JP3827863B2 - Resource allocation status management system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention supports the planning (decision making) of an optimal resource allocation plan to a resource supplier that unexpectedly occurs, changes, or disappears, such as a disaster area when a large-scale disaster occurs. In addition, the present invention relates to a resource allocation status management system for efficiently and accurately monitoring the allocation status.
[0002]
[Prior art]
In the event of a city earthquake, in addition to the damage caused by the earthquake itself, damage from a wide-area fire or tsunami as a secondary disaster is expected. Therefore, in the fields of disaster prevention, first aid, etc., a number of related administrative agencies are connected by wired and wireless communication networks to ensure communication means, and when a disaster occurs, fire engines, ambulance vehicles, and other human / materials A system has been established to supply natural resources (hereinafter simply referred to as “resources”) to disaster areas (suppliers). When a disaster actually occurs, after grasping the demand (disaster situation) in the disaster area, the relevant administrative agencies communicate with each other to supply resources while allocating or reallocating resources.
[0003]
[Problems to be solved by the invention]
Whether or not damage can be minimized in the event of a disaster depends on how quickly and accurately resources can be allocated, reallocated and supplied.
However, in a situation where the type and number of resources, or the number of demands of a supplier constantly changes, it is difficult to quickly grasp the overall picture of what resources and what resources should be supplied to which suppliers. In addition, it is impossible to grasp which resources can be supplied, which resources have already been supplied, and whether the resources at the supply destination are excessive or insufficient.
[0004]
In addition, when resources are distributed in multiple regions, such as local governments, and each resource allocation decision maker is located in other local governments that are physically separated, these resources are coordinated and distributed consistently. It is very difficult to make a decision quickly. This becomes prominent when resources are managed by different organizations or unique information processing systems.
[0005]
Furthermore, in the event of a small-scale disaster, there may be cases where it can be dealt with only by the resources in the area, but when a large-scale disaster occurs, not only will there be a shortage of absolute resources, but there will also be a distribution of resources from other areas. It will cause trouble. This is because, for example, firefighting systems are supplied with resources triggered by reports from disaster areas, but when a large-scale disaster occurs, the site becomes a disaster-affected area, so reports are usually paralyzed. is there. For this reason, it is impossible to grasp the whole picture of the disaster based on the report, so for example, the resource is obtained by grasping the whole picture based on information reported by the advance team (helicopter, fire engine, ambulance, etc.). An allocation plan must be made.
[0006]
Such a problem is not only caused by a disaster, but also by actually allocating and reallocating multiple resources that are required to be supplied promptly and appropriately to suppliers that occur, change, or disappear unexpectedly. This commonly occurs in applications where the resource allocation status must be managed.
[0007]
SUMMARY OF THE INVENTION An object of the present invention is to provide a resource allocation status management system that supports quick and accurate determination of allocation and redistribution of resources to supply destinations and related technology.
[0008]
[Means for Solving the Problems]
The resource allocation status management system provided by the present invention is a system that manages the allocation status of a plurality of resources that are required to be supplied promptly and appropriately to a supplier that unexpectedly occurs, changes, or disappears.
(1-1) Database management means for acquiring demand state information and supply state information of resources at the supply destination to be changed at any time, and storing these in an updatable manner;
(1-2) A distribution plan matrix in which one of the supply destination and the resource in the database management unit is row and the other is a column is generated, and the demand state information and supply state information are stored in the corresponding cell of the distribution plan matrix. Matrix generating means for automatically assigning to
(1-3) The allocation content of the allocation plan matrix is displayed on a predetermined display device, and the allocation content being displayed is dynamically changed each time the content of at least one of the demand status information and the supply status information changes. Control means for updating.
[0009]
In this resource allocation status management system, each resource information is represented by a unique symbol, and each unique symbol is linked to demand status information and supply status information and mapped onto a corresponding cell of the allocation plan matrix, thereby displaying It is possible to update information by moving a unique symbol on the distribution plan matrix. Further, the display form of the corresponding cell in the distribution plan matrix is changed according to the demand state information and the supply state information.
[0010]
The resource allocation status management system of the present invention may be configured by connecting a plurality of information processing systems via a communication network. In this case, a plurality of information processing systems cooperate to constitute the database management means, the matrix generation means, and the control means. Alternatively, some of the plurality of information processing systems each include the database management unit and the matrix generation unit, and when the storage information of any database management unit is updated, all the other database management units and the resources The display contents of the distribution plan matrix may be updated synchronously.
[0011]
The present invention also provides a computer processing method for efficiently managing a distribution status of a plurality of the resources.
In this method, demand state information and resource supply state information at the supply destination are acquired and stored in a predetermined memory in an updatable manner, and one of the supply destination and the resource is assigned as a row and the other as a column. A plan matrix is generated, demand state information and supply state information are allocated to the corresponding cells of the distribution plan matrix, and the allocation contents of the distribution plan matrix are displayed on a predetermined display device. Each time at least one of the contents changes, a process for dynamically updating and controlling the assigned contents being displayed is included.
[0012]
The present invention also provides a computer-readable recording medium in which a program for causing a computer device to execute the following processing is recorded.
(2-1) Information indicating the demand state in a supply destination that unexpectedly occurs, changes, or disappears and the actual supply state of a resource that is required to be quickly supplied to the supply destination can be acquired and updated to a predetermined memory. Process to store,
(2) A process of generating a distribution plan matrix having one of the supply destination and the resource as a row and the other as a column, and assigning demand state information and supply state information to a corresponding cell of the distribution plan matrix;
(3) a process for displaying the distribution plan matrix and the content of the allocation on a predetermined display device;
(4) A process of dynamically updating and controlling the distribution plan matrix being displayed and its assigned contents each time the contents of at least one of the demand state information and the supply state information change.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment when the present invention is applied to a resource allocation status management system that manages a resource allocation status at the time of occurrence of a disaster will be specifically described.
As shown in FIG. 1, the resource allocation status management system 1 according to this embodiment is configured by connecting a plurality of information processing systems 2 installed in a plurality of prefectures, cities, and the like so that they can communicate with each other using a wide area network L. Is done. These information processing systems 2 may be realized by installing a program in the recording medium of the present invention in a mobile computer terminal or a desktop computer terminal having a communication function, and a plurality of computers in which the program is installed. A form in which terminals are connected by a local network or the like to perform distributed processing may be employed. Here, for convenience, an example in which a single computer terminal is used is shown.
[0014]
As shown in FIG. 2, each information processing system 2 according to this embodiment includes a data input device 21 including a pointing device such as a mouse and a numerical input device such as a keyboard, a display device 22 including a liquid crystal panel, and a magnetic device. It has a storage device 23 composed of a disk, a magneto-optical disk or the like, and a data input / output device 21, a display device 22, a storage device 23, and a central processing unit 25 connected to an external system or the like through an input / output interface 24.
[0015]
The central processing unit 25 includes a database management block 10, a matrix management block 20, and a control block 30 that are formed based on an operating system (OS) recorded in the recording device 23 and the above program.
[0016]
The database management block 10 manages a database (DB) 231 built in the storage device 23 based on information relating to a supply destination and resources input through the data input device 21 or an external system. Resource management unit 11 that manages the resource and its attribute information, each supply destination that is an object and a supply destination management unit 12 that manages the attribute information, an update processing unit 13 that updates the attribute information of the resource and the supply source, and resource Alternatively, the attribute search unit 14 that searches for specific attribute information of the supply destination, the supply cost of the resource (time, distance, money, etc.), the demand state based on the time-series fluctuation factors of the resource and the attribute information of the supply destination It has the function of the calculation unit 15 to calculate information aggregation / aggregation, supply status information aggregation / aggregation, resource excess / deficiency, importance of supplier, severity at supplier, etc. To have.
[0017]
“Demand status information” is information indicating how much demand there is at the supplier. “Supply status information” is the number of supply plans that indicate how much resources are allocated in the plan, and which resources are actually allocated. The number of supplies indicating how much is supplied. “Importance” is an index that represents the duration of the number of past demands at the supplier, the current demand scale, etc., and “Severity” is an indicator that indicates how difficult the supplier is due to a delay in the supply of resources. It is. Importance and severity are derived based on time-series trends such as the number of past demand and supply performance at the supplier, and which resources are given priority when the type or absolute number of resources is small. This information is used when determining whether or not to distribute the information.
[0018]
The attribute information managed by the resource management unit 11 includes an identification code (fixed) uniquely determined on the system, a resource name (fixed), a resource type (fixed), an allocated supply destination name (variable), and a management source (resource Owner: fixed), current physical location (variable), scheduled supply date (variable), resource status (available / not available / during: variable), physical quality and quantity characteristics (variable) Other information. “Fixed” is information used in a fixed manner, and “variable” is information that is changed as needed. “Resource type” is information for distinguishing fire engines, ambulances, helicopters, etc., for example, and “assigned supplier name” is information indicating to which supplier each resource is assigned, which will be described later. It changes dynamically as the resource moves on the resource allocation planning matrix. “Characteristic” represents, for example, the remaining cruising distance (time) of the helicopter.
[0019]
The attribute information managed by the supply destination management unit 12 includes an identification code uniquely determined on the system (fixed), a supply destination name (fixed), a supply destination type (fixed), and a current physical position (variable). , Importance (important (emergency) / normal / impossible: variable), characteristics (variable) and other information about physical quality and quantity. “Supplier type” is information for distinguishing, for example, fire, flood, etc., and “Supplier name” is information specified by the type. “Characteristic” represents, for example, the size of a fire.
[0020]
In the database management block 10, by checking the “assigned supply destination name” of each resource, the resources with the same supply destination and resources for which no supply destination is set are grouped and managed. Further, by examining the “resource type” of each resource, resources having the same resource type are grouped and managed. For example, in the case of a supply destination, the number is n, and in the case of a resource, when the number of groups created for resources with the same resource type is m, the relationship between these groups is represented by n rows and m columns. It can be managed in matrix format.
[0021]
The matrix management block 20 generates a resource allocation plan matrix based on the matrix of n rows and m columns, and supplies demand state information and supply state information at the supply destination to other cells of the resource allocation plan matrix. It has a function of a mapping processing unit 22 that automatically assigns and maps on the corresponding cell. Each row and column is automatically deleted from the DB 231 when the supply destination or the resource type disappears, that is, when it becomes unnecessary to manage.
[0022]
When generating the resource allocation plan matrix, the matrix generation unit 21 extracts only the fire-related information currently required by specifying the supply destination whose supply destination attribute information is “fire”, for example. The resources are to be arranged in order from the priority to be supplied according to the importance, severity, or current demand status information and supply status information obtained by the parameter calculation unit 15.
[0023]
A plurality of resource allocation planning matrices can be generated simultaneously. For example, generate a hierarchical resource allocation plan matrix for each country, prefecture, city, town, or generate a side-by-side resource allocation plan matrix such as other prefectures and cities, and link them together. can do. In this case, in each allocation plan matrix, a shared cell for sharing the contents with other allocation plan matrices and a common cell that represents the total result of data in a specific cell in a plurality of resource allocation plan matrices are formed. Is desirable. This will be described later.
[0024]
Further, the contents of the resource attribute information can be viewed directly from the resource allocation plan matrix, and the contents can be updated. The attribute information updated thereby is reflected in the DB 231 through the database management block 10 and is synchronized with all the resource allocation plan matrices.
In this way, all information necessary for resource allocation planning and reallocation planning can be grasped through the resource allocation planning matrix. Either the supply destination or the resource may be in a row or a column. However, in the following description, for convenience, it is assumed that the supply destination is assigned to “row” and the resource (resource type) is assigned to “column”.
[0025]
These resource allocation planning matrices include a matrix ID uniquely determined on the system, a matrix name, a plan manager, the number of supply destinations (number of matrix rows n), the number of resource types (number of matrix columns m), The number of demands, the number of planned supplies, and the number of supplies for each resource type (cell unit) at each supply destination are stored as attribute information. This attribute information can be shared with other terminals or information processing systems via the DB 231 and the control block 30, and is synchronized with the change of data contents when notified from the own system or other terminals. Updated.
[0026]
The control block 30 displays an event processing unit 31 that drives a required event process every time a resource or its supply destination is generated, changed, or disappeared, and a resource allocation plan matrix and its allocation contents on the display device 22 in real time. At the same time, when there is a change in the allocation contents of the resource allocation plan matrix being displayed, the display control section 32 that dynamically updates the corresponding display contents and the contents of changes in the DB 231 are notified to other information processing systems. The function of the communication control unit 33 is provided. Specifically, the event processing includes input / change processing of demand information of resources for each supply destination, change processing of attribute information of supply destinations and resources, icon movement processing described later, and the like.
[0027]
The display control unit 32 displays resources and supply destinations with unique symbols, for example, icons, and displays demand state information and supply state information on the corresponding cells as character data and numerical data. Further, it has functions of a cell control unit 321 and an icon control unit 322 for controlling the display color of individual cells and the display color of icons in the resource allocation plan matrix.
The cell control unit 321 is linked to, for example, a control table having the contents shown in FIGS. 3 and 4 and changes the background color of the corresponding cell to a predetermined color for each supply destination state and resource supply state. The control table of FIG. 3 defines the above-mentioned importance (important / normal / no supply required) as the supply destination state, and the control table of FIG. 4 shows the supply number with respect to the number planned in advance as the supply state. It defines the degree (insufficient / slightly insufficient / appropriate / surplus). Similarly, the icon control unit 322 is linked to, for example, a control table having the contents shown in FIG. 5, and has a predetermined color according to the resource supply status (supplied / in supply / available / unnecessary supply). Change the icon color. In this way, the current resource allocation status can be monitored by color change.
[0028]
Next, the operation of the resource allocation status management system 1 will be described.
When the resource, supply destination, demand state information, and supply state information are input, the database management block 10 calculates the demand number of the resource for each resource type in each supply destination according to the demand of the supply destination, The result is registered in the DB 231. Also, the number of all registered resources is totaled, and the planned supply number of resources for each resource type at each supply destination is automatically registered in the DB 231. Further, the number of resources whose resource status is already supplied is totaled, and the supply number of resources for each resource type at each supply destination is automatically registered in the DB 231. Then, the supply destination and the resource type are grouped and managed in a matrix format of n rows and m columns as shown in FIG.
[0029]
The matrix generation block 20 generates a resource allocation plan matrix having the contents illustrated in FIG. 7 based on the registered contents in the matrix format in the database management block 10. This resource allocation plan matrix is displayed on the display device 22 through the control block 30, and the color of each cell and icon is dynamically updated according to the contents defined in FIGS.
[0030]
In FIG. 7, “suppliable” cells (rows) are cells (rows) for allocating resources that can be supplied. In the resource allocation plan matrix, as shown in the figure, icons and character data representing the state of the resource, for example, the number of demands (“demand X”), the number of planned supplies (“total Y”), and the number of supplies (“Z Z”) Are mapped for each cell, and the icon can be moved between the same resource types by dragging and dropping with a pointing device. As the icon moves, the attribute information of the resource changes, and this is reflected in the DB 231 so that character data such as the number of supply plans on the resource allocation plan matrix is updated as needed. That is, the number of demands is mainly input from the outside (other systems, other matrices, etc.), and the number of supply plans changes with the movement of the icons. Further, the supply number varies depending on the status (for example, icon color) of the resources owned by each cell.
[0031]
The supply and demand information in the resource allocation plan matrix can be aggregated / aggregated as appropriate and displayed.
FIG. 8 shows an example of a totaling method of shared cells (rows) when a certain matrix is hierarchized as an example of the totaling / aggregating function. Here, it is assumed that two matrices A1 and A2 are managed by one matrix B1. In the figure, “shared A1” and [shared A2] cells (rows) are cells (rows) that can be shared by the respective matrices A1, A2 and B1. That is, “shared A1” in matrix A1 and “shared A1” in matrix B1 are linked to each other (the same thing is displayed), and “shared A2” in matrix A2 and “shared A2” in matrix B1 are also linked. Yes.
[0032]
The number of demands, the number of plans (the number of supply plans) and the number of supplies in each cell are calculated as follows. For example, the aggregation / aggregation method for the matrix A1 is as shown in FIG.
The demand number is input and displayed from the outside (another matrix, another system, a mouse / keyboard input device, etc) mainly by electronic means. As the number of plans (the number of supply plans), the number of resources allocated to each cell in plan is counted and displayed. The supply number refers to the resource state in the planned number, and the resources in the supplied state are counted and displayed.
[0033]
In the shared cell (“shared A1”), the number of demands, the number of plans, and the number of supplies of each cell are further aggregated and displayed. The demand number c in “shared A1” is calculated by comparing the total value “a” of the demand numbers for each cell with the total value “b” of the number of plans. This value indicates the number of shortages with respect to the number of demands of the entire matrix.
The value of a is calculated by summing the demand number “4” of “supplier A1a” and the demand number “5” of “supplier A1b” (a = 4 + 5 = 9). The value of b is calculated by summing the planned number “3” of “supplier A1a”, the planned number “2” of “supplier A1b”, and the planned number “2” of “suppliable A1” (b = 3 + 2 + 2 = 7). For a demand number c of “shared A1”, the value of a−b is substituted if a> b (if the demand number is larger than the planned number), and if a ≦ b (the demand number is larger). If not) the value of c = 0 is substituted. In this example, since a> b, c = 2. The planned number is displayed by counting the number of resources allocated to the “suppliable A1” plan. The supply number refers to the attribute of “resource” in the planned number, and the resource whose state (“resource” attribute) has already been supplied is counted and displayed.
[0034]
In the same manner for the matrix A2, the number of demands, the number of plans, and the number of supplies are totalized and displayed in “Shared A2”. Since “shared A1” and “shared A2” are linked to the matrix B1, these cells are simultaneously displayed on the matrix B1, and further, the “shared B1” is added to the “shared B1” by the above-described aggregation / aggregation method. The number of demands, the number of plans, and the number of supplies are compiled and displayed.
[0035]
Next, a specific example of a mechanism for linking these when there are a plurality of resource allocation plan matrices will be described with reference to FIG. FIG. 10 shows the movement of resources in the hierarchical matrix shown in FIG. 8 and the change in display form in that case.
[0036]
Here, when a resource on the matrix A1 is moved from “Supply A1b” to “Share A1” by drag and drop (1), the assigned supplier name, which is one of the attribute information of the resource, is “ “Supplier A1b” is changed to “Shared A1”. Then, this resource is displayed not only on the matrix A1 but also on the “shared A1” on the matrix B1 (2). Further, when this resource is moved to “suppliable B1” on the matrix B1 (3), the allocated supply destination name of the resource is changed to “suppliable B1”. Then, the resource disappears from the “shared A1” on the matrix B1, and at the same time, the resource disappears from the linked matrix A1 (4). Next, on the matrix B1, when the resource is moved in order to allocate the resource from “suppliable B1” to “shared A2” (5), the allocated supply destination name of the resource is changed to “shared A2”. . Since the matrix B1 and the matrix A2 are linked, the resource is simultaneously displayed in the “shared A2” of the matrix B1 and the matrix A2 (6). When this resource is further moved to “suppliable A2” on the matrix A2 (7), the resource allocation destination name is changed to “suppliable A2”, and at the same time the resource disappears from the “shared A2” on the matrix A2. Disappears from the matrix B1.
[0037]
Since the resource allocation plan matrices can be linked in this way, the operator can adjust the resource allocation / redistribution state while visually grasping the status. In addition, it is possible to easily grasp the whole image such as what supply destination should be supplied by each matrix. Furthermore, since the current demand state and supply state can be confirmed with the cell color and icon color, it is possible to see at a glance which resources are currently available, which resources are already supplied, and which resources are insufficient or remaining. It becomes possible to grasp.
Therefore, for example, it is possible to simultaneously grasp the situation in a disaster occurrence area by the information processing system 2 in another area, and instantly indicate the state of resources and the supply state to the supplier in all areas at that time. Therefore, resource allocation planning / redistribution planning becomes extremely easy, and appropriate judgment without contradiction becomes possible.
In the resource allocation status management system of the present embodiment, resources provided from other organizations can be incorporated and allocated / redistributed in cooperation with other systems, which is suitable for situations such as large-scale disasters. Correspondence becomes possible.
[0038]
【Example】
Next, an embodiment of the resource allocation status management system 1 shown in FIG. 1 will be described with reference to FIGS.
FIG. 11 shows a specific example of the resource allocation plan matrix displayed on the display device 22. Here, the resource allocation plan matrix is configured by hierarchizing a plurality of panels, and the panel displayed at the lower level manages the panel displayed at the higher level.
[0039]
For example, the supply destination panel 52 and the resource panel 53 are arranged on the main panel 51 under the window 50, and further, individual panels, supplyable panels, and shared panels are arranged in a matrix on the supply destination panel 52 and the resource panel 53, respectively. The resource allocation plan matrix is configured. Adding, arranging (changing), and deleting a GUI (interface) and these panels as shown in the figure can be realized by using a function of “Java” that is a well-known technique.
[0040]
In the illustrated panel, the supply destination title 52a and the resource type title (A, B) 55 are merely displayed, and no events are accepted. The supplyable panel 52c and the supplyable resource panel (A, B) 57 are added in advance as panels that are fixedly present in the resource allocation plan matrix. As described above, the supply destination sharing panel 52d and the resource sharing panel (A, B) 58 are sharing panels with other related matrices, and have link information with the other matrices. The supply destination individual panels (# 1, # 2) are panels for displaying the supply destination names described in the list managed by the supply destination panel 52 and icons representing them.
[0041]
The resource individual panel (A1, A2, B1, B2) 56 lists resources having the same supply destination information among the resources managed by the resource type panel (A, B) 54, as shown in FIG. The symbol display panel 60 and the demand supply display panel 61 are managed. The symbol display panel 60 has a function of converting all resources registered in the list of the resource individual panel 56 into unique symbols (icons) and drawing the unique symbols on the individual symbol panel 57a.
[0042]
The demand supply display panel 61 refers to the list of the demand information panel 61a having a function of displaying the demand information of the supply destination and the resource individual panels (A1, A2, B1, B2) 56, and displays the distribution plan information and the supply information. The plan information panel 61b and the supply information panel 61c having the function of collecting and displaying are managed.
[0043]
FIG. 13 is a diagram illustrating a configuration example of the supplyable panel 52c. The supplyable panel 52c manages a symbol display panel 70 having a plurality of individual symbol panels 70a and a supplyable information panel 71. The symbol display panel 70 basically performs the same function as the resource individual panel 56 shown in FIG. The supply possibility information panel 71 is different from the demand supply information display panel 61 of the resource individual panel 56 in that there is no demand information or supply information.
[0044]
FIG. 14 is a diagram showing a configuration example of the resource sharing panel (A, B) 58. The individual symbol panel 72a, the symbol panel 72, the demand information panel 73a, the plan information panel 73b, the supply information panel 73c, and the demand supply information. The display panels 73 are basically the same as those of the resource individual panel 56 shown in FIG. The only difference is that the information in the demand information panel 73a displays how much demand is present in the entire matrix calculated from the information in the resource type panel (A, B) 54.
[0045]
FIG. 15 shows how the resource allocation plan matrix configured as described above is linked with the DB 231.
Here, a sequence when the registered content in the DB 231 is updated is shown. Each list in the figure indicates that the resource or the supply destination holds the DB 231 or a reference destination for identifying where the contents of the DB 231 are in the cached memory as a list. Alternatively, an object developed on a memory may be used.
[0046]
In FIG. 15, first, the resources and supply destinations to be managed in the resource allocation plan matrix are added from the DB 231 to the all resources and all supply destination lists. The window 50 searches the list registered in the all resources and all the supply destination lists. If “supply destination” is registered, it is registered in the supply destination management table. If it is “resource”, the type is checked to check the resource type. Register in the type management table. The supply destination management table is used to create a “row” of the resource allocation plan matrix, and the resource type management table is used to create a “column” of the resource allocation plan matrix. The “rows” on each resource type panel 54 are added in the same order as when they were added to the supply destination panel 52 while referring to the supply destination management table and the existing resource type management table.
[0047]
The window 50 distributes all resources and all supply destination lists to the supply destination panel 52 and each resource type panel 54 according to the attribute information, thereby distributing them to the total supply destination list and the resource type lists A and B. Further, the resource type panel 54 forms a resource individual list in the corresponding resource individual panel 56 by searching for the supply destination of each resource based on the resource type list.
[0048]
On the symbol display panel 56, an individual symbol panel for displaying all resources registered in the resource individual list is created. On the supply and demand information display panel, the number of supply plans and the number of supplies are calculated and displayed by examining the attribute information of all resources registered in the resource individual list. The demand information can be sent from another system or input on the screen.
[0049]
When the resource attribute information on the individual symbol panel is changed, the DB 231 is updated by referring to the resource individual list. When the DB 231 is updated, the DB monitoring process in the window 50 detects this and redraws the resource allocation plan matrix on the main panel. Thereby, the registration contents of the DB 231 and the display contents of the resource allocation plan matrix can be easily synchronized.
As described above, according to the present embodiment, it is possible to monitor the resource allocation status at the supply destination in real time through the resource allocation planning matrix, and to perform allocation / redistribution simply by dragging and dropping the symbols. Since the plan can be implemented, it becomes very easy to manage a wide variety of resources that are insufficiently generated, changed, or lost.
In addition, although this embodiment and an example gave and demonstrated the example when a disaster occurred, it cannot be overemphasized that this invention is not limited to these examples.
[0050]
【The invention's effect】
As is clear from the above description, according to the present invention, demand for resources unexpectedly occurs / changes / disappears at many suppliers, and there are many types of resources to be supplied, and the supply status is dynamic. Even if it changes, it is possible to provide a mechanism capable of quickly and accurately determining resource allocation / redistribution.
[0051]
In addition, since multiple allocation plan matrices are linked to form shared cells and common cells, different organizations can function as if they were one organization, and there are no conflicting resources. It will be possible to provide an environment in which allocation and reallocation decisions can be made.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a resource allocation status management system according to the present invention.
FIG. 2 is a configuration diagram of an information processing system according to the present embodiment.
FIG. 3 is a chart defining an example of correspondence of cell colors to supply destination states.
FIG. 4 is a chart defining an example of correspondence of cell colors to resource supply states.
FIG. 5 is a chart that defines an example of correspondence of icon colors to resource supply states.
FIG. 6 is a diagram showing a relationship between a supply destination and a resource type managed in a matrix format of m rows and n columns.
FIG. 7 is an explanatory diagram showing an example of a resource allocation plan matrix.
FIG. 8 is an explanatory diagram showing a mechanism (shared cell) of a plurality of matrices A1, A2, and B1.
FIG. 9 is a diagram showing a specific example of an aggregation / aggregation method of various data for the matrix A1.
FIG. 10 is an explanatory diagram showing a cooperation mechanism (information update) in a plurality of matrices.
FIG. 11 is an overall configuration diagram showing a specific example of a resource allocation plan matrix.
FIG. 12 is a diagram showing a configuration example of a resource individual panel.
FIG. 13 is a diagram showing a configuration example of a supplyable resource panel.
FIG. 14 is a diagram showing a configuration example of a resource sharing panel.
FIG. 15 is an explanatory diagram showing a mechanism of cooperation between a resource allocation plan matrix and a database.
[Explanation of symbols]
1 Resource allocation status management system
2 Information processing system
21 Data input device
22 Display device
23 Storage device
231 Database (DB)
24 I / O interface
25 Central processing unit
10 Database management block
20 Matrix management block
30 Control block
50 windows
51 Main panel
52 Destination panel
53 Resource Panel
54 Resource Type Panel
56 Resource individual panel
57 Supplyable Resource Panel
58 Resource Sharing Panel

Claims (6)

A system that manages the allocation status of multiple resources that are required to be supplied promptly and appropriately to suppliers that unexpectedly occur, change, or disappear.
Database management means for acquiring attribute information of the supply destination and the resource, which changes as needed, and registering them renewably;
Based on the attribute information registered in the database management means, a distribution plan matrix having one of the supply destination and the resource as a row and the other as a column is generated, and the demand state information and supply of the resource at the supply destination Matrix generating means for mapping state information to corresponding cells of the distribution plan matrix;
Control means for dynamically displaying the content of the allocation being displayed each time the content of at least one of the demand status information and the supply status information fluctuates; Have
The matrix generation means generates a first distribution plan matrix and a plurality of second distribution plan matrices having different hierarchies from the first distribution plan matrix, and the contents are common among these distribution plan matrices. Are formed in each of the first distribution plan matrix and the second distribution plan matrix, and the shared cell is one of the first distribution plan matrix and the second distribution plan matrix. Each of which has a common content, and in the first allocation plan matrix, a shared cell is formed for each of the second allocation plan matrices. Information is represented by unique symbols that can move between a plurality of cells, and each unique symbol is linked to the supply status information to each of the allocation plan managers. When a mapping operation is performed on one cell of the unique symbol, the one of the first allocation plan matrix and the second allocation plan matrix is mapped to the shared cell. The resource allocation status management system, wherein the movement operation is reflected in the shared cell of the other allocation plan matrix.   2. The resource distribution status management system according to claim 1, wherein the matrix generation means displays the total cell result in the generated distribution plan matrix on the generated shared cell.   The said control means changes the display form of the said allocation plan matrix dynamically according to the fluctuation | variation of at least one of the said demand status information and supply status information, The item of any one of Claim 1 or 2 characterized by the above-mentioned. The resource allocation status management system described.   4. The resource allocation status management system according to claim 3, wherein the change in the display form is a change in the display color of the corresponding cell and the corresponding symbol. A system for monitoring the distribution status of a plurality of resources that are required to be supplied promptly and appropriately to a supplier that unexpectedly occurs, changes, or disappears. Connected through
Each information processing system constitutes the database management means, the matrix generation means, and the control means described in any one of claims 1 to 4 in cooperation with each other. Distribution status management system.   Some of the plurality of information processing systems each include the database management unit and a matrix generation unit, and when the storage information of any database management unit is updated, all other database management units and the resource allocation plan 6. The resource allocation status management system according to claim 5, wherein display contents of the matrix are updated in synchronization.

Images