KR20050049522A - Area dividing system - Google Patents

Abstract

A region where a plurality of vending machines are installed is divided into charge-taken areas so that each operator may efficiently go round the area. A plurality of initial setting sections (114) are set such that an area including at least one vending machine is used as an initial value. A divisional processing section (115) calculates statistics determined by the characteristics of the vending machines included in each area, and the plurality of vending machine are reverted to some of the areas so that the difference in statistic in each area may be small.

Description

 Area Division System {AREA DIVIDING SYSTEM}

The present invention relates to a system for dividing an area in which a plurality of vending machines are installed, into an area in charge of a worker who tours the vending machine.

For example, a vendor, such as a bottler, who sells merchandise at a vending machine, needs to perform regular replenishment, inventory checks, cash recovery, change of change, and garbage collection for each vending machine. have. Conventionally, when dividing the tour work of the vending machine in one business area to a large number of workers, the area division is performed by hand using a map so that the area of each charge area is about the same. By using the map in this way, it is possible to visually grasp the area division state.

Moreover, in order to make the circulation work of each worker more efficient, the attempt to make the circulation work of a vending machine efficient using a computer or a network is proposed. For example, a method has been proposed to reduce the burden on the worker performing the replenishment work of the vending machine by allowing the truck to grasp the stock situation of each vending machine in advance (see Patent Document 120). For example, a vending machine has a communication function to collect sales performance information from each vending machine through a network, and it is possible to improve the circulation efficiency of each worker by making a circuit / replenishment plan based on the sales performance information. It is proposed (refer patent document 2).

Patent Document 1: Japanese Patent Application Laid-Open No. 9-204561

Patent Document 2: Japanese Patent Publication No. 2002-42217

The above and other objects, features, and advantages are clarified by the following preferred embodiments and the accompanying drawings.

Fig. 1 is a flowchart showing the procedure of area dividing processing in the first embodiment of the present invention.

FIG. 2 is a diagram schematically showing the procedure shown in FIG. 1.

Fig. 3 is a block diagram showing the configuration of an area simulator apparatus for performing area division processing in the first embodiment of the present invention.

FIG. 4 is a diagram showing a part of the data structure of the vending machine information storage unit shown in FIG.

FIG. 5 is a block diagram showing details of an initial setting unit shown in FIG. 3.

FIG. 6 is a diagram showing a part of the data structure of the initial setting storage unit shown in FIG.

FIG. 7 is a block diagram illustrating in detail the division control unit shown in FIG. 3.

FIG. 8 is a block diagram showing details of the logic memory shown in FIG.

FIG. 9 is a diagram showing a part of the data structure of the area division information storage unit shown in FIG.

10 is a flowchart showing the procedure of seed setting processing in the first embodiment of the present invention.

FIG. 11 is a view for explaining an example of the seed setting process shown in FIG. 10.

12 is a view for explaining another example of the seed setting process shown in FIG. 10.

13 is a flowchart showing a procedure of area dividing processing in the embodiment of the present invention.

FIG. 14 is a flowchart showing a procedure for selecting candidates for the vending machine of step 102 shown in FIG.

FIG. 15 is a view for explaining an example of the area dividing process shown in FIGS. 13 and 14.

FIG. 16 is a flowchart showing the procedure of calculating the total number of courses in each divided area.

17 is a diagram showing a part of the data structure of the area division information storage unit.

18 is a diagram illustrating a screen for setting parameters and initial settings.

19 is a diagram showing a screen for setting parameters and initial settings.

20 is a diagram illustrating a screen for setting parameters and initial settings.

Fig. 21 is a diagram showing a screen for setting parameters and initial settings.

Fig. 22 is a diagram showing a screen for setting parameters and initial settings.

Fig. 23 is a diagram showing a screen for setting parameters and initial settings.

FIG. 24 is a flowchart showing the procedure of the process when the adjustment accepting unit accepts the change processing from the user to another.

Fig. 25 is a flowchart showing a procedure of seed setting processing and area division processing in the second embodiment of the present invention.

Fig. 26 is a diagram showing a setting screen for the number of seed candidates and selection conditions in the second embodiment of the present invention.

Fig. 27 is a block diagram showing the construction of the area simulator apparatus according to the third embodiment of the present invention.

FIG. 28 is a block diagram showing details of the initial setting unit shown in FIG.

FIG. 29 is a block diagram showing details of the logic memory shown in FIG.

30 is a flowchart showing a procedure of seed setting processing and area division processing in the third embodiment of the present invention.

FIG. 31 is a flowchart showing the procedure of area number calculation processing of step 222 shown in FIG.

32 is a diagram showing a screen for setting parameters and initial settings.

33 is a diagram illustrating a screen for setting parameters and initial settings.

34 is a diagram showing a screen for setting parameters and initial settings.

Fig. 35 is a diagram showing an area simulator system including the area simulator apparatus in the fifth embodiment of the present invention.

36 is a diagram showing another example of a part of the data structure of the vending machine information storage unit.

37 is a diagram showing another example of a part of the data structure of the vending machine information storage unit.

FIG. 38 is a block diagram showing the configuration when the area simulator apparatus according to the first embodiment has a data registration accepting section.

39 shows a screen for registering the vending machine information data.

40 shows a screen for registering the vending machine information data.

However, even if the area of each area was made almost equal, the number of vending machines in the area and the various environments were different. Therefore, there was a difference in labor in the circuit work. In addition, in the area division by manual work, since the charge is divided by a small amount of the person in charge, the objectivity is lowered, and there is a case where unfairness is created among the workers. In this manner, conventionally, since area division is performed simply by focusing on the area without considering the difference in environment for each area, the labor force of each worker cannot be grasped objectively.

Moreover, as a method of making the conventional circulation work more efficient, only a viewpoint has been examined from the viewpoint of how quickly each worker can tour the pre-divided charge area. It can be expected to improve the overall work efficiency to some extent by increasing the work efficiency of each worker. However, in this method, the burden on the worker becomes heavy because it depends on the individual work of the worker.

An object of the present invention is to provide a technique for objectively dividing an area in which a plurality of vending machines are installed, into a plurality of responsible areas so that a worker who performs a tour of the vending machine has a sense of fairness. Another object of the present invention is to provide a technique of dividing an area in which a plurality of vending machines are installed into a plurality of areas in charge so that the work load of the worker who performs the tour work of the vending machine becomes equal. It is still another object of the present invention to provide a technique for dividing an area in which a plurality of vending machines are installed into an area in charge of an employee who objectively performs a tour of the vending machine while visually grasping the divided state. Is in. It is still another object of the present invention to provide a technique for dividing an area in which a plurality of vending machines are installed, into a plurality of responsible areas so as to streamline the work of the worker who performs the circulation work of the vending machine. It is still another object of the present invention to provide a technique for dividing an area in which a plurality of vending machines are installed into a plurality of areas in charge so as to reduce the total work load of all of the employees who are performing the circulation work of the vending machine.

According to the present invention, an area dividing system for dividing an area in which a plurality of vending machines are installed into an area in charge of a worker performing a tour of the vending machine, wherein the area including at least one vending machine in the area according to the number of persons in charge. An initial setting section for setting a plurality, a calculation section for calculating statistics determined by the characteristics of the vending machine included in each area, a specific area in consideration of the statistics, and a vending machine added to the specific area. There is provided an area dividing system, comprising a processing unit that repeatedly executes an expanding process, terminates the process when a predetermined condition is satisfied, and determines the obtained area as the area in charge of a plurality of persons in charge.

Here, the characteristics of the vending machine include the position information of the vending machine, the layout information between the vending machines, the working time, the sales amount, the type, the moving speed or the moving time between the vending machines, the moving speed or the moving time at a predetermined point such as a base. . In addition, the statistics can be calculated based on the characteristics of all the vending machines included in the area, but can also be calculated based on the characteristics of the vending machine exhibiting specific properties in comparison with other vending machines. Here, the predetermined condition means, for example, that in this area, when all the vending machines belong to a certain area, when the candidate selection process is performed a predetermined number of times, the difference in statistics between the areas is within a predetermined range. Or when appropriate combination conditions are met.

By repeatedly executing the process of expanding the area in this manner, the area to be targeted can be objectively divided according to a predetermined criterion.

The area dividing system according to the present invention may further include a candidate selecting unit for selecting candidates of the vending machine to be added for each area, and the calculating unit calculates statistics when the candidate of the vending machine is added to each area, The processor may select a specific area in consideration of the statistics when the vending machine candidate is added.

In the area dividing system according to the present invention, the processing unit may select a specific area so that the difference in the statistics of each area becomes small in the state where the vending machine is added to a certain area.

In the area division system according to the present invention, the processing unit evaluates the uniformity of statistics of each area when a vending machine is added to a certain area, and can select a specific area based on the evaluation result.

In the area division system according to the present invention, the processing unit may select a specific area so that the difference in the statistics of each area becomes more even when a vending machine is added to a certain area. In this way, the vending machine can be attributed to any area so that the statistics are even, and the target area can be divided equally.

In the area division system according to the present invention, the processing unit can select a specific area by changing the area to which the vending machine is added, evaluating the uniformity of the statistics in each case, and comparing the uniformity. Can be.

The area dividing system according to the present invention may include a position information storage section for storing position information of the vending machine, and the candidate selecting unit may select a candidate with reference to the position information of the vending machine.

In the area dividing system according to the present invention, the candidate selecting unit may select sequentially in consideration of the distance from the representative point determined based on the position information of the vending machine which is divided in advance to each person in charge. According to the present invention, since the candidate vending machine is selected in consideration of the distance from the representative point of the area, the target area can be appropriately divided into an area having a predetermined shape.

In the area dividing system according to the present invention, the candidate selecting unit may determine a representative point based on the position information of all the vending machines which are divided in advance to each person in charge.

In the area dividing system according to the present invention, the candidate selecting unit may determine, as a representative point, the center point of the vending machine position pre-divided to each person in charge.

In the area dividing system according to the present invention, the statistic can be the work amount of each person in charge when the work is carried out by the vending machine included in each area in charge. According to the present invention, since the area is divided in consideration of the work amount of each person in charge, for example, the target area can be equally divided into the area in charge so that the work amount of each person in charge is equalized.

In the area dividing system according to the present invention, the calculating unit may calculate a statistic in consideration of the travel time between the vending machines.

The area dividing system according to the present invention can include a characteristic information storage section for storing information on the characteristics of each vending machine.

In the area division system according to the present invention, the characteristic information storage unit can store the position information of each vending machine, and the calculation unit can calculate the travel time between the vending machines based on the position information between the vending machines.

In the area division system according to the present invention, the area may include a base, and the calculation unit may calculate a statistic in consideration of the travel time between the base and each vending machine. The area dividing system according to the present invention may include a base information storage unit that stores location information of the base.

In the area dividing system according to the present invention, the calculating unit may calculate the statistics in consideration of the working time in each vending machine.

In the area dividing system according to the present invention, the calculating unit may calculate the statistics based on the type of each vending machine.

In the area division system according to the present invention, the processing unit may add the vending machine to each area so that the distance between the vending machines included in each area is within a predetermined limit distance. In this way, the vending machines at relatively close positions where the distance from each other is within a predetermined range are classified in the same area, so that the target area can be divided into areas. In addition, when the work is to be traversed between vending machines, the work time in each area can be shortened.

The area dividing system according to the present invention may include a weight setting unit for applying a weight to the statistics for each area, and the calculating unit may calculate the statistics in consideration of the weight.

The area dividing system according to the present invention may include a combination designation accepting section for accepting a combination designation of a vending machine to be included in the same charge area among a plurality of vending machines. The vending machine can be included in the same area of charge.

The area division system according to the present invention includes a map information storage unit for storing map information of an area, and a display processing unit for displaying a vending machine included in each area in charge together with map information so as to know a difference for each area. can do.

The area dividing system according to the present invention may include a feature information receiving unit which receives an input of information about a feature of the vending machine through a network.

According to the present invention, as a data structure used when dividing an area in which a plurality of vending machines are installed into an area in charge of a worker who performs a tour of the vending machine, identification of the vending machine which belongs to each area in charge in advance is in charge. The first data portion that distinguishes and accepts the information and identification information of the vending machine to be assigned to each of the respective charge areas next, and the vending machine to be assigned to each of the charge areas in advance and the vending machine to be assigned to the next. A data structure is provided, comprising a second data portion for receiving statistics calculated on the basis of information on characteristics. In this way, the vending machine assigned to each area in advance and the vending machine to be assigned to each area in the future can be distinguished and handled, and these can be combined to calculate handling and statistics.

The data structure of the present invention may include a vending machine attributable to each responsible area in advance and a data portion for receiving statistics determined by the characteristics of the vending machine which is a candidate to be attributed to each responsible area next.

In the data structure of the present invention, the information on the characteristics of the vending machine includes the location information of each vending machine, and the data structure is determined based on the location information of the vending machine which is assigned to the respective area in advance. It may include a data unit for receiving the position information of the representative point for each area in charge.

The data structure of the present invention may include a data portion that marks a corresponding area in charge when there is a change in the identification information of the vending machine accepted in the first data portion.

In the embodiment of the present invention, an example of dividing a business area including a plurality of vending machines (hereinafter, simply referred to as a "vending machine") into an area in charge of a worker who performs a tour of the vending machine will be described. Here, when dividing the vending machine included in the business area to be divided among a large number of workers to carry out the tour work, the area is divided so that the overall work efficiency is increased and the labor force of each worker is equalized. In addition, each worker visits a vending machine in his or her area every day, and tours the vending machines in his area to replenish and deliver goods, and at the end of the day, returns to the base. Therefore, in order to raise the overall work efficiency, it is preferable to perform area division by shortening the distance between the base station, the vending machine, and the vending machine, and the vending machine to which each worker moves. Moreover, in order to equalize the labor force of each worker, it is preferable to divide an area, adjusting the labor force of the circulation work in many areas.

(First embodiment)

Fig. 1 is a flowchart showing the procedure of area division processing in the first embodiment of the present invention. First, various data required for the area dividing process are registered (S1). Subsequently, the parameters required for area division are set (S2). Next, initial setting, such as setting of the number of areas (S3) provided in a business area, seed setting (S4) used as a starting point in each area, is performed. Subsequently, area division starting from the seed is performed (S5). Thereafter, the area division results are displayed, and evaluation and adjustment are performed (S6).

FIG. 2 is a diagram schematically showing the procedure shown in FIG. 1.

Prior to the area division processing, various data such as map information data, base information data, and vending machine information data are registered. Subsequently, bases and vending machines are mapped as points to map information and corresponding positions on the map information on the screen based on the registered various data. In addition, parameter setting and initial setting necessary for area division are performed. Based on the parameters and the initial settings, the business area is divided by the area division engine. Subsequently, the map information and the divided state of the area are mapped on the screen. At the same time, the statistics for each area are listed and displayed. The statistics here are, for example, the number of courses in each area (the amount of work per day), the number of vending machines included in each area, the average reloading time per vending machine, the average number of monthly reloads per vending machine, and the base from the vending machine. Information indicating characteristics of the vending machine included in each area, such as the distance average, the vending period distance average, the number of vending machines per course, the total sales, and the average sales per vending machine. The user can see the displayed divided area and statistics on the screen (not shown), and can check the divided state of the area. Based on the area-specific statistics, the parameter is reset manually or automatically as necessary, and the area division is performed again. In addition, the user can work to change the point of the vending machine belonging to each area manually by another based on the displayed information. By the above process, area divided data is created, and this data is stored.

Fig. 3 is a block diagram showing the structure of an area simulator apparatus for performing area division processing in the present embodiment. The area simulator apparatus 100 includes a display processing unit 108, a parameter setting unit 110, an initial setting unit 114, a division processing unit 115, a map information storage unit T1, and a base information storage unit T2. And a vending machine information storage unit T3, a parameter storage unit T4, an initial setting storage unit T5, an area division information storage unit T6, and a logic storage unit T7. The division processing unit 115 includes a candidate selection processing unit 116 and a division control unit 118.

The map information storage unit T1 stores map information data of a business area to be divided. The base information storage unit T2 stores base information data. The base information data includes an identification code of the base, the name of the base, the position of the base (latitude and longitude, or the y-coordinate and the y-coordinate). Here, a base is a business office in the business area, for example.

The vending machine information storage unit T3 stores the vending machine information data. The vending machine information data includes the identification code of the base, the identification code of the vending machine, the name of the vending machine, the position of the vending machine (hardness, hardness and height, or Ⅹ coordinates, Y coordinates and Z coordinates), monthly sales (yen), and monthly payload ( Dog), reloading time per minute (minutes), number of monthly reloads, moving speed from the base (km / hour), and movement period of the keyboard period (km / hour). FIG. 4 is a diagram showing a part of the data structure of the vending machine information storage unit T3 according to the present embodiment. Here, for example, the vending machine of the vending machine code "a" belongs to the base of the base code "1000", the name is "super", the position is "(Ⅹ ₁ , Y ₁ )", and the height is "ground". The working time of this vending machine is "25 minutes".

Returning to FIG. 3, the display processing unit 108 performs a process of displaying various data on a screen (not shown). The parameter setting unit 110 accepts setting of parameters necessary for area dividing the business area. The parameters include the daily standard working time of each worker, the standard working time at each vending machine, the standard moving speed between the vending machines, the standard moving speed between the base and the vending machine, the distance magnification, the vending machine acquisition limit distance, and the like. The parameter storage unit T4 stores these parameters.

The initial setting unit 114 performs initial setting necessary for area dividing the business area.

The initial setting unit 114 accepts the selection of the seed setting method, the number of areas, the weight setting, the combination designation, and the like from the user. FIG. 5 is a block diagram showing details of the initial setting unit 114 shown in FIG. The initial setting unit 114 includes a seed setting unit 122, a combination designation accepting unit 132, a weight setting accepting unit 134, and an end condition setting accepting unit 135. The seed setting unit 122 includes a seed setting method accepting unit 124, a seed setting accepting unit 126, an area number setting accepting unit 128, and a seed selecting unit 130.

Here, the side is a vending machine which becomes a starting point in each area at the time of area division. In this embodiment, for example, when dividing the business area to be divided into four, four seeds are set. The seed setting unit 122 selects a vending machine that becomes a seed in a plurality of vending machines. The seed setting method accepting unit 124 accepts a manual or automatic selection as the seed setting method. When the seed setting method accepting unit 124 receives a manual as the seed setting method, the seed setting accepting unit 126 accepts input of seed setting from the user. When the seed setting method accepting unit 124 automatically accepts the seed setting method, the area number setting accepting unit 128 accepts the setting of the area number from the user. The seed selector 130 automatically selects the number of seeds set by the area number setting acceptor 128. There are various methods for the automatic setting of seeds, but the seed is set so that the business area is divided into areas when the vending machines in the business area are classified based on each seed.

The combination designation accepting unit 132 accepts, from the user, combination designation of the vending machine to be divided into the same area among the plurality of vending machines. The user may designate the combination by referring to the point of the vending machine mapped on the screen, or may designate the combination by referring to the vending machine information storage unit T3.

The weight setting accepting unit 134 accepts the setting of the weight to be applied to the statistics when calculating the statistics in a plurality of areas set based on the seed set by the seed setting unit 122 as a starting point.

The end condition setting accepting unit 135 accepts setting of a condition for terminating the area dividing process. As the termination condition, for example, (i) when all the vending machines belong to a certain area, (ii) when the processing for which the vending machine is acquired in a certain area is performed a predetermined number of times, (iii) the difference in statistics in each area Can be made when the value falls within a predetermined range or when the conditions in which (i) to (iii) are appropriately combined are satisfied.

Returning to FIG. 3, the initial setting storage unit T5 stores these initial settings. 6 is a diagram showing a part of the data structure of the initial setting storage unit T5. Here, for example, it is assumed that the vending machines of the vending machines codes "a" to "Z" are included in the business area to be divided. The vending machine of the vending machine code "a" is selected as a seed of the area 1 here. As the seed of the area 2, the vending machine of the vending machine code "e" is selected. In addition, the weight "1" is applied to the area 1, and the weight "2" is applied to the area 2. In addition, the vending machine of the vending machine code "c" and the vending machine of the vending machine code "d" are designated by combination. Accordingly, when either the vending machine of the vending machine code "c" or the vending machine of the vending machine code "d" is acquired in a certain area, the vending machine of the vending machine code "c" and the other of the vending machine of the vending machine code "d" are also simultaneously Is acquired.

Returning to FIG. 3, the division processing part 115 performs area division of the business area of division object from the seed set by the initial setting part 114 as a starting point. The candidate selection processing unit 116 selects, for each area, a candidate for classifying a vending machine located at a position close to the representative point of the area as the area. The division control unit 118 assigns a vending machine of a corresponding candidate to a certain area so that the statistics of each area become more evenly among the areas. As shown in FIG. 7, the division control unit 118 includes a statistical calculation unit 136, a candidate attribution processing unit 138, and an adjustment acceptance unit 140. The statistical calculation unit 136 calculates a statistical value determined based on the vending machine included in each area. The candidate attribution processing unit 138 sequentially assigns a plurality of vending machines to each area so that the statistics for each area calculated by the statistical calculation unit 136 become almost equal in all areas. The adjustment accepting unit 140 performs adjustment such as changing a vending machine belonging to each area from the user to another after the area division by the candidate selection processing unit 116, the statistical calculation unit 136, and the candidate attribution processing unit 138 is performed. Receive. When the adjustment accepting unit 140 receives the adjustment from the user, the statistical calculation unit 136 calculates the statistics of each area in the case of making the adjustment. As a result, the adjustment acceptance unit 140 permits adjustment if the amount of change due to adjustment is within the allowable range.

The logic memory T7 includes a seed selection logic memory T7a, a candidate selection logic memory T7, and a statistics calculation logic memory T7c as shown in FIG. The sheet selection logic storage unit T7a stores the logic necessary for automatic seed setting in the seed selection unit 130. The candidate selection logic storage unit T7 stores the logic necessary for the candidate selection processing unit 116 to select candidates for points belonging to each area. The statistical calculation logic storage unit T7c stores the logic necessary for calculating the statistics in the statistical calculation unit 136 of the division controller 118.

When the automatic area division processing by the division processing unit 115 ends, the result is stored in the area division information storage unit T6. 9 is a diagram showing a part of the data structure of the area division information storage unit T6. Here, the business area is divided into four areas of areas 1 to 4. For example, the vending machines of the vending machine codes "a" and "b" belong to area 1. Similarly, the vending machine of the vending machine code "d" belongs to the area 2, the vending machine of the vending machine code "u" belongs to the area 3, and the vending machine of the vending machine code "z" belongs to the area 4, respectively. The area division information storage unit T6 can store various data calculated for each area based on the vending machine information of the vending machine belonging to each area. The area division information storage unit T6 stores, for example, a base-key period average moving time M ₁ , a key period average moving time M ₂ , the number of necessary vending machines N ₂ , statistics (total number of courses), and the like. These calculation methods are mentioned later.

The display processing unit 108 also displays the area division state on a screen (not shown). Accordingly, the user can grasp the area division state. The user can make adjustments such as setting parameters again, changing the initial settings, or changing the vending machine belonging to each area to another based on the displayed area division state.

FIG. 10 is a flowchart showing logic required for the seed selection section 130 stored in the seed selection logic storage section T7a to automatically set the seeds in this embodiment.

The area number setting accepting unit 128 accepts the setting of the area number (seed number) from the user (S10). Subsequently, the seed selector 130 selects any point of the area number as the initial point among the points corresponding to the plurality of vending machines in the business area (S12). The seed selector 130 may select initial points in a list order with reference to the vending machine information storage unit T3. The seed selector 130 detects the shortest distance I ₁ between the selected initial points (S14). Next, the seed selector 130 selects the next vending machine of the vending machine information storage unit T3 list as the inspection point (S16). The seed selector 130 calculates, within the initial point, the shortest distance I ₂ between the initial point of the recent lean and the test point from the test point (S18). Subsequently, the seed selector 130 performs a first inspection (S20). In the first inspection, the seed selector 130 compares the shortest distance I ₁ between the initial points detected in step 14 and the shortest distance I ₂ calculated in step 18 (S22). When the shortest distance I ₂ is larger than the shortest distance I ₁ (Yes in S22), the seed selector 130 replaces the inspection point with one of the initial points to make a new selection point (S24). The object to be replaced is an initial point having a shorter distance from the inspection point among the points constituting the shortest distance I ₁ between the initial points.

In step 22, when the shortest distance I ₂ is less than or equal to the shortest distance I ₁ (No in S22), the seed selector 130 calculates the shortest distance I ₃ from the inspection point to the initial point other than the initial point of the latest lean. (S26). In addition, the seed selector 130 calculates the shortest distance I ₄ from the initial point of the recent lean to another initial point (S28). Subsequently, the seed selector 130 performs a second inspection (S30). In the second inspection, the seed selector 130 compares the shortest distance I ₄ between the initial point of the recent lean and another initial point and the shortest distance I ₃ calculated in step 26 (S32). If the shortest distance I ₃ is large (Yes in S32), the flow advances to step 24, and the seed selection unit 130 replaces the inspection point with the initial point of the most recent frame to make a new selection point (S24).

In Step 32, when the shortest distance I ₃ is equal to or shorter than the shortest distance I ₄ between the initial point of the latest link and another initial point (No in S32), no point replacement is performed.

The above processing is performed a predetermined number of times for all points in the business area, for example, 100 times here. In step 34, when i is 100 or less (No in S34), the process returns to step 14 and the shortest distance I ₁ between the new selection points is selected. The seed selection unit 130 selects the next vending machine in the list of the vending machine information storage unit T3 as the inspection point (S16), and repeats the same processing hereinafter. On the other hand, in step 34, when i> 100 (Yes in S34), the point selection process ends. The seed selector 130 selects the selection point in this step as a seed.

FIG. 11 is a diagram for specifically describing a seed setting process described with reference to FIG. 10. Here, the number of areas is set to "3". First, as shown in Fig. 11A, points a, point b, and point c are selected as initial points. The seed selector 130 detects the shortest distance between these initial points. Here, the point a and the point b become the shortest distance L ₁ . Next, point d is selected as the inspection point. The seed selector 130 detects the initial point of the closest row from the point d, and calculates the shortest distance between the point d and the initial point of the closest row. Here, the point d and the point c become the shortest distance L ₂ . The seed selector 130 compares the shortest distance L ₁ and the shortest distance L ₂ . Here, since the shortest distance L2> shortest distance L ₁ , the seed selector 130 replaces the point d with another initial point and sets it as a new selection point. Here, the object to be replaced with the point d is either the point a or the point b constituting the shortest distance L ₁ . Seed selection unit 130, to determine the point of the replacement target for replacing the point d, the distance between point d and the replacement target point a and point b, as shown in Figure 11 (b) L ₃ and L ₄ To calculate. Since L ₄ > L ₃ , the point a becomes a substitution target. By the above processing, as shown in Fig. 11C, points b, point c and point d become new selection points. The same process is repeated, and the selection point at the time when the predetermined number of times of processing ends is selected as the seed.

12 is a diagram for explaining another example of the seed setting process. Here again, the number of areas is set to "3". First, as shown in Fig. 11A, points a, point b, and point c are selected as initial points. The seed selector 130 detects the shortest distance between these initial points. Here, between point a and point b is the shortest distance L ₁ . Next, point e is selected as the inspection point. The seed selector 130 detects the initial point of the recent lean from the point e, and calculates the shortest distance between the point e and the initial point of the recent lean. Here, between point e and point b is the shortest distance L ₂ . The seed selector 130 compares the shortest distance L ₁ and the shortest distance L ₂ . Here, since the shortest distance L ₂ < the shortest distance L ₁ , the seed selector 130 performs a second inspection.

As shown in Fig. 11 (b), the seed selector 130 calculates the shortest distance L ₃ between the point a and the point e close to the point e after the initial point b of the latest line of the point e as the inspection point. . In addition, the shortest distance L ₁ between the point b of the closest point and the closest point a is calculated. The seed selector 130 compares the shortest distance L ₃ and the shortest distance L ₁ . In this case, since the shortest distance L ₃ > the shortest distance L ₁ , the point e is replaced with the latest point b. Through the above processing, as shown in Fig. 11C, points a, point c, and point e become new selection points. The same process is repeated, and the selected point selected at the time point when the predetermined number of times of processing ends is set as the seed.

In the above processing, in the first inspection, when the shortest distance between the inspection point and the existing selection point is longer than the shortest distance between the existing selection points, the selection point is replaced, and thus the combination of points having a short distance between points is excluded. Going. Moreover, since the selection point of the one with the shorter distance from the inspection point is replaced among the selection points to be replaced, the distance between the new selection points can be made longer. Moreover, even if the conditions of the first inspection are not satisfied, in the second inspection, when the inspection point and the existing selection point are replaced, the point is replaced when the distance between other selection points becomes longer. Therefore, the selection point is replaced so that the distance between the points becomes longer. By the above processing, the vending machines in which the distances are equally long in each other in many vending machines can be set as a seed.

FIG. 13 is a flowchart showing the procedure of area division processing by the area simulator apparatus 100 according to the present embodiment. First, the seed is set manually or automatically by the initial setting unit 114 (S10O). The candidate selection processing unit 116 selects candidates for the vending machine belonging to the same area for each seed (S104).

Here, with reference to FIG. 14, the procedure by which the candidate selection processing part 116 selects the candidate of the vending machine which belongs to each area in step 104 is demonstrated. FIG. 14 is a flowchart showing logic required for the candidate selection processing unit 116 to select a candidate stored in the candidate selection logic storage T7b in this embodiment. Since the candidate selection processing unit 116 performs the same processing for each area, only one area will be described. First, the candidate selection processing unit 116 calculates the position of the representative point of each area. Here, the candidate selection processing unit 116 calculates the center of the vending machine acquired in the area as a representative point (S130). In the stage where only the seed is included in each area, the position of the seed vending machine becomes the center.

Next, the candidate selection processing unit 116 detects the vending machine located at the shortest position at the representative point of the area among the independent vending machines that do not belong to either area (S132). Subsequently, among the vending machines previously acquired in the area, the shortest distance from the vending machine detected as the candidate for the shortest machine and the machine for the candidate is calculated (S134). The shortest distance calculated here is compared with the vending machine acquisition limit set in advance by the parameter setting unit 110 (S136), and when the shortest distance is within the limit (Yes in S136), the vending machine of the candidate is located in the area. The decision is made as a candidate (S138). In a certain area, when a new candidate is determined, the candidate selection processing unit 116 sets a flag in that area. On the other hand, in step 136, if the shortest distance is not within the limit (No in S136), it is determined whether there are other independent vending machines (S140). If there are other independent vending machines (Yes in S140), the flow returns to step 132 to detect the vending machine at the next shortest position from the representative point of the area as a candidate. The same process is repeated below.

In step 140, when there is no other independent vending machine (No in S140), among all the vending machines including the acquired vending machines already acquired in another area, the vending machine located at the shortest position from the representative point of the area is detected as a candidate. (S142). Subsequently, among the vending machines previously acquired in the area, the shortest distance from the vending machine detected as the candidate for the shortest machine and the machine for the candidate is calculated (S144). The shortest distance calculated here is compared with the vending machine acquisition limit set in advance by the parameter setting unit 110 (S146), and when the shortest distance is within the limit (Yes in S146), the vending machine of the candidate is located in the area. The decision is made as a candidate (S138). On the other hand, in step 146, if the shortest distance is not within the limit (No in S146), it is determined whether or not there is another deodorant in the acquired vending machine (S148). If there is something that can be seized (Yes in S148), the flow returns to step 142 to detect the vending machine located next to the shortest position from the representative point of the area as a candidate. The same process is repeated below. In step 148, if there is no vending machine that can be seized (No in S138), the candidate selection process for this area is terminated.

 Returning to Fig. 13, it is determined whether or not a candidate has been selected in step 104 (S101). The statistical calculation unit 136 determines whether or not a candidate is selected in step 104 according to whether or not a flag is set in each area. If the candidate is selected in step 104 (YES in S10), the statistical calculation unit 136 calculates the statistics of the area including the candidate vending machine (S108). As a statistic, the total course number can be used, for example. The calculation method of the total course number is mentioned later.

Subsequently, the candidate attribution processing unit 138 detects an area where the statistics of the area become the minimum (S110). If it is detected by the candidate attribution processing unit 138 that the statistic is the minimum (Yes of SI101), the candidate attribution processing unit 138 acquires the vending machine of the candidate (S112). Subsequently, the candidate attribution processing unit 138 refers to the initial setting storage unit T5 to determine whether the area dividing process satisfies the end condition (S114). As the termination condition, for example, the independent vending machine disappeared in the business area, the candidate acquisition process in step 112 was performed a predetermined number of times, for example, 100 or more times, or the difference in statistics in each area was within a predetermined range. Things can be set. If the end condition is not satisfied (No in S114), the flow returns to step 104 to select the next candidate. In step 114, when the end condition is satisfied (Yes in S114), the area dividing process ends.

In step 110, when it is detected that the statistic is not the minimum (No in S110), the process proceeds to step 116, and the candidate attribution processing unit 138 suspends processing of the area until the candidate is acquired by another area. (No in S116). In step 116, when a candidate is acquired by another area (Yes of S116), the candidate attribution processing part 138 detects whether the vending machine acquired previously in the area was seized in another area (S118). If it is not seized (No in S118), since there is no change in the vending machines and candidates previously acquired in the area, the flow returns to step 110 to determine whether the statistic is minimum again (S110).

In step 118, when the vending machine acquired in advance in the area is seized in another area (YES in S118), the flow advances to step 114 to determine whether the end condition is satisfied. If the end condition is not satisfied (No in S114), the process returns to step 104, and the candidate selection processing unit 116 performs a process for selecting a new candidate.

On the other hand, if no candidate is selected in step 104 (No in S106), the process proceeds to step 120, and the candidate attribution processing unit 138 suspends processing of the area until the candidate is acquired by another area (step S120). No). In step 120, when a candidate is acquired by another area (Yes in S120), the candidate attribution processing unit 138 detects whether the vending machine previously acquired in the area has been taken over by another area (S122). If the vending machine previously acquired in the area is seized in another area (Yes in S122), the flow advances to step 114 to determine whether the end condition is satisfied. If the end condition is not satisfied (No in S114), the process returns to step 104, and the candidate selection processing unit 116 performs a process for selecting a new candidate.

On the other hand, in step 122, if the vending machine acquired in advance in the area is not seized to another area (No in S122), the flow proceeds to step 124, and the candidate attribution processing unit 138 refers to the initial setting storage unit T5. It is then determined whether the area dividing process satisfies the end condition. In step 124, when it is determined that the end condition is satisfied (Yes in S124), the area dividing process ends. If it is determined in step 124 that the end condition is not satisfied (No in S124), the process returns to step 120, and the candidate attribution processing unit 138 suspends processing of the area until the candidate is acquired by another area. (No in S120). Hereinafter, the same process is performed.

In the candidate selection process of step 104, the vending machine selected as a candidate of a certain area is treated as an independent. In addition, when the vending machines of candidates of many areas overlap, the area of high priority of acquisition acquires the vending machine.

FIG. 15 is a view for explaining an example of the area division processing shown in FIGS. 13 and 14. Here, area division is performed so that the total number of courses in each area is equalized. As shown in Fig. 15A, a vending machine and a base corresponding to points a to point z are provided in this business zone. Hereinafter, the case where the area number is set to 4 by the initial setting part 114 is demonstrated.

As shown in Fig. 15B, the seed setting unit 122 sets points a, point d, point u, and point z as seeds of area 1, area 2, area 3, and area 4, respectively. The display processing unit 108 performs processing so that points belonging to different areas are displayed with different marks or different colors.

As shown in Fig. 15C, the candidate selection processing unit 116 selects candidates of points belonging to the area 1, the area 2, the area 3, and the area 4, respectively. Here, the candidate selection processing unit 116 selects point e as a candidate for area 1, selects point g as a candidate for area 2, selects point q as a candidate for area 3, and points y as a candidate for area 4. Choose. The statistical calculation unit 136 gradually calculates the total number of courses in each area according to the calculation method described later. The candidate attribution processing unit 138 acquires a candidate from an area where the total number of courses becomes the minimum, and whenever an area acquires a candidate, detects an area where the total number of courses becomes the minimum and repeats the process of acquiring the candidate. .

In this way, when points are sequentially selected in each area, as shown in Fig. 15D, a plurality of points gradually belong to each area.

Hereinafter, with reference to FIG. 15 (d), a process of selecting a next candidate point in area 3 will be described. As described in step 132 of FIG. 14, the candidate selection processing unit 161 first detects the candidate candidate within an independent point. The candidate at this point is point o. The candidate selection processing unit 116 calculates the distance between the points s and the point o located closest to the point o among the points previously acquired in the area 3. The candidate selection processing unit 116 compares this distance with a preset vending machine acquisition limit distance. Here, the calculated distance is assumed to be larger than the acquisition limit distance. In this case, the candidate selection processing unit 116 cannot select the point o as a candidate of the area 3.

The candidate selection processing unit 116 sequentially detects the candidates in order of close distance from the center of the area 3 with respect to the independent points. As a result, when either point has the shortest distance from the point belonging to the area 3 in advance than the vending machine acquisition limit distance, the candidate selection processing unit 116 includes the vending machine previously acquired in another area. Redo the detection. As a result, the candidate selection processing unit 116 detects a point x belonging to another area 4 in advance as a candidate. The candidate selection processing unit 116 calculates the distance between the points s and the point x which are closest to the point x among the points previously acquired in the area 3. The candidate selection processing unit 116 compares this distance with a preset vending machine acquisition limit distance. Here, when the calculated distance is equal to or smaller than the acquisition limit distance, the candidate selection processing unit 116 selects the point x as a candidate of the area 3.

In addition, in the process just before, deodorization is not performed by setting a flag etc., for example in the point which was seized from another area. In this way, for example, if the point x was originally acquired in the area 3, and is deprived to the area 4 immediately before this processing, the area 3 cannot be recaptured from the area 4 as the next candidate. By doing so, it is possible to prevent the acquisition process of the candidate from being substantially stopped by repeating the takeover which is one point between the two areas.

According to the area dividing process in the present embodiment, since the vending machine at a position close to the representative point such as the center of the area is selected as the next candidate, each area can be formed into a block shape. Accordingly, when dividing a plurality of vending machines included in the business area into a plurality of groups while taking into account the statistics of the vending machines, the vending machines can be divided into areas without being spread between the areas. This makes it easier to grasp the status of group sharing and gives employees a fair sense.

FIG. 16 is a flowchart showing logic used by the statistical calculation unit 136 to calculate the total number of courses in each area, which is stored in the statistical calculation logic storage unit T7c. Since the same processing is performed for each area, only one area will be described here. The statistical calculation unit 136 appropriately refers to the base information data stored in the base information storage unit T2, the vending machine information data stored in the vending machine information storage unit T3, and the parameters stored in the parameter storage unit T4, and sums them in the following order. Calculate the number of courses.

The statistical calculation unit 136 _first calculates an average moving time M ₁ from the base to the vending machine and the candidate vending machine belonging to the area in advance (S160). First, the total distance from the base to the respective vending machines is calculated, and the total travel time is obtained by dividing the total distance by the base-vending period moving speed set by the parameter setting unit 110. Next, M ₁ is calculated by dividing this total travel time by the number of electronic machines in the area.

Subsequently, the statistical calculation unit 136 calculates an average moving time M ₂ between the vending machines (S162). First, the total distance from each vending machine to the nearest n vending machines is obtained, and the total travel time is obtained by dividing the total distance by the vending period moving speed set by the parameter setting unit 110. Next, by dividing this total moving time by n, the average moving time M _{1 to} m _n from each vending machine to another vending machine is obtained. Subsequently, M ₂ is calculated by adding these average moving times m ₁ to m _n and dividing by the number of electronic machines in the area. Here, when n is small, the number of electronic machines in the area can be n.

Subsequently, the statistical calculation unit 136 calculates the number of vending machines N ₁ that can be worked on daily (S164). Total working hours per day

Tz = 2 × M ₁ + M ₂ × (N ₁ -1) + TXN ₁

(T is the average working time per vending machine)

, So you can modify this expression

Calculate N ₁ = (Tz-2 × M ₁ + M ₂ ) / (M ₂ + T).

On the other hand, the statistical calculation unit 136 calculates the number of vending machines N ₂ that require processing per day (S166). First, a monthly reload number W is calculated by calculating and adding the monthly reload number for each vending machine. Next, N ₂ = W / 20 is calculated as 4 days x 5 days = 20 days per month for each worker.

The statistical calculation unit 136 then calculates the number of courses in each area = N ₂ / N ₁ by dividing the number of vending machines N ₂ that need to be processed per day by the number of vending machines N ₁ that can work per day (S168). ).

According to the above processing, when calculating the number of vending machines N ₁ that can be worked on a day, the moving time from the base to the vending machines in each area is also taken into consideration. Therefore, each area can be divided so that the distance from the base becomes almost equal. In addition, since the number of courses is calculated in consideration of the distance of the keyboard period in each area, the business area can be divided so that the moving distance in each area is equalized.

17 is a diagram showing a part of the data structure of the area division information storage unit T6. In the area division information storage section T6, an area column, an attached vending machine code column, a candidate vending machine code column, an immediate deprivation column showing a vending machine taken from another area immediately before, and a new candidate are selected to show an area requiring recalculation of statistics. Includes recalculation. The area segmentation information storage unit T6 also has a base for each area in the same manner as shown in Fig. 9-Key period average shift time M ₁ column, Key period average shift time M ₂ column, Number of necessary vending machines N ₂ column and statistics (total course) Number) field. FIG. 17A illustrates a case where a plurality of points are classified into areas as shown in FIG. 15D. At this time, since the point a is classified into the area 1, the area is stored as "a" in the "binding vending machine code" column corresponding to "1". In addition, since the point c becomes a candidate in the area 2, it is stored as "c" in the "candidate vending machine code column" column corresponding to "2" in the area. Although point w belongs to area 4, but becomes candidate in area 3, area "w" and "area" correspond to "3" in the "attribute vending machine cord" column corresponding to "4""W" is also stored in the "candidate vending machine code" column. Here, for example, when the point w is selected as the candidate in the area 3, the statistics in the area 3 need to be recalculated. In that case, the display is stored in the recalculation column corresponding to the area 3. Accordingly, the statistics calculation unit 136 can grasp the area in which statistics need to be recalculated. The statistical calculation unit 136 recalculates the statistics only for the marked areas. The result calculated by the statistical calculation unit 136 is based on the area of the corresponding area-the average period moving time M ₁ of the period, the average period moving time M _{2 of the} key period, the number of necessary machine presses N ₂ and the statistics (the total number of courses) Are remembered in the column.

In addition, when the point w was originally acquired in the area 3, and was deodorized in the area 4 in the last processing, as shown in Fig. 17B, the area is indicated in the immediately deodorized field of the point w corresponding to "4". Described. Accordingly, area 3 or another area cannot select the point w as the next candidate.

According to the area simulator apparatus 100 according to the present embodiment, since the vending machines are sequentially obtained from areas where the statistics such as the total number of courses are minimum, the statistics in all areas can be equalized. In each area, the candidate vending machine is selected so that the distance of the vending period is shortened, so that the travel time in each area can be reduced, and the travel time in all areas can be suppressed low. Thereby, the work efficiency in a business area can be improved.

18 to 23 show screens for setting parameters and initial settings. 18 shows a selection screen of the division method. Here, "Tokyo 2" is selected as the base of the division target. In addition, options of the division method include "seed manual setting" and "seed automatic setting". Here, "seed manual setting" is selected.

19 shows a setting screen for basic conditions for division. In this business zone, the daily work time of each worker, the working time for each vending machine, the base-the moving speed of the vending period, the moving speed of the vending machine-the vending period, the distance magnification, and the vending machine acquisition limit distance are set. Here, the daily working time of each worker is "7 hours 30 minutes", the working time is "20 minutes" for each vending machine, the movement speed between the base and the vending machine is "50Km / h", and the movement speed between the vending machine and the vending machine is "50Km". / h ", the distance magnification is" 1 ", and the vending machine acquisition limit distance is set to" 10 km. " These parameters can be used when calculating the number of courses in each area described with reference to FIG.

At that time, for example, if the distance magnification is set to "2", the total distance from the base in the processing of steps 160 and 162 of Fig. 16 to each vending machine and the total of the n vending machines closest to each vending machine are By doubling the distance, the average travel time M ₁ and the average travel time M ₂ are calculated. The number of courses in each area is calculated based on the travel time calculated from the movement distance between the base-vending period and the vending machine-vending period, and the working time for each vending machine. However, by setting the distance magnification appropriately, the weight can be multiplied by the weight. have. In the present embodiment, the distance between the base-the vending period and the vending machine-the vending period is used to calculate the number of courses. In practice, however, there are many cases of moving between strongholds, vending machines, and vending machines, passing through winding roads or through complicated roads. Therefore, by setting a predetermined distance magnification as regional characteristics for each business area, the actual moving distance can be reflected in the number of courses.

If the vending machine acquisition limit distance is set to " 10 Km ", in step 146 of Fig. 14, the vending machine at a distance of more than 10 km from any of the vending machines previously acquired in the area is not acquired in the area. Therefore, the shortest distance of the vending period in each area can be 10 Km or less, and a business area can be divided into blocks of many areas. Vending machine acquisition limit distance can be appropriately set according to the size of the business area to be divided.

In the selection screen of the division method shown in FIG. 18, when "seed manual setting" is selected, the seed setting screen is displayed as shown in FIG. As shown in Fig. 20 (a), the user may set the seed from the list of the vending machine or set the seed on the map as shown in Fig. 20 (b).

When the seed is set, the seed set as shown in Fig. 20B is displayed on the map. Here, the point showing the vending machine is indicated by a mark on the map. In the vending machine set as the initial seed, a circle is placed around the screen. The setting screen includes a "vending machine information" display screen and a "statistical information" display screen. When the user moves the point to any of the vending machines on the map, information about the vending machine is displayed on the "Vending Machine Information" display screen.

In the selection screen of the division method shown in Fig. 18, when " seed automatic selection " is selected, an input screen of the number of areas is displayed as shown in Fig. 21. Here, a user inputs the area number (seed number) in the base of division object. Here, the area number is set to be "6".

Next, a weight setting screen is displayed as shown in FIG. For example, if there are 1 to 6 areas, the number of courses in any area can be multiplied by the weight. The weight set here is used when calculating a statistics in each area. For example, the weight "2" is set in the area "4" here. Therefore, in the calculation process of the total number of courses shown in FIG. 16, the statistical calculation unit 136 compares the number of courses in another area with the number of courses in another area. In this way, the number of courses in the area 4 is finally set to about half of the other areas. For example, such a weight setting can be performed when a part-time worker is divided into the person in the area 4.

Subsequently, a combination designation screen is displayed as shown in FIG. Here, among a plurality of vending machines, a combination of vending machines to be divided into the same area can be specified. For example, the user can designate a combination of vending machines in which the overall efficiency is better when the machines are divided into the same area, such as a vending machine in the same building, a vending machine installed in the same site, or a vending machine in the same place as the place where the truck is to be placed. For example, point c and point d are specified in combination here. In this case, when one of the points c and the point d is selected as a candidate in a certain area, the candidate selection processor 116 selects the other of the points c and the point d as a candidate of the area. The statistical calculation unit 136 calculates a statistical value in consideration of all the combination designated points. The combined point c and point d are thus obtained in any area at the same time.

In addition, as shown in FIG. 37, the vending machine information storage unit T3 can store information on the combination of the vending machines set in advance in addition to the data structure shown in FIG. Here, for example, vending machines of codes "b", "c", and "d" are installed in the same building, and are named "Building 1", "Building 2", and "Building 3". Since these are installed in the same building, the positions on the plane are almost the same and are "(Ⅹ ₂ , Y ₂ )". In addition, the height of the vending machine of the vending machine code "b" is "two layers", the height of the vending machine of the vending machine code "c" is "five layers", and the height of the vending machine of the vending machine code "d" is "eighth floor". When the points of the combination designated vending machines are selected as candidates, the statistical calculation unit 136 calculates the statistics in consideration of the total time of the working time in each vending machine and the movement time in the height direction between the designated points.

For example, the vending machines of the vending machine codes "e" and "f" are both provided in the training station A, and the names are "softener A1" and "softener A2". These are because they are juxtaposed, position on the plane is substantially the same, all of which are "(Ⅹ _3, Y _3)." In addition, the heights of the vending machines of the vending machine codes "e" and "f" are also "ground". When the points of the combination designated vending machines are selected as candidates, the statistical calculation unit 136 does not have to consider the travel time between the vending machines, but calculates the statistics in consideration of the total time of working time in each vending machine.

When the area division processing is performed as described above, the result is stored in the area division information storage unit T6. The user can appropriately read the state of the area division from the area division information storage unit T6, and can cause the display processing unit 108 to display it on the screen. The adjustment accepting unit 140 has a limitation and can accept an instruction of correction from the user. The restriction on the instruction of the correction from the user can be considered in various forms, but the adjustment reception unit 140 can accept the correction only when, for example, the difference in the statistics of each area due to the correction is within a predetermined range.

FIG. 24 is a flowchart showing the procedure of the process in the case where the adjustment accepting unit 140 receives the process by changing from the user to another. If the user receives an instruction to change the vending machine to another (S270), the adjustment accepting unit 140 determines whether or not there is a right to change to another (S272). Here, the determination of whether or not the user has the authority to change to another can be performed by, for example, authentication of whether the user has the authority. In addition, when the process is changed to another number of times in advance with respect to the area dividing process, applying the process of changing the number of times to another does not have the meaning of performing automatic area dividing. You can also judge perception. In step 272, when it is determined that there is a right to change to another one (Yes in S272), the statistical calculation unit 136 makes a statistical value in each area when changing to another one according to the user's instruction. It is calculated (S274). Subsequently, the adjustment accepting unit 140 determines whether the difference in the statistics in each area in the case of changing to another is within the allowable range (S276). If the difference in the statistics is within the allowable range (Yes in S276), the adjustment accepting unit 140 stores the area dividing result reflecting the instruction from the user to another as the new area dividing result in the area dividing information storage unit T6 ( S278). On the other hand, if it is determined in step 272 that there is no authority (No in S272) or if it is not within the allowable range in Step 276 (No in S276), the adjustment acceptor 140 accepts an instruction to change from the user to another. If it cannot be said, it can not notify that it cannot change to another (S280).

As described above, according to the area dividing process in the present embodiment, since the vending machines are sequentially received in each area so as to shorten the distance between the vending machines, finally the vending machines having shorter distances between the areas are classified into each area. do. Therefore, one business area can be divided into area in block units so as to reduce the movement distance and the like of the keyboard period in each area. Thus, according to the area division process in a present Example, a business area can be divided so that the efficiency of the circulation operation of the vending machine in each area may become high. In addition, since the vending machines are accepted in each area so that the statistics of a plurality of vending machines included in each area are equalized, the worker can have a sense of fairness. In addition, since these results are mapped with the map information, the person in charge can objectively recognize the sense of fairness.

(2nd Example)

In the present embodiment, the seed setting processing in step 4 shown in FIG. 1 is different from the first embodiment. Here, first, a number of seeds larger than the number of seeds actually required is selected, and the seeds satisfying a predetermined condition in the seeds are finally selected as seeds.

25 is a flowchart showing a procedure of seed setting processing in the present embodiment. The area number setting accepting unit 128 accepts setting of the number of seed candidates and selection conditions (S200). Here, the selection condition is what condition to select how many seeds finally from the number of seed candidates.

The seed selector 130 sets the number of seed candidates set as the number of seed candidates in the same order as shown in FIG. 10 (S202). Subsequently, the seed selector 130 performs group division for assigning the vending machine in the business area to any of the seed candidates set in step 202 (S204).

As a group division, the vending machine in a business area can be assigned to the seed candidate located in the nearest position among the seed candidates set in step 200, respectively. As another example of group division, the division processing unit 115 can cause the area division to be preliminarily performed in the same order as shown in Figs. 13 and 14 starting from the seed candidate set in step 200.

Thereafter, the seed selector 130 considers the information of the vending machine divided into the respective seed candidates as a result of group division, and selects several seed candidates as seeds based on the selection condition (S206).

By the above processing, the seed for actually performing area division is set, and area division is performed in the same order as shown in FIGS. 13 and 14 (S208).

Fig. 26 is a diagram showing a setting screen for the number of seed candidates and selection conditions in the present embodiment. Here, "6" is input as a seed candidate. In addition, as the selection condition, the condition "how many are selected as seed candidates from the group with many vending machines from the division result" and "how many are selected as seed candidates from the group with few vending machines from the division result" The condition is described. Here, " 3 " is inputted on the condition of "how many are selected as seed candidates in the group with few vending machines from the division result".

When input in this way, six vending machines are selected as seed candidates first, and another vending machine belongs to any of these six vending machines, and group division is performed. Subsequently, the number of vending machines in each group is detected. Among the six groups, three groups are selected from the order in which the number of vending machines is small, and the seed candidates in the group are selected as the final seeds.

According to the area dividing process in the present embodiment, the area dividing is performed starting from the seeds, respectively, so that the number of courses in the plurality of areas is equalized. Therefore, when seed is provided in the street area where the vending machine is dense, the seed will reduce the moving distance of the neighborhood vending machine. Therefore, the area containing the seed may include many vending machines even in the same course number as in other areas. If the number of vending machines in a large number of areas is extremely different, there is a fear that there will be an unfair feeling among workers even if the number of courses is set equal.

In addition, if a seed vending machine is provided at an extremely remote position from another vending machine as a seed, the moving distance from the seed to the vending machine of the neighborhood becomes long. Therefore, in the area including the seed, even if the area is divided so as to have the same course number as other areas in the calculation process of the number of courses during the area dividing process, there is a possibility that the result of area dividing may be inefficient.

According to the area dividing process in the present embodiment, the seed is set in a region where the vending machine is dense or the seed is set at an extremely far position from another vending machine. Thus, the number of courses in a large number of areas can be avoided. At the same time, the area can be divided so that the number of vending machines included in each area is close. This can reduce the inequalities of the workers in charge of each area.

(Third Embodiment)

In the present embodiment, the seed number is also set automatically, which is different from the first and second embodiments.

FIG. 27 is a block diagram showing the configuration of the area simulator apparatus 100 according to the present embodiment. In the present embodiment, the area simulator apparatus 100 differs from the area simulator apparatus 100 in the first embodiment in that the divided state determination unit 120 is provided. In FIG. 27, the same code | symbol is attached | subjected to the same component as shown in FIG. 3, and description is abbreviate | omitted suitably.

After the division processing is performed by the division processing unit 115, the division state determination unit 120 compares the statistics in each divided area to determine whether division is properly performed. When the division state determination unit 120 determines that division is not performed properly, the parameter and initial setting are again performed, and the redivision process is performed.

Fig. 28 is a block diagram showing details of the initial setting unit 114 in the present embodiment. In the first embodiment, the initial setting unit 114 has a course number setting accepting unit 142 and an area number calculating unit 144 in addition to the configuration described with reference to FIG. 5. The seed setting method accepting unit 124 accepts selection of seed manual setting, seed automatic setting, or course number setting as a seed setting method. When the seed setting method accepting unit 124 receives seed manual setting or seed automatic setting, the same processing as in the first embodiment or the second embodiment is performed. When the seed setting method accepting unit 124 receives the selection of the course number setting, the course number setting accepting unit 142 accepts the setting of the course number from the user. The area number calculating unit 144 calculates the number of areas based on the number of courses received by the course number setting accepting unit 142.

Fig. 29 is a block diagram showing details of the logic storage unit T7 in the present embodiment. In addition to the configuration shown in FIG. 8 in the first embodiment, the logic storage unit T7 includes a logic storage unit T7d for calculating the area number. The logic storage unit T7d stores logic required for calculating the area number in the area number calculating unit 144.

FIG. 30 is a flowchart showing logic used by the area number calculation unit 144 to calculate the area number for dividing the business area, stored in the area number calculation logic storage unit T7d.

The course number setting accepting unit 142 accepts an input of the number of courses in each area from the user (S220). Here, since the number of courses is the amount of work that each worker can perform in one day, "1" is set as an initial value of the number of courses in each area. However, for example, in case of a busy case, the number of courses may be 1 or more, or the number of courses may be 1 or less in consideration of working hours other than the tour work. Subsequently, the area number calculation unit 144 calculates the required number of areas in the business area (S222).

FIG. 31 is a flowchart showing logic used by the area number calculation unit 144 to calculate the required area number in this business area, stored in the area number calculation logic storage unit T7d. This process is performed in the same order as the calculation of the total number of courses in each area described with reference to FIG. The area number calculating unit 144 appropriately refers to the base information data stored in the base information storage unit T2, the vending machine information data stored in the vending machine information storage unit T3, and the parameters stored in the parameter storage unit T4 in the following order. Calculate the total number of courses.

First, the area number calculation unit 144 calculates an average moving time M ₃ from the base to the vending machine in the business area (S250). First, the total distance from the base to the respective vending machines is calculated, and the total travel time is obtained by dividing the total distance by the base-vending period moving speed set by the parameter setting unit 110. Next, M ₃ is obtained by dividing this total travel time by the number of machines.

Subsequently, the area number calculator 144 calculates an average moving time M ₄ between the vending machines (S252). First, the total distance from each vending machine to the nearest n vending machines is calculated, and the total travel time is obtained by dividing the total distance by the vending period moving speed set by the parameter setting unit 110. Next, by dividing this total moving time by n, the average moving time m _{1 to} m _n from each vending machine to another vending machine is obtained. Subsequently, these were combined and the average travel time ~m m _{1 n,} and calculates the M ₄ by dividing the entire vending machine number.

Subsequently, in this business area, the area number calculating unit 144 calculates the number of vending machines N ₃ that can work per day (S254). Total work time per day

Tz = M ₃ × 2 + M ₄ (N ₃ -1) + TXN ₃

(T is the average working time per vending machine)

Since we transform this expression

N ₃ = (Tz-M ₃ × 2 + M ₄ ) / (M ₄ + T)

Calculate

On the other hand, the area number calculating unit 144 calculates the number of vending machines N ₄ which require processing per day (S256). First, the number of times of loading W for each month is calculated by calculating and adding the number of times of loading for each vending machine every month. Next, the number of working days in January of each worker is 4 weeks x 5 days = 20, and N ₄ = W / 20 is obtained.

Thereafter, the area calculator 144 calculates the required number of courses per day = N ₄ / N ₃ by dividing the number of vending machines N ₄ that need to be processed per day by the number of vending machines N ₃ that can work per day (S258). . The area number calculation unit 144 calculates the required number of areas in this business area by dividing the required course number calculated in this manner by the number of courses input in step 220 of FIG. 30 (S260).

Returning to FIG. 30, the seed selector 130 sets the seed twice the number of the required required areas in the same order as shown in FIG. 10 (S224).

Subsequently, the seed selector 130 performs group division in the same order as described in the second embodiment (S226). Thereafter, the seed selector 130 selects seeds having the necessary number of areas sequentially from the seed having few vending machines in consideration of the number of vending machines attached to each seed as a result of group division. The seed selected here is set as the final seed (S228).

By the above processing, the seed for actually dividing the area is set, and the area dividing is performed in the same order as shown in Figs. 13 and 14 (S230).

Subsequently, the divided state determination unit 120 calculates the number of courses in the area actually divided under this condition, and evaluates the divided state (S232). As a result, if the calculated number of courses is within the allowable range (Yes in S234), this processing ends and the result is displayed. If it is not within the allowance (No in S234), the flow returns to step 222, and a new area number is calculated.

32 to 34 show screens for setting parameters and initial settings in the present embodiment. 32 shows a selection screen of the division method. In this embodiment, in addition to the contents described with reference to FIG. 18 for the first embodiment, "course number setting" is included as an option of the division method. Here, "course setting" is selected as the division method.

Fig. 33 shows a setting screen for basic conditions for division. In this embodiment, in addition to the contents described with reference to FIG. 19 with respect to the first embodiment, the main operating days are included as items. Here, "5" days are set as the main operation days.

In the selection screen of the division method shown in FIG. 32, when " course number setting " is selected, an input screen of course number is displayed as shown in FIG. Here, the user inputs the number of courses in each area. Here, "1" is input as the number of courses. Subsequently, the user enters a tolerance range. Here, it is set to + 10% and -10%. Therefore, area division is performed so that the number of courses in each area may be 0.9 to 1.1.

According to the area division processing in the present embodiment, the business area to be divided can be divided into a plurality of areas only by setting the number of courses in each area. The business area is automatically divided by the area simulator apparatus 100 so that the statistics of a plurality of vending machines included in each area are equalized, so that the area can be objectively divided and the worker can have a sense of fairness. Further, in each area, the vending machines are sequentially accepted so as to shorten the distance of the vending period, so that vending machines having a short distance between the areas are finally classified into each area. Therefore, one business area can be divided into block units, and the moving distance of the vending period in each area can be reduced, thereby improving the circulation work efficiency of the vending machine.

(Example 4)

In the present embodiment, when the statistical calculation unit 136 calculates the number of courses in each area, the number of courses is calculated in consideration of the actual work time for each vending machine stored in the vending machine information storage unit T3. Different from the first to third embodiments. In the first to third embodiments, for example, as described in step 164 of FIG. 16 in the first embodiment, the work for each vending machine input as the basic condition of FIG. 19 is used to calculate the number of courses in each area. The average working time of the time was described as being used. However, for example, in recent vending machines, the number of stocks is confirmed from a remote place or there is no need for cash, and the working time in the actual vending machine depends on the characteristics of the vending machine. In the present embodiment, the statistical calculation unit 136 calculates the statistics by reflecting the working time set for each vending machine by referring to the type or characteristic of the vending machine stored in the vending machine information storage unit T3, and thus more precisely to the actual workload. You can calculate the number of courses. Thus, by storing the characteristics for each vending machine in the vending machine information storage unit T3 and using the information, the area can be more strictly divided, and the effort of the worker in each area can be equalized.

The processing of the statistical calculation unit 136 in the present embodiment will be described with reference to FIG. The statistical calculation unit 136 calculates an average moving time M ₁ from the base to the vending machine and the candidate vending machine in advance in the area as in the first embodiment (S160). Subsequently, the statistical calculation unit 136 calculates the average moving time M ₂ between the vending machines as in the first embodiment (S162).

Subsequently, the statistical calculation unit 136 calculates the number of vending machines N ₁ that can work per day (S164). The statistical calculation unit 136 first refers to the vending machine information storage unit T3 and calculates the total time T _o of the working time in the vending machine and the candidate vending machine previously acquired in the area. In this case, 1 day total work time

Tz = 2 × M ₁ + M ₂ × (N ₁ -1) + T _o

, So you can modify this expression

N ₁ = {(Tz-2M ₁ -T _o ) / M ₂ } +1

To calculate.

On the other hand, the statistical calculation unit 136 calculates the number of vending machines N ₂ that need processing per day as in the first embodiment (S166). The statistical calculation unit 136 then calculates the number of courses in each area = N ₂ / N ₁ by dividing the number of vending machines N ₂ that need to be processed per day by the number of vending machines N ₁ that can work per day (S168). ).

36 is a diagram showing another example of a part of the data structure of the vending machine information storage unit T3.

Here, the vending machine information data includes the vending machine classification, the parking situation, and the like for each vending machine. Here, the type of vending machine can be determined according to the amount of work in the vending machine. For example, no cash is required and the communication function is attached, so it is not necessary to collect the sales amount, and the vending machine that can know the amount of replenishment, etc. is not necessary. Vending machines can be classified as "C" which requires "B", recovery of sales, replenishment change and confirmation of replenishment. In addition, the parking situation can be determined according to the parking availability of the delivery vehicle. For example, if you can park next to the vending machine, "1", if the distance between the vending machine and the parking position is within 20m, for example, "2", and the distance between the vending machine and the parking position is less than 20m. Can be set to "3". The statistical calculation unit 136 may calculate the working time in each vending machine based on the classification of each vending machine, the parking situation or the loading amount, not shown. In this case, the statistical calculation part 136 can calculate the number of courses in each area mentioned above using the work time computed in this way.

As described above, the statistical calculation unit 136 calculates the number of courses more strictly since the statistics can be calculated by referring to the vending machine information storage unit T3 for each vending machine, reflecting the actual working time or the situation difference for each vending machine. can do. The labor force of the worker in each area can be equalized. In addition, when calculating the number of vending machines N ₁ that can be worked in one day, the travel time from the base to the vending machines of each area is also taken into consideration, so that each area can be divided so that the distance from the base becomes almost equal. In addition, since the number of courses is calculated in consideration of the distance of the keyboard period in each area, the business area can be divided so that the moving distance in each area is equalized.

(Fifth Embodiment)

FIG. 35 shows an area simulator system 146 including the area simulator apparatus 100 described in the first to fourth embodiments. Processing from the user described in the first to fourth embodiments can be performed by the user terminal 150 via the network 148. In the present embodiment, the user terminal 150 may be anything as long as it can communicate with the area simulator apparatus 100 via the network 148. For example, the user terminal 150 can be a PC, a PDA, a mobile phone, or any other hardware.

In this way, the user has the user terminal 150, and can actually send the area simulator apparatus 100 an instruction necessary for the area division processing while actually circulating in the business area in which the vending machine is installed. Accordingly, by reflecting the actual on-site situation, for example, the combination designation can be inputted to the combination designation acceptor 132 or the process can be inputted to the adjustment acceptor 140.

Further, the area simulator apparatus 100 described in the first to fourth embodiments may have a data registration accepting unit that accepts registration of various data such as base information data and vending machine information data in addition to the configuration described in each embodiment. good.

FIG. 38 is a block diagram showing a configuration in the case where the area simulator apparatus 100 according to the first embodiment has a data registration accepting unit 152. The data registration accepting unit 152 accepts registration of various data from the user, and stores those data in the base information storage unit T2 or the vending machine information storage unit T3. As a result, the user can register various data while actually traveling in the business area where the vending machine is installed with the user terminal 150. Therefore, more accurate and clear information can be stored in the base information storage unit T2 and the vending machine information storage unit T3. Further, even when various types of data are registered in the base information storage unit T2 or the vending machine information storage unit T3 in advance, data can be promptly updated when there is a change in the site situation. By clearly and promptly maintaining various data stored in the base information storage unit T2 and the vending machine information storage unit T3, it is possible to appropriately divide the area of the business area to be targeted.

39 and 40 show screens for registering the vending machine information data. Fig. 39A shows a screen for inputting a vending machine code of a vending machine for registering data. FIG. 39 (b) shows an input screen of vending machine information data corresponding to the vending machine code input in FIG. 39 (a). Here, in FIG. 39A, "b" is input as a vending machine code. If the user has specified a vending machine code, the data registration accepting unit 152 determines whether the vending machine information data of the corresponding vending machine is stored in advance with reference to the vending machine information storage unit T3. When the vending machine information data of the corresponding vending machine is stored in advance, the data registration accepting unit 152 reads the vending machine information data. The vending machine information data read by the data registration accepting unit 152 is displayed on the screen of FIG. 39 (b). On the other hand, when the vending machine information data of the corresponding vending machine is not yet stored or there are items that are not stored, the screen of Fig. 39B is displayed in a blank state. Here, the base code of the vending machine for vending machine code "b" is "1000", the name is "○ building 1" position is a vending machine information data of "Ⅹ = Ⅹ _2", "Y = Y _2" and a height of "second floor" Is displayed. If there is a correction, the user can correct these vending machine information data. In addition, since the working time is blank, the user inputs the working time.

When the input of the screen of Fig. 39 (b) is finished, as shown in Fig. 40 (a), the data registration receiving unit 152 asks which vending machine and vending machine combination of the vending machine code "b" is to be specified. If the user selects "no" here, the registration of the vending machine information data of the vending machine code "b" is complete | finished. On the other hand, if the user selects "Yes", the data registration accepting unit 152 designates the vending machine for which the user specifies the combination. At this time, the data registration accepting unit 152 may input the vending machine code of the vending machine for which the combination designation is made. For example, as shown in Fig. 40 (b), the combination registration designation is performed based on the position information of the vending machine code "b". A list of vending machines that are likely to be done may be presented to the user. In this case, the user can select and designate a vending machine to be combined with the vending machine of the vending machine code "b" among vending machines included in the list.

In the present embodiment, since the information necessary for the area simulator 100 can be transmitted and received from the user terminal 150 via the network 148, the area simulator apparatus is configured to actually send information necessary for area division while circulating in the business area. 100 can be transmitted. Therefore, for example, various data can be updated clearly and quickly, and the precision of area division optimization can be improved.

In the above, this invention was demonstrated based on the Example. The embodiments are illustrative, and it is understood by those skilled in the art that various modifications can be made to the combination of each component thereof and each treatment process and that such modifications are also within the scope of the present invention. Hereinafter, such a modification is demonstrated.

In the first embodiment, the area division processing described with reference to Figs. 13 to 15 can be performed using various procedures. For example, in the candidate selection process of step 104 in Fig. 13, the vending machine located at the shortest position from the center of the vending machine that has been acquired in each area is detected as a candidate (Figs. 14, S130 and S132), but in each area. The vending machine at the shortest position from the vending machine set as the seed may be detected as a candidate. Also in this case, the determination of whether or not the detected vending machine is determined as a candidate can be made in the same process as that in FIG.

In the third embodiment, the seed is set automatically when the number of courses is input. However, the initial setting unit 114 receives the input of the number of courses from the user, referring to the logic storage unit T7. It is also possible to calculate the number of areas by the process shown in FIG. 31 and to present the required number of areas to the user. In this case, the user can select whether to set the seed manually or automatically, and make fine adjustments such as weight setting as necessary.

In the above embodiment, the total number of courses in each area was described as an example of statistics, but in each area, for example, the number of vending machines included in each area, the average reloading time per vending machine, and the average month per vending machine. Areas can be divided so that statistics other than the number of courses are equal, such as the number of reloads, the distance average from the base per vending machine, the distance average between vending machines, the number of vending machines per course, the total sales, and the average sales per vending machine. For example, when the sales average per vending machine is used as a statistic, the sales in each area can be equalized. As described in the second and third embodiments, such a process may be combined with a process for group division by setting more seed candidates than actually required seed numbers. In this case, since the seed which equalizes the number of vending machines contained in each area can be set suitably, the sales in each area can also be equalized, making the number of courses in each area finally equalize to some extent. As a result, the employee's sense of fairness can be increased.

In addition, in the above embodiment, an example of dividing the business area into a plurality of areas has been described, but the same method may be used when setting a plurality of business areas. In this case, a base in each business zone can also be set in the same manner as the seed is set in the above embodiment.

According to the present invention, the area in which a plurality of vending machines are installed can be objectively divided into a plurality of responsible areas so that a worker who performs a tour of the vending machine has a sense of fairness. In addition, according to the present invention, an area in which a plurality of vending machines are installed can be divided into a plurality of responsible areas so that the workload of the worker who performs the circulation work of the vending machine is equalized. According to the present invention, it is possible to divide an area in which a plurality of vending machines are installed into an area in charge of a worker who objectively performs a vending operation of the vending machine while the divided state can visually grasp. According to the present invention, an area in which a plurality of vending machines are installed can be divided into a plurality of areas in charge so as to make the circulation work of the worker who performs the circulation work of the vending machine more efficient. According to the present invention, an area in which a plurality of vending machines are installed can be divided into a plurality of areas in charge so as to reduce the total work load of all the workers who are performing the circulation work of the vending machine.

Claims (19)

An area dividing system that divides an area in which a number of vending machines are installed into an area in charge of a worker who tours the vending machine. An initial setting unit for setting a plurality of areas in the area including at least one vending machine according to the number of persons in charge; A calculation unit for calculating a statistic determined by the characteristics of the vending machine included in each area; After selecting a specific area in consideration of the statistic, the process of expanding the area by adding a vending machine to the specific area is repeated, ending the processing when a predetermined condition is satisfied, and the obtained area is designated by the plurality of persons in charge. An area dividing system, comprising: a processing unit for determining as an area in charge of the; The method of claim 1. A candidate selection unit for selecting candidates for the vending machine to be added for each area; The calculating unit calculates the statistics when a candidate of the vending machine is added to each area, And the processing unit selects the specific area in consideration of the statistics when the candidate of the vending machine is added. The method of claim 2, And the processing unit selects the specific area so that a difference in the statistic of each area becomes small when a vending machine is added to a certain area. The method of claim 2 or 3, A location information storage section for storing location information of the vending machine, The candidate selecting unit selects the candidate with reference to the position information of the vending machine. The method of claim 4, wherein And the candidate selecting unit sequentially selects each person in consideration of the distance from the representative point determined based on the position information of the vending machine previously divided. The method of claim 5, And the candidate selecting unit determines the representative point based on the position information of all the vending machines previously divided to each person in charge. The method according to claim 5 or 6, And the candidate selection unit sets a center point of a position of a vending machine previously divided to each person in charge as the representative point. The method according to any one of claims 1 to 7, And said statistic is the amount of work of each person in charge when traveling through a vending machine included in each area in charge. The method of claim 8, And the calculating unit calculates the statistics in consideration of the travel time between the vending machines. The method according to any one of claims 1 to 9, The information on the characteristics of each vending machine includes the location information of each said vending machine, and is provided with the characteristic information storage part which stores the location information of this vending machine, And the calculating unit calculates a moving time between the vending machines based on the position information between the vending machines. The method according to any one of claims 8 to 10, The area includes a stronghold, And the calculating unit calculates the statistics in consideration of the travel time between the base and the vending machines. The method according to any one of claims 8 to 11, And said calculating section calculates said statistics in consideration of the working time in each said vending machine. The method according to any one of claims 8 to 12, And said calculating unit calculates said statistic based on each type of said vending machine. The method according to any one of claims 1 to 13, And the processing unit adds the vending machine to each area so that the distance between the vending machines included in each area in charge is within a predetermined limit distance. The method according to any one of claims 1 to 14, A weight setting unit that applies weight to the statistics for each area, And the calculating unit calculates the statistic in consideration of the weight. The method according to any one of claims 1 to 15, Among the plurality of vending machines, has a combination designation accepting section for accepting a combination designation of a vending machine to be included in the same area of charge, And the initial setting unit or the processing unit includes a vending machine designated as a combination in the same area. The method according to any one of claims 1 to 16, A map information storage unit for storing map information of the area; And a display processing unit for displaying a vending machine included in each area, together with the map information so as to know the difference for each area in charge. The method according to any one of claims 1 to 17, And a characteristic information receiver for accepting input of information on the characteristics of the vending machine through a network. In the data structure used when dividing an area in which a plurality of vending machines are installed into a worker's area in which the vending machine is toured, A first data section for discriminating and accepting identification information of the vending machine assigned to each of the charge areas in advance and identification information of the vending machine to be assigned to the respective charge areas next; And a second data portion for receiving statistics calculated on the basis of information on the characteristics of the vending machine preliminarily attributed to each responsible area and the vending machine to be attributable next.