JP4114407B2 - Relationship display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a relationship display device that displays a relationship between a plurality of types of elements, and more particularly to a device for displaying a relationship between elements and a relationship between elements and element groups.
[0002]
[Prior art]
In various types of research and analysis work, it is often important to grasp the relationship between a plurality of analysis objects. In addition, there are many cases where a plurality of sets exist for the analysis target, and the relationship between the sets becomes a problem. For example, there is a set of people working in a certain company and a set of information used for business in the company, and the usage relationship between the person and the information is analyzed.
[0003]
A table format is often used when presenting the relationship between elements between such sets collectively. As an apparatus for creating such a table, spreadsheet software, database management software, and the like have been widely used.
[0004]
In addition, a network diagram may be used to present such a relationship. In the network diagram, each element is arranged as a node, and the relationship between the elements is displayed by an arc connecting the nodes. Analysis tools that create and display such network diagrams are also known.
[0005]
The present applicant has proposed a device disclosed in Japanese Patent Application Laid-Open No. 2002-024283 as a device for displaying the relationship between elements between sets. In this device, the nodes indicating the elements belonging to one set are arranged inside and the nodes indicating the elements belonging to the other set are arranged outside in a substantially concentric circle, and the elements that are related between the sets are connected by an arc. indicate.
[0006]
[Problems to be solved by the invention]
In such an analysis of the relationship between sets, elements in the set can often be classified into a plurality of groups. In such a case, it may be necessary to understand the relationship between these groups and the elements of other sets. For example, when information used in a company can be classified by genre, the genre information used by each person is analyzed. Thus, when displaying the relationship between an element in one set and a group in another set, conventionally, by arranging elements belonging to the same group adjacent to each other in the rows and columns of the table, The configuration is being done. However, in this case, the element-to-group relationship is only indirectly expressed in the form of the element pair “elements in a group”. To express the element-to-group relationship more directly, Create another table with the elements in the set and the groups in the other set in rows and columns, respectively, or add a row or column that represents the group in the table that shows the element-to-element relationship. Or create a table that lists the element-to-element and element-to-group relationships.
[0007]
However, in such a system, as the number of elements included in each element set increases, the size of the table increases, and it is difficult to ensure listability. Furthermore, when the relations grouped together were incorporated into the table at the same time, the listability decreased due to an increase in the number of elements.
[0008]
In the concentric circle display by the network diagram and the applicant of the present application, when the nodes of elements in the set are arranged in the display space, the nodes of elements in the same group are brought close to each other so that the grouping can be grasped. However, regarding the point that both the element-to-element relationship and the element-to-group relationship are displayed in a list in an easy-to-read manner, little consideration is given to those conventional techniques.
[0009]
The present invention has been made in order to solve the above-described problems of the prior art, particularly the problem of the relationship display when elements in a set are classified into a plurality of groups. It is an object of the present invention to provide a method and apparatus capable of displaying both of the group-to-group relationships in a list-like manner.
[0010]
[Means for Solving the Problems]
  Reference exampleThen, when displaying the relationship between the first set including a plurality of elements and the second set including a plurality of grouped elements using a computer system,
(A) Set the first area A and the second area B so as not to interfere with each other;
(B) On the first area A, nodes indicating the first elements are arranged,
(C) On the second region B, group nodes representing each group i (i is an integer from 1 to the total number of groups in the second set) are arranged,
(D) An element connecting a node on the first area A and a group node on the second area B based on information indicating an element-to-group relationship between the elements of the first set and the group of the second set Place a group-to-group relationship arc,
(E) The third region Ci and the fourth region Di corresponding to the group i do not interfere with each other, do not interfere with the first region A and the second region B, and each of the regions Ci and Di Is set to be in a predetermined arrangement relationship with respect to the group node indicating the group i on the second area B and the first area A,
(F) On the third area Ci, nodes indicating the elements of the first set are arranged,
(G) On the fourth area Di, a node indicating an element belonging to the group i among the elements of the second set is arranged,
(H) An element pair connecting a node on the third area Ci and a node on the fourth area Di based on information indicating an element-to-element relationship between the elements of the first set and the elements of the second set Place element-related arcs,
  Thus, a relationship display chart displaying a list of element-to-element relationships and element-to-group relationships between the first set and the second set is formed and displayed.
[0011]
According to this configuration, the group node representing the group i of the second set and the node representing the element in the group i are arranged in different areas, and the group node of the group i and the node of the element of the group i Since the fourth area Di for arranging the elements is set in a regular arrangement relation, when displaying the element-to-element relation and the element-to-group relation in a list, the group node and the element node are not mixed and the group node It is easy to grasp the correspondence between the node and the element node belonging to the group. Also, the nodes of each element of the first set are arranged in both the first area A and the third area Ci, and the nodes on the first area A are used for displaying the element-to-group relationship, and the nodes on the third area Ci. Is used for displaying an element-to-element relationship, so that it becomes easy to distinguish between an element-to-group relationship arc and an element-to-element relationship arc.
[0012]
  Note that the execution order of steps (A) to (H) shown in the above configuration is logically necessary such that steps (E) to (H) must be executed after step (C). Except for the order relationship, basically, the order described in the claims is not bound.
The present invention provides an element-to-element relationship storage for storing an element-to-element relationship for each element-to-element pair between a plurality of first set elements belonging to a first set and a plurality of second set elements belonging to a second set Means and information indicating the group i to which the second set element belongs (i is an integer from 1 to the total number of groups) for each of the plurality of second set elements belonging to the second set For each element-to-element pair with the grouping information storage means, the group i to which the second set element forming one of the element-to-element pairs belongs is specified based on the information stored in the grouping information storage means. The element-to-group relationship storage means stores the element-to-group relationship for each element-to-group pair between the first set element forming the other of the element-to-element pair and the specified group i. And calculating the arrangement position of each first set element on a predetermined first circular area A according to the arrangement order determined for a plurality of first set elements belonging to the first set A means for storing in the position storage means, and the first circle area A set outside the first circle area A according to the arrangement order determined for the plurality of groups to which the plurality of second set elements belong. Means for calculating an arrangement position of each group i on the second circular region B substantially concentrically related and storing it in the position storage means; and for each group i, the first circle Between the region A and the second circular region B and at a first position corresponding to the arrangement position of the group i stored in the position storage means, the first circular region A and the second circle Third circular region C so as not to interfere with region B i And the first circular region A, the second circular region B, and the third circular regions C at the second position close to the arrangement position of the group i. i So as not to interfere with the fourth region D i And the third circular region C i For each time, the third circular area C corresponding to the arrangement position of each first set element on the first circular area A stored in the position storage means. i Each of the above positions is represented by the third circular area C i Means for calculating the arrangement position of each first set element above and storing it in the position storage means; and the fourth region D i For each of the fourth areas D with reference to the information in the grouping information storage means. i A plurality of second set elements belonging to the group i corresponding to, and the fourth region D according to the arrangement order determined for the specified plurality of second set elements i Means for calculating the arrangement position of each of the second set elements and storing it in the position storage means, and for each pair of element pairs, the first set element forming one of the pair of element pairs Is obtained from the position storage means for the arrangement position on the first circular area A and the arrangement position on the second circular area B of the group i forming the other of the pair of the element pairs. Means for drawing an element pair group relation arc connecting the obtained arrangement positions, and for each element pair element pair, the third circle region C of the first set element forming one of the element pair element pairs. i The fourth region D of the second set element forming the other of the arrangement position and the other element-to-element pair i The above-described arrangement position is obtained from the position storage means, the element-to-element relation arc connecting the obtained arrangement positions is drawn, and the first set element stored in the position storage means The arrangement position of each group i on the second circle area B, and the third circle area C of each first set element. i Arrangement position above, and the fourth region D of each second set element i There is provided a relation display device comprising means for drawing a node at each of the above arrangement positions.
[0013]
First3Circle ofRegion Ci is the firstCircle ofBy making the shape similar to the region A, it becomes easy to understand that both the regions are the arrangement regions of the nodes of the elements of the same first set.
[0014]
  FurtherSecond3Circle ofThe node of each element of the first set arranged in the area Ci is the first of the nodes indicating the same element.Circle ofThe third corresponding to the arrangement position on the area ACircle ofArranged at position in area CiBe done.
[0015]
  Therefore, FirstCircle ofRegion A and thirdCircle ofIt becomes easy to understand the position of the node of the same element in the area Ci.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention (hereinafter referred to as embodiments) will be described with reference to the drawings.
[0017]
In the following explanation, there are two sets of the element display that are the relationship display and the target, the first element set and the second element set, and only the second element set is grouped as an example. I do. For example, the first element set is a set having each staff member in the company as an element, and the second element set is a paper document, an electronic document or other “information” used for business execution in the company. This is a set of elements, such as when the elements are grouped with respect to the latter “information” set.
[0018]
FIG. 1 is a block diagram showing a configuration example of a relationship display device according to the present invention. The relation display device illustrated in FIG. 1 includes an input unit 10, a structure data storage unit 20, an arrangement processing unit 30, a display processing unit 40, and a display unit 50.
[0019]
The input unit 10 is a means for inputting data about a display target. Information input from the input unit 10 includes, for example, (1) information about each element of the first element set, (2) information about each element of the second element set, and (3) a group of elements in the second element set. Group information indicating division, (4) element-to-element relationship information indicating the relationship between the elements of the first element set and the elements of the second element set, and (5) the elements of the first element set and the groups of the second element set. Element-group relationship information indicating the relationship is included.
[0020]
The structure data storage unit 20 is a storage unit that stores the information input from the input unit. Hereinafter, when the information group stored in the structure data storage unit 20 is referred to as a group, it is referred to as structure data.
[0021]
The arrangement processing unit 30 calculates the arrangement position of each element on the display image based on the structure data stored in the structure data storage unit 20.
[0022]
Based on the arrangement information calculated by the arrangement processing unit 30, the display processing unit 40 reads the data of each element, the data of each group, and the relationship information representing each relationship from the structure data storage unit 20, and displays them for display. After processing the data, a drawing instruction is issued to the display unit 50 based on the result. The display unit 50 creates and displays an image for display according to the instruction from the display processing unit 40.
[0023]
In the following, for simplicity of explanation, a case will be described in which a set of people is used as the first element set, and a set of documents (documents) referred to by those persons is used as the second element set. In this case, an element in the first element set points to an individual person, and each element in the second element set points to a referenced document. The grouping information corresponding to the second element set is information indicating to which group each element of the second element set belongs. In this case, the grouping information can be considered as information indicating the classification of the document.
[0024]
FIG. 2 shows an example of a data structure for storing the first element set in this example. In this example, the data of each element (in this case, “person”) includes two data items “HID” and “NAME”. “HID” is an identifier unique to the data, and “NAME” is a name of “person” indicated by each data. In the structure data storage unit 20, for example, a list expressing such individual element data in a list format is stored as element data of the first element set.
[0025]
FIG. 3 shows an example of a data structure for storing the second element set in this example. In this example, the data of each element (in this case, “document”) includes two data items “DID” and “NAME”. “DID” is an identifier unique to the data, and “NAME” is a name of “document” pointed to by each data. In the structure data storage unit 20, for example, a list expressing such individual element data in a list format is stored as element data of the second element set.
[0026]
FIG. 4 shows an example of the grouping information of the second element set. In this example, “DID” is an identifier of a document that is an element of the second element set, and “GID” is an identifier of a group to which the document belongs. The grouping information is stored in the structural data storage unit 20 as data representing the correspondence between such elements and groups, for example, in a list format.
[0027]
FIG. 5 shows an example of information related to each group of the second element set. In this example, “GID” indicates a group identifier, and “NAME” indicates a group name.
[0028]
In the example of FIGS. 4 and 5, the case where the grouping for the elements of the second element set has already been taken as an example, but the grouping can be performed dynamically based on the attribute information of the elements. . FIG. 6 is a diagram illustrating an example of the data structure of the second element set when such dynamic grouping is performed. In this example, in addition to the items “DID” and “NAME” illustrated in FIG. 3, two items “attribute 1” and “attribute 2” are added. In this example, “attribute 1” is an attribute indicating the type of the object targeted by the document as the element, and “attribute 2” is an attribute indicating the season related to the object targeted by the document. . If the attribute of interest is specified, each element can be automatically grouped by the value of that attribute. For example, if “attribute 1” is designated as a classification viewpoint, a document group related to “flower”, a document group related to “food”, and the like can be grouped according to the type of thing targeted by the document. Thus, if one or more attribute values are registered in advance for each element, the elements can be grouped according to the viewpoint (attribute) to which attention is paid.
[0029]
FIG. 7 is a diagram illustrating an example of a data structure of relationship information representing a relationship between elements belonging to the first element set and elements belonging to the second element set. In this example, use history data of each document that is an element of the second element set of each person that is an element of the first element set is given as an example of the relationship information data. In this example, “HID” is an identifier of an element (person) in the first element set, “DID” is an identifier of an element (document) in the second element set, and “DATE” is the use of the document. Date data indicating the date, “METHOD” is an information item indicating how to use the document. For example, when these documents are registered in one database or electronic bulletin board, data as illustrated in FIG. 7 can be obtained as an access log for the database or electronic bulletin board. The data illustrated in FIG. 7 is close to the raw data of the usage history (log), and when the element-to-element relationship is actually displayed, the result of summing up the data is used as the relationship information data. It is also possible. For example, by collecting raw usage history data for each element (HID) -to-element (DID) correspondence, it is possible to create relationship information representing the number of times of use for each element-to-element correspondence.
[0030]
As described above, the example of the structure data stored in the structure data storage unit 20 has been described with reference to FIGS. 2 to 7, but the various data formats illustrated are merely examples.
[0031]
In the present embodiment, a relationship display chart as shown in FIG. 8 is generated. In this example, the central circular region 100 and the eight small circular regions 110 around it are set as regions in which the nodes of each element of the first element set are arranged. The central circular area 100 is a node display area for displaying the relationship with the group in the second element set. The surrounding circular area 110 is a node display area for displaying the relationship with each element of the second element set. Each circular area 110 corresponds to one of the groups in the second element set. That is, the example of FIG. 8 corresponds to the case where the elements of the second element set are classified into eight groups.
[0032]
In the central circular region 100, nodes of all elements belonging to the first element set are arranged at regular intervals, for example. Similarly, in the eight circular regions 110, nodes of all elements belonging to the first element set are arranged at equal intervals, for example.
[0033]
The eight nodes 120 located on the outermost periphery are nodes that represent groups in the second element set. The relationship between the elements of the first element set and the groups of the second element set is expressed by an arc 140 that connects the group node 120 and each node on the central circular region 100.
[0034]
Each arc region 130 located between the group nodes 120 is a region in which nodes of elements belonging to the second element set are arranged. A pair of arc regions 130 on both sides of one group node 120 is an arrangement region for nodes of elements belonging to the group indicated by the group node 120. A pair of arc regions 130 and circular regions 110 corresponding to one group are arranged close to each other in a form in which a certain regularity is felt. In the example of FIG. 8, a fan-shaped range 160 is assigned to each of the eight groups, and the arc region 130 and the circular region 110 of the group are arranged in the range 160. The relationship between each element in the group and each element in the first element set is as follows: each node on the pair of arc regions 130 of the group and each on the circular region 110 located in the vicinity of the pair of arc regions 130 It is expressed by an arc 150 connecting the nodes.
[0035]
Heretofore, an example of the relationship display chart created by the relationship display device of the present embodiment has been described. In this relationship display chart, the group node representing the group of the second element set and the node representing the element in the group are arranged at different positions and regularly close to each other. There is an advantage that the correspondence between the group node and the node of the element belonging to the group can be easily grasped. In addition, as a region for arranging the nodes of the first element set, a circular region 100 for displaying an element-pair relationship and a circular region 110 for displaying an element-to-element relationship are provided separately. As a result, the arc 140 representing the element-to-group relationship and the arc 150 representing the element-to-element relationship extend from separate circular regions 100 and 110, respectively. In addition, since the element-to-element relation display circular area 110 is provided for each group of the second element set, the element-to-element relation arc 150 extending from the elements of different groups is divided into different ranges for each group. This improves the visibility. In addition, since the region in which the group node 120 is arranged is substantially concentric with the central circular region 100, the angle at which each group node 120 is desired from the circular region 100 becomes substantially the same. The number of arcs connected to 120 can be roughly determined by the darkness of the image in the same angular range.
[0036]
Next, arrangement area setting by the arrangement processing unit 30 when creating the relationship display chart illustrated in FIG. 8 will be described. Hereinafter, the arrangement area setting process will be described in two stages of a first stage process and a second stage process for convenience.
[0037]
FIG. 9 is a diagram for explaining an arrangement area set in the first stage process. In this first step, the arrangement of the group node 120 representing each group in the second element set and the arrangement position of the elements of the first element set for representing the relationship between the group nodes are determined. Calculate to do. That is, in the first stage process, an arrangement area of nodes for displaying the relationship between element pairs is set.
[0038]
The arrangement area A is an area for arranging the first element set, and corresponds to the central circular area 100 in FIG. In the example of FIG. 8, the arrangement area A is a circular area, but may be an elliptical area. The reference point PA is a reference point for the arrangement of the arrangement area A. If the arrangement area A is circular, it is the center of the circle. Further, a donut-shaped region in which a circle or an ellipse has a width can be used as the arrangement region A. In this case, since the arrangement positions of the nodes can be distributed in the width direction of the donut shape (in the radial direction in the case of a circle and an ellipse), the distinguishability of the arranged nodes is improved as compared with a simple circular region or the like. be able to.
[0039]
The arrangement area B is an area in which the group node 120 corresponding to the group of the second element set is arranged. The arrangement area B is preferably a figure similar to the arrangement area A with the same reference point PA as that of the arrangement area A as a reference. Since the number of groups is considered to be much smaller than the number of elements, group nodes 120 are sparsely arranged in the arrangement region B as illustrated in FIG.
[0040]
In the above, preferred examples of the arrangement area A and the arrangement area B include a circular area, an elliptical area, and a circular or elliptical donut-shaped area centered on the reference point PA. The effect of this embodiment can be obtained to some extent even if it is a square region or a part of the shape.
[0041]
Next, the arrangement area set in the second stage process will be described with reference to FIG. At this stage, a node arrangement area for displaying the element-to-element relationship is set. That is, a pair of arc regions 130 for each group of the second element set and a circular region 110 that is an arrangement region of elements of the first element set corresponding to each group are set. In this area setting, the following processing is repeated for each group in the second element set.
[0042]
First, the setting of the circular area 110 will be described. Here, among the groups of the second element set, the group of interest is the i-th group, and the corresponding group node is the group node i. In this case, first, a reference point PCi is set for the group node i, and an arrangement area Ci (corresponding to the circular area 110) in which the first element set is arranged corresponding to the reference point PCi is set. This reference point PCi is preferably arranged on a straight line connecting the reference point PA and the arrangement coordinates of the group node i. However, this is an example. Any position may be used as the reference point PCi as long as a regular relationship can be grasped for each group node i. Such a position can be obtained with reference to the reference point PA and the arrangement coordinates of the group node i. The arrangement area Ci is set as a shape having the reference point PCi as a reference position. Preferably, the arrangement area Ci is an area having a shape that can easily grasp the correspondence with the shape of the arrangement area A, such as a shape similar to the arrangement area A, or a shape obtained by performing affine transformation on the arrangement area A. Set as.
[0043]
Next, the setting of the arc region 130 will be described. In this setting process, a reference point PDi is set for the group node i, and an arrangement area Di for arranging elements of the i-th group of the second element set is set corresponding to the reference point PDi. Here, the reference point PDi is preferably arranged on a straight line connecting the reference point PA and the arrangement coordinates of the group node i. However, this is an example. Any position may be used as the reference point PDi as long as a regular relationship can be grasped for each group node i. Such a position can be obtained with reference to the reference point PA and the arrangement coordinates of the group node i. In an extreme case, the reference point PDi can be set at the same coordinates as the reference point PA. The arrangement area Di is set around the reference point PDi. Preferably, the arrangement area Di is set as an arc-shaped area centered on the reference point PDi. As shown in the drawing, this arc-shaped arrangement area Di is set to a range on the group node i side as viewed from the reference point PDi, and its radius is determined so as not to intersect the arrangement area B and the arrangement area Ci. In the example of FIG. 10, the straight line connecting the reference point PA and the arrangement coordinates of the group node i is used as the symmetry axis, and the arrangement area Di is set so as to be symmetric about the axis. A pair of arc regions 130 illustrated in FIG. 8 can be set by notching part of the arc-shaped arrangement region Di in the vicinity of the axis of symmetry and providing a gap. This gap prevents the arc region 130 (arrangement region Di) from blocking the portion of the viewing angle at which the arrangement region A is desired from the group node i. Accordingly, the element-to-group arc 140 that connects the arrangement area A and the group node can be prevented from passing through the arrangement area Di, so that the element-to-element arc 150 and the element-to-group arc 140 Makes it easier to distinguish.
[0044]
The method for determining the arrangement area Di described above is merely an example. The shape of the arrangement region Di is not limited to an arc, and may be a part of an ellipse, for example. Further, the arrangement of the arrangement area Di is not limited to being symmetrical with respect to a straight line connecting the reference point PA and the arrangement coordinates of the group node i. The arrangement area Di may be set in any arrangement as long as a regular relationship can be grasped for each group node i.
[0045]
By repeating the setting of the placement areas Ci and Di as described above for the number of groups in the second element set, the process of the second stage is completed.
[0046]
Hereinafter, the processing procedure of the apparatus of this embodiment will be described.
[0047]
FIG. 11 is a flowchart showing an example of the overall processing flow of the apparatus of this embodiment. In this processing procedure, first, the above-described structure data is read from the input unit 10 and stored in the structure data storage unit 20 (S10). Next, the display processing unit 40 executes a preparation process for display (S12). This display preparation process includes the above-described process of calculating the usage history data to obtain the relationship information, the dynamic grouping process of the second element set, and the like. Next, the arrangement processing unit 30 determines each of the arrangement areas A, B, Ci, Di illustrated in FIGS. 9 and 10 according to a predetermined calculation method, and further, determines each node on each of the arrangement areas. An arrangement position is determined (S14). Then, the display processing unit 40 generates a relation display chart according to the information on the arrangement area and the arrangement position of each node and the relation information between each node (element, group) stored in the structure data storage unit 20. And display (S16).
[0048]
Next, an example of display preparation processing (S12) in the overall processing procedure will be described.
[0049]
In the history data in which a person refers to a document or various information as illustrated in FIG. 7, an element in the first element set (in this example, person) and an element in the second element set are often used. It is held as history data in the form of a combination (in this example, a document). In this display preparation process, first, such history data is aggregated to generate relation information.
[0050]
In this tabulation process, tabulation on the element-to-element relationship and tabulation on the element-to-group relationship are performed between the first element set and the second element set. As a simple example of this tabulation, an example is one in which the appearance frequencies for each of the relationships appearing in the history data are tabulated.
[0051]
In such a tabulation process, since the history data shows the element-to-element relationship in each usage history, the element-to-element relationship information can be obtained simply by performing a tabulation process on this history data. Good. For example, for each element, the frequency at which the relationship to which the element belongs appears in the history data, or the frequency at which the relationship indicated by the pair appears in the history data for each element-to-element pair, etc. Can be processed. The total result data includes, for example, a table TEA composed of a set of identifiers and total values of each element of the first element set, and a table TEB composed of a pair of identifiers and total values of each element of the second element set. included. Further, the total value table TRAB for each element-element relationship is also included in the total result. In this table TRAB, each element-to-element relationship is indicated by a pair of an element identifier of the first element set and an element identifier of the second element set constituting the relationship. The data of the total result is also stored in the structure data storage unit 20.
[0052]
Next, the aggregation of the element-to-group relationship will be described. Here, an example will be described in which aggregation of elements of the first element set is performed for each group.
[0053]
First, as many tabulation tables as the number of groups in the second element set are generated. This table corresponding to the group i is referred to as a total table TGiA. In this aggregation table TGiA, for each element of the first element set, the appearance frequency of the relationship between that element and group i (that is, the appearance frequency of that element in the history data) is registered. Further, a tabulation table TG for the group is generated. In this tabulation table TG, for each group i, the appearance frequency of the relationship between the group and the element group of the first element set (that is, the appearance frequency of the group in the history data) is registered. Further, a totaling table TRAG for recording a totaling result for each element-group relationship is generated. In the tabulation table TRAG, the frequency at which the combination appears in the history data is registered for each combination of the element and group of the first element set.
[0054]
In the aggregation process, one data is extracted from the list of history data (see FIG. 7), the DID value that is the identifier of the element of the second element set is obtained from the data, and the grouping information (see FIG. 4) is referred to. The group to which the element belongs is determined. When the obtained group identifier GID is, for example, k, in the aggregation table TGkA, the aggregation value corresponding to the HID included in the extracted data is increased by one. In this case, the total value of the group k is increased by 1 in the total table TG. Also, in the aggregation table TRAG, the aggregation value for the combination of the identifier k of the group and the identifier HID of the first element set is increased by one.
[0055]
The above processing is totaled for the entire history data or the range specified by the user (for example, the history period can be specified) in the history data, and the aggregation tables TGiA (the number of groups), TG, TRAG are created. And stored in the structure data storage unit 20.
[0056]
Next, the flow of the arrangement calculation process will be described with reference to FIG. In this arrangement calculation process, the arrangement area A used for displaying the element-to-group relationship is first set by the method described above, and the arrangement position of the node corresponding to each element of the first element set is determined (S20). The arrangement positions of the nodes are determined so that, for example, the nodes are arranged at equal intervals in an order determined according to a predetermined rule. The arrangement order of the nodes can be determined based on various attribute values or combinations of various attribute values of the elements of the first element set. For example, when the element is “person”, the arrangement order of the nodes of each person is determined by the value of one attribute or the combination of the values of a plurality of attributes among various attributes such as the name and department of each person. Then, according to the arrangement order determined in this way, the arrangement position of each node is determined so that each node is arranged from a predetermined reference position of the arrangement area A according to a predetermined arrangement rule. The calculated arrangement position coordinates of each node are stored in the structure data storage unit 20. In this case, preferably, for each element of the first element set, the identifier (HID) of the element, the arrangement position of the node of the element, and the arrangement position indicate that the arrangement position is related to the arrangement area A. A set of information is stored.
[0057]
Next, the arrangement area B is set by the above-described method, and the arrangement position of the group node representing each group of the second element set is determined (S22). The arrangement positions of the group nodes are determined so that, for example, the group nodes are arranged at equal intervals in an order determined according to a predetermined rule. It is also preferable to determine the arrangement interval of each group node according to, for example, the ratio of the number of elements belonging to the corresponding group instead of the equal interval. This is the same concept as the pie chart (pie graph) in the graph display, and the interval between the group nodes is determined according to the number of elements in the group. Therefore, the element arrangement area Di corresponding to the group is determined according to the number of elements in the group. Area can be secured. The arrangement order of group nodes can be determined according to a predetermined rule according to the attribute value (or combination of a plurality of attribute values) of the corresponding group. The calculated arrangement position coordinates of each group node are stored in the structure data storage unit 20. In this case, preferably, for each group, a set of the identifier (i) of the group and the arrangement position of the group node is stored. Furthermore, information indicating that the arrangement position is an arrangement position related to the arrangement area B may be stored in association with the set.
[0058]
Either of the arrangement calculation processes (S20 and S22) relating to the arrangement areas A and B described above may be executed first. When these steps are finished, next, an unprocessed group i is selected from the structure data storage unit 20 (S24), and the arrangement calculation for the arrangement area Ci and the arrangement area Di is executed for the group i (S26 and S28). ).
[0059]
First, in step S26, the arrangement area Ci is set for the group i by the above-described method, and the arrangement position of the node corresponding to each element of the first element set in the arrangement area Ci is determined. In this step, for example, the reference point PCi is set to a position that internally divides the line segment connecting the reference point PA and the arrangement position of the group node i into m: n (m and n are integers). The placement region Ci is, for example, a circular region (or a donut shape with the circle as a reference) having a radius obtained by multiplying the radius of the circle of the placement region A by n / (m + n). Area). The arrangement position of the node of each element on the arrangement area Ci is a position corresponding to the arrangement position of the node of the element in the central arrangement area A. For example, when attention is paid to an element α in the first element set, the arrangement position Aα of the node of the element α on the arrangement area A has already been determined in step S20 as shown in FIG. Here, a vector extending from the reference point PA of the arrangement area A toward the arrangement position Aα is defined as LAα. Then, the vector LCiα parallel to the vector LAα is extended from the reference point PCi, and the point where the vector LCiα intersects the circle of the placement area Ci is defined as the placement position Cα of the node corresponding to the element α on the placement area Ci. To do. According to this method, the arrangement position Cα in the arrangement area Ci and the arrangement position Aα in the arrangement area A with respect to the node of the same element α are in the same direction as viewed from the reference points PCi and PA of each area. Therefore, it is easy to grasp nodes representing the same element in both the areas A and Ci. The arrangement position coordinates of each node calculated in this way are stored in the structure data storage unit 20. In this case, preferably, for each element of the first element set, the identifier (HID) of the element, the arrangement position of the node of the element, and the arrangement position indicate that the arrangement position is related to the arrangement area Ci. A set of information is stored.
[0060]
Next, in step S28, the arrangement area Di is set for the group i by the above-described method, and the arrangement position of the node of each element belonging to the group i on the arrangement area Di is calculated. For example, the reference point PDi can be set on a straight line connecting the reference point PA and the arrangement position of the group node i, and can be the same position as the reference point PCi described above. Then, the radius of the arrangement area Di is determined based on the length of the line segment that connects the reference point PDi and the arrangement position of the group node i with the reference point PDi as the center. When the reference point PDi and the radius are determined, it is determined which part of the circumference defined by these is used as the placement region Di. In the example of FIG. 8, an arc-shaped area is set symmetrically with respect to a vector (referred to as vector V) extending from the reference point PA to the group node i, and a portion of the arc-shaped area near the vector V is deleted. Thus, a pair of arc regions 130 is set as the arrangement region Di for the group i. In this case, each arc region 130 can be defined by the center angle of the arc with respect to the vector V. Such radius and center angle conditions may be registered in advance in the placement processing unit 30 as fixed conditions, or input may be received from the user via a user input device such as a keyboard or a mouse. Good.
[0061]
When this arrangement region Di is strictly calculated based on predetermined parameters in advance, various known calculation methods, for example, a calculation method disclosed in Japanese Patent Laid-Open No. 11-85837 may be diverted. it can.
[0062]
On the arrangement area Di thus determined, the nodes of the elements belonging to the group i are arranged according to a predetermined rule. When the chart of FIG. 8 is created, each element of the second element set associated with the group i is ordered according to a predetermined rule, and the ordered element group is classified into two sets according to a predetermined criterion. Are assigned to the respective arc regions 130. Then, according to the ordering of the elements, the arrangement positions of the nodes of the respective elements are determined so that the respective elements are arranged at equal intervals on the respective arc regions 130.
[0063]
The processes in steps S24 to S28 described above are repeated for all groups in the second element set (S29).
[0064]
Note that the example shown in FIG. 8 in which the arrangement area Di of the elements of the group i is divided into two at the center position is merely an example. For example, instead of dividing into two, even if only the arc-shaped area extending to one side of the vector extending from the reference point PA to the group node i is set as the arrangement area Di, the relationship between the group node i and the arrangement area Di is regular and understood. It's easy to do.
[0065]
The display process (S16) using the results of the display preparation process and the arrangement calculation process described above will be described with reference to FIG. The steps described below do not necessarily have to be performed in the order described here. Even if the order of some steps is changed, the same effect can be obtained, but an example is briefly given here.
[0066]
In this process, the element-group relationship is first drawn (S30). In this step S30, information of the aggregation table TRAG (holding the aggregation result for each element-to-group relationship) is obtained from the structure data storage unit 20, and processed in order. Prior to this process, it is possible to perform a pre-process of rearranging the order of each data in the total table TRAG according to a predetermined rule.
[0067]
In the process of step S30, data is sequentially read from the table TRAG, and the element identifier HID and group identifier GID of the first element set are obtained from the data. Next, from the information of the arrangement calculation result, the arrangement position of the node corresponding to the identifier HID in the arrangement area A and the arrangement position of the node corresponding to the identifier GID are obtained. Then, a line (arc) connecting these two arrangement positions is drawn. Here, by changing the display form of the arc (for example, the color and the thickness of the line) according to the value of the total value included in the data read from the table TRAG, the degree of the relationship between the element and the group can be set. Can be read from the arc. The above processing is performed for all data included in the aggregation table TRAG.
[0068]
Next, one unprocessed group is selected (S32), and drawing processing for this group is performed (S34 to S38).
[0069]
Let i be the identifier of the group selected in step S32. In this series of processes, an arc indicating the element-to-element relationship is first drawn between the placement area Ci and the placement area Di (S34). In this drawing processing, first, data is sequentially read from the structural data storage unit 20 from the aggregation table TRAB (holding the aggregation result for each element-element relationship), and the element identifier HID of the first element set is read from the data. Then, the identifier DID of the element of the second element set is obtained. Next, the group identifier GID corresponding to the obtained identifier DID is obtained by referring to the grouping information. If the identifier GID of the group is different from the identifier i of the currently focused group, the drawing process is not performed and the process proceeds to the next data in the table TRAB. When the identifier GID is the same as i, the arrangement position in the arrangement area Ci corresponding to the obtained identifier HID and the arrangement position in the arrangement area Di corresponding to the obtained identifier DID are respectively read from the structure data storage unit 20. Then, an arc connecting the two arrangement positions is drawn. The display form of the arc can also be changed according to the total value for the relationship.
[0070]
Next, a node drawing process on the placement area Ci is performed (S36). In this process, information on the elements of the first element set is sequentially obtained from the structural data storage unit 20, and the arrangement position in the arrangement area Ci is obtained from the identifier HID of each element. Further, the total value corresponding to this identifier HID is obtained from the total table TGiA. Then, with the arrangement position as a reference, the node of the element is drawn in a display form corresponding to the total value. As a simple example, a process such as drawing a figure such as a circle or a rectangle centered on the obtained coordinate value with a color corresponding to the total value can be given.
[0071]
Similarly, a node drawing process on the placement area Di is performed (S38). In this process, the information of the elements of the second element set is obtained in order from the structural data storage unit 20, the identifier GID of the group corresponding to the elements is obtained from the grouping information, and the identifier GID is currently focused on. It is determined whether or not it matches the group identifier i. If they do not match, the process moves to the next element. If they match, the arrangement position in the arrangement area Di corresponding to the identifier DID of the element is obtained from the arrangement calculation result, and the total value corresponding to the identifier DID is obtained from the total table TB. Then, with the arrangement position as a reference, the node is drawn in a display form corresponding to the total value. As a simple example, a process such as drawing a figure such as a circle or a rectangle centering on the obtained arrangement position with a color corresponding to the total value may be mentioned. More simply, the information of the elements of the second element set is obtained in order, and the group identifier GID is obtained from the identifier DID corresponding to the element by referring to the structured data. After confirming that the group is a group, the arrangement position in the arrangement area Di can be obtained by referring to the structure data storage unit, and the same drawing process can be performed.
[0072]
The series of processes (S32 to S38) described above are repeated for all groups (S40). As a result, the arc indicating the element-to-element relationship and the nodes related thereto are drawn for all the groups. Instead of drawing all groups, it is possible to limit the groups to be drawn according to the user's specification.
[0073]
When the drawing regarding the element-to-element relationship is finished in this way, the node in the placement area A is drawn (S42). In this process, information on the elements of the first element set is sequentially obtained from the structural data storage unit 20, and the arrangement position of the element in the arrangement area A is obtained from the identifier HID of each element. Further, the total value corresponding to the element is obtained from the total table TA. Then, with the arrangement position as a reference, a node having a display form corresponding to the total value is drawn. As a simple example, a process such as drawing a figure such as a circle or a rectangle centering on the obtained arrangement position with a color corresponding to the total value may be mentioned.
[0074]
Next, a group node is drawn in the arrangement area B (S44). In this process, group information is sequentially obtained with reference to the grouping information in the structure data storage unit 20, and the arrangement position of the node of the group in the arrangement area B is obtained from the identifier GID of each group. Further, the total value for the group is obtained from the total table TG. Then, with the arrangement position as a reference, a node having a display form corresponding to the total value is drawn. As a simple example, there is a process of drawing a figure such as a circle or a rectangle centering on the obtained arrangement position with a color corresponding to the total value.
[0075]
Through the processing as described above, the relationship display chart illustrated in FIG. 8 is drawn.
[0076]
In the apparatus of this embodiment, concentric circle display of only the element-to-element relationship (illustrated in FIG. 15) in JP-A-2002-024283 described above, display of only the element-to-group relationship as illustrated in FIG. In addition, the simultaneous display of the element-to-element relationship and the element-to-group relationship in the present embodiment can be sequentially switched and displayed. This display switching is not only simple switching but also so-called morphing, in which each node and each arc is continuously moved from the position / posture in the switching source display to the position / posture in the switching destination display. It is also suitable to use. In the concentric circle display of FIG. 15, the nodes representing the elements of the two element sets are arranged in the central circular area 100 and the outer circular area 170, respectively, and the relationship between the elements of both sets is an arc. It is shown in Further, in the display of FIG. 16, a node representing the element of the first element set is arranged in the central circular area 100, and a group node 120 representing the group of the second element set is arranged in the outer concentric area, Element-to-group relationships are indicated by arcs.
[0077]
In addition, in the conventional concentric circle display of FIG. 15, the nodes of the second element set arranged in the outer circular area 170 can be selected by the user, and the above-mentioned elements can be selectively selected only for the group to which the node selected by the user belongs. It is also possible to simultaneously display the relationship between the pair group and the element pair element. As a result, the user can perform detailed analysis on the part he / she wants to see. In addition, the nodes 170 of the second element set are arranged in advance according to the grouping in the concentric circle display of FIG. 15, and dummy nodes for accepting user selections representing each group are displayed in the vicinity of the node group of each group. This facilitates an operation for selecting a group to which the user pays attention.
[0078]
In addition, in the above, the method of displaying the relationship has been described by taking as an example the case where one of the two element sets is grouped. However, by applying the same technique recursively, the element sets can be hierarchically multi-staged. The relationship when grouped can be displayed.
[0079]
In this hierarchically grouped structure, the intermediate group can be displayed as shown in FIG. 16, and the display can be changed hierarchically in the upper and lower directions.
[0080]
In particular, when the display method of displaying the individual elements of the terminal hierarchy first and then grouping them in order is used, the arrangement order in the state where the elements of the terminal hierarchy are completely expanded as shown in FIG. In consideration of the above, it is desirable to determine the arrangement order of nodes representing groups in the middle hierarchy. By doing so, there is an advantage that when the display is changed hierarchically, the correspondence between the nodes displayed before and after the change becomes easy to understand.
[0081]
As an extreme example, the arrangement area Di is provided in the arrangement area B, and the reference point PDi of the arrangement area Di can be set to the same position as the position of the reference point of the arrangement area B. This corresponds to dividing the arrangement area B by the arrangement areas Di for the number of groups. In this case, the group node 120 and the node of the element of the second element set are located on the circumference having the same radius as viewed from the reference point PA that is the center of the concentric circle. This is a form close to that obtained by adding an arc of a group node and an element pair group relationship to the concentric circle display of the element pair element illustrated in FIG. If the group node is simply added to the circular area outside the concentric circle display, it may be difficult to distinguish between the group node and the element node and the range of each group. If the gap is provided so as not to interfere with each other and the arrangement area Di is divided into two as illustrated in FIG. 8 and the group node 120 is arranged between them, the distinction between them can be easily seen. According to such an arrangement setting, only the element-to-group relation display as shown in FIG. 16, the element-to-element-only relation display as shown in FIG. When sequentially switching the three displays, such as display, by morphing, etc., it is not necessary to move the position of the node (particularly the element of the second element set or the node of the group) shown in each display. It becomes easy to understand the correspondence between nodes between displays. This effect becomes more effective when a plurality of hierarchies are grouped.
[0082]
In the above description, the case where only the second element set arranged in the outer area is grouped has been described. However, this eliminates the grouped display of the first element set displayed in the inner area. It is not a thing. The grouping display of the first element set may be performed, for example, by a method of arranging the element nodes on the central arrangement area A by dividing the range into groups. If a gap is provided between the ranges of adjacent groups, the separation of the groups can be easily understood. The grouping may be performed dynamically according to, for example, the attribute value of the element, or may be realized by giving the apparatus information about the first element set from the beginning.
[0083]
In the above example, the element-to-group relationship is represented by an arc between the node on the central circular area 100 (arrangement area A) and the group node 120 arranged in the outer arrangement area B. However, instead of this, an arc indicating the element-to-group relationship can be expressed by an arc extending from a node on the circular area 110 (arrangement area Ci) to the group node 120. In this modification, there are a modification in which a node corresponding to the first element set is not drawn in the arrangement area A and a modification in which drawing is performed. In the latter case, a node corresponding to the first element set is drawn in the arrangement area A, and the first arranged in the arrangement area A according to the presence / absence of the relation with each group node i and the total value of the relation. There may be a modification in which an arc that connects a node of an element of an element set and a node representing a corresponding element arranged in each arrangement area Ci is displayed. In this modification, the final relationship display chart is similar to that shown in FIG. 8, but the size of the arrangement area Ci is changed, or the positional relationship between the group node i and the arrangement area Ci is given a degree of freedom. Can do. For example, the positional relationship among the circular areas 100 and 110, the group node 120, and the arc area 130 can be set as shown in FIG. In the example of FIG. 17, in order to avoid complexity, only the arrangement area of the nodes related to some groups is shown, and the arc indicating the relationship is not shown. Even in the arrangement as shown in FIG. 17, there is a certain regular relationship between the group node 120 and the areas 110 and 130 corresponding to the group, and the relationship can be grasped on the display. Further, in a modification in which the first element set is not drawn in the arrangement area A, the arrangement area B in which the group node is arranged is set on the opposite side of the arrangement area Di with respect to the arrangement area Ci (that is, the arrangement area in FIG. There may be a modification in which a group node placement area B is set at a position of A). In this modification, for example, a name, symbol or symbol figure representing a group is arranged in the center of the figure, an arrangement area Ci corresponding to the group i is set outside thereof, and an arrangement area Di is set outside thereof. It becomes the form.
[0084]
In the above, the case where nodes are arranged in a region on a closed curve such as a circle or an ellipse has been described, but the application of the method of the present embodiment is not limited to such a case. For example, as shown in FIG. 18, the arrangement area of each node may be a linear area. In this example, nodes (indicated by circles in the figure) representing elements of the first element set are arranged in the areas 200 and 210, respectively. An area 200 is an area for a node indicating a relationship between element pairs and corresponds to the circular area 100 in FIG. An area 210 is an area for a node indicating an element-to-element relationship, and corresponds to the circular area 110 in FIG. The area 210 is provided for each group, and is set in parallel to the area 200 around a perpendicular line that extends from the group node 220 corresponding to the group toward the area 200 (on a straight line). The area 230 is an area for a node indicating an element of each group in the second element set, and is set in parallel with the area 200. In this example, a pair of regions 230 corresponding to the group are provided on both sides in the vicinity of the group node 220. That is, the element node of the second element set is not arranged in the vicinity of the vertical line from the group node 220 toward the region 200. For this reason, it is possible to make the arc 240 indicating the element-pair relationship and the arc 250 indicating the element-element relationship difficult to be confused.
[0085]
As described above, according to the apparatus of the present embodiment, the element-to-element relationship and the element-to-group relationship between a plurality of element sets can be displayed on the same display surface in an easy-to-read manner. it can. By using such a relationship display chart, the efficiency in analyzing and managing the structure of the relationship between sets can be increased. In addition, the easy-to-understand display is useful for discussion and persuasion among a plurality of analysts and observers, and the efficiency in such a scene can be increased.
[0086]
Note that the relationship display device of the present embodiment described above can be typically configured by causing a computer system to execute a program describing each function and processing procedure described above.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a schematic configuration of a relationship display device according to an embodiment.
FIG. 2 is a diagram illustrating an example of data contents of information of an element group of a first element set.
FIG. 3 is a diagram illustrating an example of data contents of information of an element group of a second element set.
FIG. 4 is a diagram illustrating an example of data contents of grouping information indicating grouping of a second element set.
FIG. 5 is a diagram illustrating an example of data contents of group information.
FIG. 6 is a diagram showing another example of the data contents of the information of the element group of the second element set.
FIG. 7 is a diagram illustrating an example of data indicating a relationship between elements.
FIG. 8 is a diagram illustrating an example of a relationship display chart generated by the apparatus according to the embodiment.
FIG. 9 is a diagram for explaining a node arrangement area when creating a relationship display chart;
FIG. 10 is a diagram for explaining a node arrangement area when creating a relationship display chart;
FIG. 11 is a flowchart showing a schematic procedure of a relation display chart creation process;
FIG. 12 is a flowchart showing a processing procedure for calculating a node arrangement position;
FIG. 13 is a diagram for explaining how to obtain the arrangement position of a node with respect to the arrangement area Ci.
FIG. 14 is a flowchart showing a procedure of display processing.
FIG. 15 is a diagram showing an example of a chart in which only the element-to-element relationship is displayed concentrically.
FIG. 16 is a diagram showing an example of a chart in which only the relationship between element pairs is displayed concentrically.
FIG. 17 is a diagram illustrating another example of a configuration of a node arrangement area.
FIG. 18 is a diagram illustrating an example in which the arrangement area of nodes is a linear area.
[Explanation of symbols]
10 input unit, 20 structure data storage unit, 30 placement processing unit, 40 display processing unit, 50 display unit, 100, 110 circular region, 120 group node, 130 arc region, 140, 150 arc.

Claims (2)

Element-to-element relationship storage means for storing an element-to-element relationship for each element-to-element pair between a plurality of first set elements belonging to the first set and a plurality of second set elements belonging to the second set;
  For each of a plurality of second set elements belonging to the second set, grouping information storing information indicating a group i to which the second set element belongs (i is an integer from 1 to the total number of groups) Storage means;
  For each element-to-element pair, a group i to which a second set element forming one of the element-to-element pairs belongs is specified based on information stored in the grouping information storage unit, and the element-to-element pair Means for storing an element pair group relationship for each pair of element pairs in the element pair group storage means between the first set element forming the other of the group i and the specified group i;
  According to the arrangement order determined for the plurality of first set elements belonging to the first set, the arrangement position of each first set element on the predetermined first circular area A is calculated and stored in the position storage means Means for storing;
  A second set which is set outside the first circular region A and is substantially concentric with the first circular region A according to the arrangement order determined for the plurality of groups to which the plurality of second set elements belong. Means for calculating an arrangement position of each group i on the circular area B and storing it in the position storage means;
  For each group i, the first position between the first circular area A and the second circular area B and corresponding to the arrangement position of the group i stored in the position storage means is the first position. The third circular region C so as not to interfere with the first circular region A and the second circular region B. i And the first circular region A, the second circular region B, and the third circular regions C at the second position close to the arrangement position of the group i. i So as not to interfere with the fourth region D i A means of setting
  The third circular area C i For each time, the third circular area C corresponding to the arrangement position of each first set element on the first circular area A stored in the position storage means. i Each of the above positions is represented by the third circular area C i Means for calculating the arrangement position of each first set element above and storing it in the position storage means;
  The fourth region D i For each of the fourth areas D with reference to the information in the grouping information storage means. i A plurality of second set elements belonging to the group i corresponding to, and the fourth region D according to the arrangement order determined for the specified plurality of second set elements i Means for calculating an arrangement position of each of the second set elements at and storing it in the position storage means;
  For each pair of the element pair group, an arrangement position on the first circular area A for the first aggregate element forming one of the pair of the element pair group and a group forming the other of the pair of the element pair group means for determining an arrangement position of i on the second circular area B from the position storage means, and drawing an element-to-group relationship arc connecting the obtained arrangement positions;
  For each element-to-element pair, the third circle region C of the first collective element forming one of the element-to-element pairs i The fourth region D of the second set element forming the other of the arrangement position and the element-pair pair i An arrangement position above, from the position storage means, means for drawing an element-to-element relation arc connecting the obtained arrangement positions;
  Arrangement position on the first circular area A of each first set element stored in the position storage means, arrangement position on the second circular area B of each group i, each first Said third circular region C of the set element i Arrangement position above, and the fourth region D of each second set element i Means for drawing a node at each of the above placement positions;
  A relationship display device comprising: Computer
Element-to-element relationship storage means for storing an element-to-element relationship for each element-to-element pair between a plurality of first set elements belonging to the first set and a plurality of second set elements belonging to the second set;
  For each of a plurality of second set elements belonging to the second set, information indicating a group i to which the second set element belongs (i is any integer from 1 to the total number of groups) is stored. Grouping information storage means,
  For each element-to-element pair, a group i to which a second set element forming one of the element-to-element pairs belongs is specified based on information stored in the grouping information storage unit, and the element-to-element pair Means for storing, in an element-to-group relationship storage means, an element-to-group relationship for each element-to-group pair between the first set element forming the other of the group i and the specified group i;
  According to the arrangement order determined for the plurality of first set elements belonging to the first set, the arrangement position of each first set element on the predetermined first circular area A is calculated and stored in the position storage means Means for storing,
  A second set which is set outside the first circular region A and is substantially concentric with the first circular region A according to the arrangement order determined for the plurality of groups to which the plurality of second set elements belong. Means for calculating an arrangement position of each of the groups i on the circular area B and storing it in the position storage means;
  For each group i, the first position between the first circular area A and the second circular area B and corresponding to the arrangement position of the group i stored in the position storage means is the first position. The third circular region C so as not to interfere with the first circular region A and the second circular region B. i And the first circular region A, the second circular region B, and the third circular regions C at the second position close to the arrangement position of the group i. i So as not to interfere with the fourth region D i Means to set
  The third circular area C i For each time, the third circular area C corresponding to the arrangement position of each first set element on the first circular area A stored in the position storage means. i Each of the above positions is represented by the third circular area C i Means for calculating the position of each first set element above and storing it in the position storage means;
  The fourth region D i For each of the fourth areas D with reference to the information in the grouping information storage means. i A plurality of second set elements belonging to the group i corresponding to, and the fourth region D according to the arrangement order determined for the specified plurality of second set elements i Means for calculating an arrangement position of each of the second set elements and storing it in the position storage means;
  For each pair of the element pair group, an arrangement position on the first circular area A for the first aggregate element forming one of the pair of the element pair group and a group forming the other of the pair of the element pair group a means for obtaining an arrangement position on the second circular area B of i from the position storage means, and drawing an element-to-group relationship arc connecting the obtained arrangement positions;
  For each element-to-element pair, the third circle region C of the first collective element forming one of the element-to-element pairs i The fourth region D of the second set element forming the other of the arrangement position and the other element-to-element pair i An arrangement position above, and a means for drawing an element-to-element relation arc connecting the obtained arrangement positions;
  Arrangement position on the first circular area A of each first set element stored in the position storage means, arrangement position on the second circular area B of each group i, each first Said third circular region C of the set element i Arrangement position above, and the fourth region D of each second set element i Means for drawing a node at each of the above placement positions,
  Program to function as.

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