138, with a given value of the viewing interval, received at the information input 139.

If the readings of the counter 84 of module 9 are less than the value of the time period selected for data analysis, then the output 142 of the comparator 13 generates a pulse, which output 142 enters both the counting input of the counter 4, increasing its readings by one, and through the input 52 of module 7 arrives at the input of element 47 OR.

Having passed element 47 OR, the synchronizing pulse is delayed by element 48 for the duration of operation of counter 4 and decoder 42 of module 7 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 counter 5 followed by entering in the corresponding registers 81-83 will be continued as described above.

The described process of data selection from the database and their analysis will continue until the comparator 13 fixes the equality of the number of scanned periods (years) coming from the output 103 of module 9 to the information input 138, with a given number of years arriving at the information input 139 comparator 13.

At this point in time, according to the synchronizing signal from the output 104 of module 9 to the input 140 of the comparator 13, the latter generates a signal at the output 141, which, firstly, is supplied to the control inputs of the trend detection module 14 and the prediction module 15, to the information inputs of which from the outputs 100-102 of block 9, numerical values of the number of flights in each of the viewed periods with an average income for each flight greater than or equal to the value specified by the user are constantly supplied.

Secondly, the signal from the output 141 of the comparator 13 is supplied both to the installation input 97 of the module 9, and from there it is fed to the installation input of the counter 84, returning it to its original state, and to the installation inputs of the meters 4-6, preparing them for the next cycle work.

To implement the functions of detecting trends and predictions, modules 14 and 15 use software from the Excel 2000 software library [3].

In particular, module 14 predicts the number of flights with a given average income for each flight using the standard Excel 2000 function - TREND.

The specified function allows linear extrapolation, or, in other words, to calculate the most suitable straight line that passes through a sequence of given points. In fact, we are talking about a problem in which a set of points is plotted, and then a straight line is selected, given by the equation Y = ax + b, by which it is possible to trace the development of the function with the smallest error.

The TREND () function returns (i.e. its result is) an array of numbers that can be used to build a trend line (trend) - a straight line that helps to understand the behavior of the actual data.

The function has four arguments:

= TREND (known_values_y; known_values x; new values x; const).

The first two are the known values of the dependent and independent variables, respectively.

The argument known_values_y is a single column, a single row, or a rectangular range.

- If the argument known_values_y consists of one row or one column, then, respectively, each column or row in the argument known values of x is considered as an independent variable.

- If the argument known values of y is a rectangular range, then only one independent variable can be used. In this case, the argument known values of x should be a rectangular range of the same size and shape as the known values of y. The third and fourth arguments are optional. If constant b const is included, the value of this argument must be TRUE or FALSE (1 or 0). If this argument is omitted or equal to 1, then the constant b is calculated in the usual way, otherwise it is set equal to 0 and the equation of the line has the form y = ax.

Consider an example that explains the analysis of changes in the rate of return on flights recorded in the database of the system for a time interval equal to seven consecutive years (Table 1).

Table 1 Serial number of the year Numerical values of the rate of return on flights Trend BUT AT FROM one 33650 1928 2 33650 60834 3 63860 119740 four 214170 178646 5 274340 237552 6 285410 296458 7 345440 355364 8 455283 - forecast for 8 years.

In this example, to calculate a trend line that approximates known data, the third and fourth arguments are omitted from the function. The array of results in column C is the same size as the range of known x values in column A.

To find the value of each point on the regression line, which approximates the data of column B, the function TREND () is used.

In this example, the argument y is the range B1: B7. The argument known_name_x is the range A1: A7. It stores the numbers of the years by which the trend is traced.

To calculate the predicted values of the levels of numerical indicators for one, two or more years in advance, one should introduce new values of x into the number of arguments of the array function.

Module 15 predicts the numerical value of the flight profitability indicator using the statistical prediction function (FORECAST), which calculates the future value of the numerical indicators based on existing values. The predicted value is the y-value corresponding to the given x-value.

Known values are x- and y- values, and a new value is predicted using linear regression.

The Predict function has the following syntax:

= PREDICT (x; known y values; known x values).

Here x is the data point for which the value is predicted.

Known y values are a dependent array or data interval.

Known values x) is an independent array or interval of data.

To illustrate the application of this statistical function, we use the same data from table 1.

table 2 Serial number of the year The numerical value of the rate of return on flights BUT AT one 33650 2 33650 3 63860 four 214170 5 274340 6 285410 7 345440 8 414351 - forecast

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.C. G 06 F 13/40, 13/38, 1992

2. US Patent No. 5129083 M.C. G 06 F 12/00, 15/40, 1992 (prototype).

3. Mark Dodge, Craig Stinson., Effective work with Microsoft Excel 2000. Publishing house "Peter", 2002 p.531-565

Claims (1)

An information-analytical system for forecasting the profitability of air transportation, containing a memory module, the information outputs of which are connected to the corresponding information inputs of the trend detection and prediction modules, the outputs of which are the information outputs of the group of information outputs of the system, the first register, the information and synchronizing inputs of which are the first information and synchronizing system inputs, the second register, the installation input of which is connected to the installation in a memory block, the third register, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, and the output of the third register is the information output of the system, the first counter, the information input of which is the third information input of the system, and the synchronizing input is connected to the first synchronizing input of the system , a database read signal generator, the information output of which is the address output of the system, and the synchronizing output is system synchronization output, characterized in that it contains a read base address identification module, the information input of which is connected to the output of the first counter, the first clock input of the read base address identification module is connected to the first clock input of the system, one information output of the read base address identification module is connected to the information input of the database read signal generator, another information output of the base address identification module the readout is connected to the information input of the second register, and the synchronization output of the identification module of the base read address is connected to the synchronization inputs of the second register and the driver of the database read signals, respectively, the feature selection module, the first information input of which is connected to one output of the first register, the second information input of the module feature selection is connected to the output of the third register, and the synchronizing input of the feature selection module is connected to the second synchronization system input, the first comparison module, one information input of which is connected to another output of the first register, the other information input of the first comparison module is connected to the information output of the feature selection module, and the synchronization input of the first comparison module is connected to the synchronization output of the feature selection unit, the second counter, the counting input of which is connected to one output of the first comparison module, and the output of the second counter is connected to the information input of the memory block, the third counter, counting the input of which is connected to the other output of the first comparison module, the second comparison module, one information input of which is connected to the output of the second register, the other information input is connected to the output of the third counter, and the clock input of the second comparison module is connected to the other output of the first comparison module, while the first the output of the second comparison module is connected to the counting input of the database read signal generator, and the second output is connected to the control input of the memory module, and the third comparison module, about the information input of which is connected to the information output of the memory unit, the other information input of the third comparison module is the fourth information input of the system, and the synchronization input is connected to the installation output of the memory module, while one output of the third comparison module is connected to the counting input of the first counter and to the second synchronizing the input of the identification module of the base reading address, and the other output is connected to the synchronizing inputs of the trend detection and prediction modules, and is set to secondary inputs of the memory module, the first, second and third counters.