JPH05205063A - Method for displaying hierarchically structured information - Google Patents

Abstract

PURPOSE:To realize efficient display by automatically deciding efficient arrangement for each hierarchy each time it is decided whether information elements are displayed or not, and recursively repeating this operation. CONSTITUTION:Search pointers are set in hierarchically structured routes by a search pointer control part 2. The search pointer shows the position of information in the hierarchical structure under processing at present. Next, relative positions between both of information are set and concerning each of information, a display information selection part 4 decides whether the information is displayed or not according to the degree of importance. Further, the search pointer control part 2 sets hierarchically structured route search pointers and decides the arrangement of all the information to be displayed. In this case, when information shown by the search pointer (assuming information A) contains information being nodes, the processing is recursively executed to that information (assuming a node X). Otherwise, the arrangement is decided by changing the size/position of the information element in the information A, and the size of a mat provided for the information A is decided from the size of an area for the information element. Finally, the arrangement is decided by an arrangement decision part 5 and displayed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information processing apparatus for storing and managing a large amount of information group having a hierarchical relationship,
The present invention relates to a method for efficiently displaying a hierarchical relationship between multiple pieces of information.

[0002]

2. Description of the Related Art Methods for managing a large amount of information such as databases and information retrieval are becoming popular. Hitherto, a method of hierarchically classifying and storing information has been widely used as an information management method. However, when the amount of information increases,
The number of layers and the number of classification items increase, and it is not possible to easily search for necessary information only by stepwise tracing from the upper layer to the lower layer. Also, when adding new information, it becomes difficult to easily determine which classification item to add.

Therefore, in order to manage a large amount of information having a hierarchical structure, the overall structure of the information space in the system is grasped by visually displaying the relationship between the information elements in the information processing system. Making it easy is effective for information management. However, when the scale of the information space becomes large, there arises a problem that the details of the entire information space cannot be displayed at once due to the physical restriction of the display screen size. On the other hand, since there is a limit to the amount of information that can be grasped by humans at the same time, there is also a limit to increasing the amount of information that can be displayed at the same time by increasing the size of the display screen and increasing the definition.

In the end, in order to grasp the large-scale information space, the user has to reconstruct the whole image in his head while sequentially walking through the subspaces. However, with the method of simply dividing the entire information space, it becomes difficult to reconstruct the whole image as the number of divisions increases. Further, a method of arranging a reduced view of the whole and an enlarged view of a part is also conventionally used, but it is difficult to say that the positioning of the enlarged part in the whole is easy to understand. That is, in logical information space visualization, simple graphic operations such as division, enlargement, and reduction are not sufficient to support the grasp of the whole image.

In order to solve such a problem, each information element in the information space is weighted and an appropriate threshold value is set for the weight so that only the information element having a weight greater than the threshold value is displayed on the screen. A method of selectively displaying highly important information by displaying it has been proposed (San-Sue: Conceptualization of Figure and its Application to Idea Generation Support, IPSJ, Human-Interface Research Group (1990)). .

As a weighting method, in the case of a hierarchical structure, weighting is performed so that the higher the information element of the hierarchy is, the lower the weight is, and the lower the information element is, the higher the weight is of the information element closer to the attentional information element. By the method of lowering the weight as the distance increases, it becomes possible to simultaneously display the detailed information around the information element of interest and the main information of the whole.

[0007]

In order to display the relationship between a large number of information elements having a hierarchical structure in an easy-to-understand manner, each information element is weighted and the important information element is selectively displayed to display the information. Efficient display is possible without being restricted by the size of the screen and the amount of information that the user can grasp at one time.

However, in order to realize the above-mentioned efficient display of the whole, a method of dynamically changing the arrangement of the display information elements is required every time the display or non-display of each information element is decided. In view of the above problems, the present invention has a plurality of information element groups having a hierarchical relationship, is provided with means for determining display or non-display by weighting each information element, and In the method of expressing the area occupied by the information element of with a recursive nested structure in which the upper information element includes, each time the display or non-display of each information element is changed, the efficiency of the displayed information element is as high as possible. It aims to automatically determine and display good placement.

[0009]

In order to achieve the above object, the present invention provides an attribute storage means for storing attributes given to individual information in a database, and a display by weighting individual information elements. Alternatively, a means for deciding non-display and a relation between those information elements for which display has been determined are shown as an inter-information element relationship diagram, and a recursive manner in which the upper information element includes the area occupied by the lower information element. And a means for deciding the arrangement on the screen for expressing in a typical nested structure, and a means for arranging the information elements on the screen according to the decided arrangement information and displaying an information element relationship diagram. It is characterized by being.

[0010]

With the above-described structure, the present invention has a plurality of information element groups having a hierarchical relationship, and is provided with means for determining display or non-display by weighting each information element, and the hierarchical relationship is defined as a lower level. In the method of expressing the area occupied by information elements in a recursive nested structure in which higher-level information elements are included, each time the display or non-display of each information element is decided, a layout that is as efficient as possible for each hierarchy is created. By automatically determining and recursively repeating this, the entire information elements can be efficiently arranged and displayed.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of the present invention. Reference numeral 1 is a database device in which the contents of each information are stored. A search pointer control unit 2 controls a search pointer indicating the position of information in the database device to be processed. An importance management unit 3 manages the importance of each piece of information stored in the database device. Reference numeral 4 denotes a display information selection unit that determines display or non-display by weighting individual information elements, and selects the display. An arrangement determining unit 5 determines the arrangement of each information on the screen so that the information selected by the display information selecting unit can be displayed as a diagram in which the relationship between the information can be understood. The determined placement information is held in the placement information holding unit 7 and used when redrawing. A display unit 6 displays each piece of information on the screen based on the arrangement determined by the arrangement determining unit 5.

The display information selecting section 4 in the arrangement determining section 5
The following method is used to determine the arrangement of each information on the screen in order to display the information selected in step 1 as a diagram that shows the relationship between the information. When expressing the hierarchical structure, the relationship between the information in the hierarchical structure is shown in FIG.
And the inclusion relation (nested structure) as shown in FIG. This replaces the hierarchical relationship of the hierarchical structure with the inclusion relationship, and the contained element is expressed by this expression so that the information of the lower layer becomes a lower set element, and the information of the upper layer includes itself. Expressed in shape.

In the information of the hierarchical structure, the hierarchical structure exists in the lower layer in the node (branch). What is called a mat is placed in such information, and it is expressed that it includes the information of the lower layer (Fig. 4). The size of this mat changes according to the number of information contained in that mat,
It expresses the range of the area required by the information in the lower layer and distinguishes it from other information in the same layer. In order to create the diagram of this inclusive relation, when a certain constituent element A is considered, the size of the constituent element A cannot be determined unless the number and size of the elements included in the constituent element A are determined. Can't decide.
Therefore, a recursive process is performed and a process for determining the placement is performed.

As a change factor when deciding the arrangement, an element such as how many columns are arranged when deciding the arrangement, and how to avoid the overlap when they are overlapped (whether to avoid to the right,
There is an element "Do you avoid it?", And these are held in the arrangement information holding unit 7. As an initial setting, the relative position when displaying each information is set from the information included in the hierarchical structure.

As means for realizing the above, there is "algorithm 1" described below. Algorithm 1 1. The search pointer controller sets the search pointer at the root of the hierarchical structure. 2. At a certain node pointed by the search pointer, the number of rows is calculated from the number of contained information.

Line to be set = [(number of information contained in node) / (number of columns to be arranged)] + 1 Note: [X] = maximum integer not exceeding X, where (line to be set) × (placement) When the number of columns to be processed> (the number of information items included in the node) is (the number of information items included in the node)-(the number of rows to be set-
1) x (number of columns to be arranged) = number of extra information, the value of (row to be set-1) is the basis of the row, and the first half of the row is the value of (extra information) Line up with. As a result, it can be arranged closer to a rectangle. 3. In order to understand the relative relationship, the X-coordinate and the Y-coordinate indicating the position of each information in the relative position holding unit in the arrangement information holding unit 7 are
The information in the 1st row and 1st column is [1,1], and the information in the 1st row and 2nd column is [1,1]
2] The value of [1, 3] is assigned to the information of the 1st row and the 3rd column, and the value of [2, 1] is assigned to the information of the 2nd row and the 1st column.

4. If the included information is for a node, the search pointer is moved to that node, and this algorithm is recursively applied from the above 2. The above operation determines the relative positions of all information. The determined relative position is held in the placement information holding unit 7 as individual information. Next, the arrangement actually displayed on the display unit 6 is determined based on the relative position between the information.

FIGS. 6 and 7 show the “algorithm 2” for determining the arrangement in a program list. From the relationship of the figures, the first half of the program list is shown in FIG. 6 and the second half is shown in FIG. There is. Algorithm 2 A node in the hierarchical structure (tentatively called node A)
In, if the node is determined to be the information displayed by the display information selection unit 4, the following processing is performed. 1. The present algorithm is recursively applied to a node A that has information elements and is a node among them. 2. The positions of all the information elements of the node A are changed. Since the above 1 is applied to the information elements that are all the nodes that the node A has, the sizes of all the information elements that the node A has are determined at this point. The position is determined based on the size of.

Regarding relative positions, if the columns are the same, they are moved to the same column. If the information elements overlap, move to the right or down according to the condition to avoid the overlap. The position is determined by the above, and the information element is moved.

With the movement of the information element, in order to determine the size of the node A, the size of the area occupied by the information element is calculated. 3. The size of the node A is changed according to the size of the area occupied by the information element. The above algorithm is used to automatically determine the placement.

The operation will be described below with reference to the case where the structure in the database has a hierarchical structure as shown in FIG. It is assumed that the display unit 6 displays the relationship between the information in the hierarchical structure as a diagram of the inclusion relationship as shown in FIG. 4 or 5. When displaying, first, the search pointer control unit sets the search pointer to the root of the hierarchical structure. This search pointer points to the position of the information within the hierarchical structure currently being processed (FIG. 2). Next, the "algorithm 1" described above is applied to the information to set the relative position between the information. Subsequently, the display information selection unit 4 determines display / non-display of each information according to its importance. Further, the search pointer control unit 2 resets the search pointer to the root of the hierarchical structure. Further, the above-mentioned "algorithm 2" is applied to information to determine the arrangement of all displayed information.

At this time, if the information pointed to by the search pointer (provisionally referred to as information A) includes information that is a node (that is, there is a further hierarchical structure in the lower layer),
Algorithm 2 is further applied to the information (provisionally set to node X), and the processing is recursively performed. Alternatively, the size and position of all the information elements of the information A are changed to determine the arrangement. Then, the size that the information A can take is determined based on the size of the area occupied by those information elements, and the size of the mat that the information A has is determined.

Finally, the information element is displayed on the display unit 6 based on the arrangement determined by the arrangement determining unit 5 by the above algorithm. By performing the above operation, automatically determining as efficient an arrangement as possible for each hierarchy, and recursively repeating this, it is possible to arrange and display all information elements efficiently. The following operations are performed when redrawing.

First, when the attribute of information is changed and the information displayed is changed, and when redrawing is performed, the display information selection unit 4
Then, the operation is started by determining display / non-display of each information according to its importance. Further, the search pointer control unit 2 resets the search pointer to the root of the hierarchical structure. Further, the above-mentioned "algorithm 2" is applied to information to determine the arrangement of all displayed information.

At this time, if the information pointed to by the search pointer (provisionally referred to as information A) includes information that is a node (that is, there is a further hierarchical structure in the lower layer),
Algorithm 2 is further applied to the information (provisionally set to node X), and the processing is recursively performed. Alternatively, the size and position of all the information elements of the information A are changed to determine the arrangement. Then, the size that the information A can take is determined based on the size of the area occupied by those information elements, and the size of the mat that the information A has is determined.

Finally, the information element is displayed on the display unit 6 based on the arrangement determined by the arrangement determining unit 5 by the above algorithm. The display form creation unit determines whether to display or not display each information along with the change of the attribute of the information, and recursively applies the “algorithm 2”. However, the placement information determined by the placement setting unit 5 and the placement information The layout information stored in the storage unit 7 is compared, and if they are the same, the layout displayed on the display unit 6 is used as it is. This operation speeds up the redrawing.

[0027]

According to the present invention, there are a plurality of information element groups having a hierarchical relationship, and a means for determining display or non-display by weighting each information element is provided,
In a method of expressing a hierarchical relationship in a recursive nested structure in which an area occupied by a lower information element is included in an upper information element, each time each display or non-display of each information element is determined, By automatically deciding the most efficient arrangement and repeating this recursively, it is possible to arrange and display all the information elements efficiently. As a result, even if the display or non-display of the information element is changed, the rearrangement can be automatically performed by adapting to the change, and it is possible to always realize efficient display.

[Brief description of drawings]

FIG. 1 is a conceptual configuration diagram of a method for displaying hierarchical structure information according to the present invention.

FIG. 2 is a conceptual diagram showing a search pointer and its movement according to the present invention.

FIG. 3 is an explanatory diagram for explaining a hierarchical structure according to the present invention.

FIG. 4 is an explanatory diagram illustrating an inclusion relation of a hierarchical structure according to the present invention.

FIG. 5 is an explanatory diagram for explaining an inclusion relation of a hierarchical structure according to the present invention.

FIG. 6 is the first half of the program list of “algorithm 2” according to the present invention.

FIG. 7 is the latter half of the program list of “algorithm 2” according to the present invention.

[Explanation of symbols]

 1 database device 2 search pointer control unit 3 importance degree management unit 4 display information selection unit 5 placement determination unit 6 display unit 7 placement information holding unit

Claims (1)

[Claims] 1. A means for storing a plurality of information elements having a hierarchical relationship, a means for giving a display or non-display attribute to each information element, and a lower-level information element occupy a hierarchical relationship. Equipped with a means for expressing a region in a recursive nested structure such that upper information elements are included, the layout of lower information elements included in it is automatically arranged so that the area of the area occupied by a certain information element is as small as possible. And a means for determining and displaying the efficient layout of the whole by recursively repeating it, and displaying the hierarchical structure information.