JPH09114859A - Information presenting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To grasp entire information even in spite of a large amount of incoming information by graphically displaying the distribution density of information elements on a two-dimensional flat surface. SOLUTION: An information elements set holding part 11 holds the set of the information elements. A two-dimensional flat surface map part 12 calculates the coordinate of the two-dimensional flat surface with respect to each information request of the information element set. A two-dimensional flat surface holding part 13 stores the coordinate of the information elements calculated by the two-dimensional flat surface map part 12 and the address of the information elements by coordinating with each other. An area indicating part 14 specifies an optional partial area in the two-dimensional flat surface stored in the two-dimensional flat surface holding part 13. A distributed situation calculation part 17 calculates the distributed situation of the information elements in the area specified by the area indicating part 14. A display 19 graphically displays the distributed situation calculated by the distributed situation calculation part 17. Picture display can be constituted so as to display the distribution density of cells by gradation or contour lines.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information presenting device for visualizing an information group in an image such as a map and for grasping the outline of the entire information group.

[0002]

2. Description of the Related Art For example, the following references can be cited as documents disclosing conventional techniques.

(1) Japanese Patent Laid-Open No. 6-215036

(2) D. R. Cutting, D.I.
R. Karger, J .; O. Pedersen, and J. O. Tukey, "Scatter / Gathe
r: AC Cluster-based Approach
to Browsing Large Document
Collections ", SIGIR '92, 19
91

(3) X. Lin, D.L. Sorge
l, and G.I. Marchionini, “A Sel
f-organizing Semantic Map
forInformation Retrieva
l ", ACM SIGIR Forum, vol. Sp
ecological Issue, 1992, pp. 262-2
69

(4) G. Salton, C.I. Buck
ley, and J. Allan, “Automatic
structuring of text file
s ", Electronic Publishing,
vol. 5, 1991, pp. 1-71

(5) Okata and Imaizumi, "Computer Multidimensional Scale Construction Method" (1994-1-14), Kyoritsu Publisher

Conventionally, a method for searching for a desired information element from a large number of information element sets has been proposed. One is a method of classifying and searching a set of information elements (Reference (1)).
Alternatively, reference (2)). In this conventional technique, the information element set is represented by a fixed number of clusters, and the search is made to select several from the clusters. The classification result is displayed in text.

Further, as another conventional technique for classifying and searching a set of information elements, a method of two-dimensionally displaying the result of classifying information has been proposed (the method of Lin et al. Described in Document (3)). It expresses the amount of relevant information in area.

Further, as another conventional technique, there is a method of classifying a set of information elements, expressing the proximity of information by a link, weighting the link, and displaying the weight (reference (4)). Described by Salton et al.).

[0010]

In the above-mentioned first conventional technique (the method described in the literature (1) or (2)), the information element set is represented by a fixed number of clusters, and the search is performed from that cluster. Since it was designed to select several clusters, it was not possible to search for clusters of any size and to search for gaps between clusters. Further, in the above-described second conventional technique (the method of Lin et al. Described in Document (3)), since the amount of information is expressed by the area, no gap is expressed and it is difficult to grasp the whole. Further, the above-mentioned third conventional technique (the method of Salton et al. Described in the literature (4)) is not suitable for seeing a group, and when a large amount of information comes, it is impossible to grasp the whole. The present invention aims to overcome these problems of the prior art. That is, it is an object of the present invention to appropriately present the distribution status of information elements so that a large amount of information can be easily grasped as a whole. Another object of the present invention is to allow a user to specify a subset of information presented as a set and easily search for desired information while performing narrowing down.

[0011]

The information presenting apparatus of the present invention calculates the coordinates of a two-dimensional plane for each information element of the information element set, and an information element set holding means for holding a set of information elements. Stored in the two-dimensional plane holding means, and two-dimensional plane holding means for storing the coordinates of the information element calculated by the two-dimensional plane mapping means and the address of the information element in association with each other. Area specifying means for specifying an arbitrary partial area of the two-dimensional plane, calculating means for calculating the distribution status of the information elements in the area specified by the area specifying means, and distribution status calculated by the calculating means are displayed. It has a basic feature that the display means is provided.

In the above structure, the information element held in the information element set holding means generally has n attributes and constitutes an n-dimensional space. The two-dimensional plane map means maps this information element set onto a two-dimensional plane. That is, the coordinates on the two-dimensional plane are calculated. The calculation result is held in the two-dimensional plane holding means. With respect to the two-dimensional plane held by the two-dimensional plane holding unit, the distribution state calculation unit first calculates the distribution state of the information elements for the entire area. For example, the entire area is divided into meshes, and the number of information elements in the area (cell) of each unit divided into the meshes is obtained. The display information generation means generates information for display based on the obtained information indicating the distribution status and displays it on the display means. In this first display, the entire area of the two-dimensional plane held by the two-dimensional plane holding means is displayed. Next, the user designates a desired partial area by using the area designating means while looking at the displayed image. The distribution status calculation means, in turn, calculates the distribution status for the designated partial area in the two-dimensional plane held by the two-dimensional plane holding means, and the result is displayed on the display means via the display information generating means. . In addition, specify the area for this display area,
Calculate and display distribution status. By repeating such an operation, the user can narrow down the area and continue searching for a desired information element while grasping the overall outline. Therefore, according to the present invention, the user can obtain desired information without special knowledge or know-how of information retrieval.

In addition to the configuration having the above-mentioned basic features, the information presenting apparatus of the present invention has a distribution status of information elements in a certain fixed area and a distribution status of information elements in a newly set area. An interpolating means for interpolating between the two is provided, and the display means generates a plurality of images which display each distribution state calculated by the calculating means and interpolated by the interpolating means, and sequentially displays them. And Thus, when the area is designated, it is possible to zoom in from the current display state to the new display state.

In addition to the structure having the above-mentioned basic features, the information presenting apparatus of the present invention has a history holding means for holding the history of images generated by the display means, and a history holding means. It is characterized in that a specifying means for specifying an image is provided, and the display means displays the image when the history image is specified by the specifying means. According to this, since the history can be held and the operation can be returned to an arbitrary stage, more flexible information element search can be performed.

In addition, the information presenting apparatus of the present invention has the above-mentioned basic characteristics, and an information element designating means for designating an information element in an image showing the distribution status displayed on the display means, and an information element. Read means for reading the contents of the information element designated by the designating means from the information element set holding means, and the display means, when the information element is designated by the information element designating means, is read by the reading means. It is characterized by displaying the contents of information elements. This allows the user to select the desired information and view the contents on the two-dimensional plane map of the related information.

Further, the information presentation apparatus of the present invention maps the information element set to a two-dimensional plane each time the information element set is input, and the information element set holding means for holding the information element set. Two-dimensional plane map means for obtaining the coordinates of the information element, two-dimensional plane holding means for storing the coordinates of the information element obtained by the two-dimensional plane map means and the address of the information element in association with each other, and the two-dimensional plane. Calculation means for calculating the distribution status of the information elements held in the holding means,
Display means for displaying the distribution status calculated by the calculating means, area designating means for designating an arbitrary partial area of the displayed two-dimensional plane, and information element corresponding to the area designated by the area designating means. A region changing means for reading the information element group in the set holding means and inputting it to the two-dimensional plane map means as a new information element set is provided. The entire information element set held in the information element set holding means is first given to the two-dimensional plane map means, and the two-dimensional plane map calculates the coordinates of the information elements on the two-dimensional plane, and the result is two-dimensional. It is held by the plane holding means. The distribution status calculation means calculates the distribution status of all the information elements held by the two-dimensional plane holding means. Based on the result, the display information generation means generates the information for display and displays it on the display means. In this first display,
The entire area of the information element set held in the information element set holding means is mapped onto a two-dimensional plane and displayed.
Next, the user designates a desired partial area by using the area designating means while looking at the displayed image. Then, the partial information element group held in the information element set holding means corresponding to the designated area is input to the two-dimensional plane map means as a new information element set. The two-dimensional plane map means calculates a mapping of the input information element set onto a two-dimensional plane. The distribution status calculation means calculates the distribution status from the obtained result, and the result is displayed on the display means via the display information generation means. Further, an area is designated also for this display area, and the information element set belonging to the area is mapped onto a two-dimensional plane and the distribution status is calculated and displayed. By repeating such an operation, the user can narrow down the area and continue searching for a desired information element while grasping the overall outline. Therefore, according to the present invention, the user can obtain desired information without special knowledge or know-how of information retrieval.

[0017]

【Example】

(Embodiment 1) FIG. 1 shows the configuration of an information presentation apparatus according to Embodiment 1 of the present invention. This information presentation device includes an information element set holding unit 11 that holds a set of information elements, a two-dimensional plane map unit 12 that calculates coordinates of a two-dimensional plane for each information element of the information element set, and its two-dimensional shape. A two-dimensional plane holding unit 13 that stores the coordinates of the information element calculated by the plane map unit 12 and the address of the information element in association with each other, and an arbitrary portion of the two-dimensional plane stored in the two-dimensional plane holding unit 13. An area designating section 14 for designating an area and coordinates of information elements of the area designated by the area designating section 14 are read from the two-dimensional plane holding section 13 and the area holding section 16 is instructed to hold the area as a new display area. A display area changing unit 15,
A distribution status calculation unit 17 that calculates the distribution status of information elements in the area held by the area holding unit 16 and information for display based on the information about the distribution status calculated by the distribution status calculation unit 17 Display information generation unit 1
8 and a display device 19 for graphically displaying the display information generated by the display information generating unit 18.

The information element set holding unit 11 holds a set of information consisting of information elements. The information element held is a unit of arbitrary information such as a newspaper article or one record in a database. Further, the information element has various attributes, and values are given to these attributes. The value of that attribute is basically a number. When the information element is represented by a character string, etc., it is digitized by some method. When digitizing the values, it is desirable to give the ones that are numerically close. For example, for attributes relating to color, there are three attributes of RGB, or three attributes of hue, saturation, and lightness.
The value of one attribute is given as the attribute value. Calculations can be performed on the values of such information elements.

Further, the similarity or distance between the information elements can be obtained from the attribute value of the information element. Various methods are known for obtaining the degree of similarity when the degree of similarity between information elements is used, and the method may be selected from the methods and used.

The two-dimensional plane map unit 12 calculates the coordinates on the two-dimensional plane when each information element of the information element set is projected on the two-dimensional plane. The n attributes of each information element form an n-dimensional space. When n-dimensional is projected on a two-dimensional plane, the coordinates on the projected plane differ depending on the projection direction. It is preferable that the projection method (projection direction) can be arbitrarily selected. Two-dimensional plane map section 1
The coordinate of each information element of the information element set obtained by 2 is 2
It is held by the three-dimensional plane holding unit 13. Two-dimensional plane holding unit 1
3 stores the address to the information element in association with the coordinates on the plane.

The area designating section 14 designates a partial area of a two-dimensional plane. Specifically, the instruction is 2 according to the contents stored in the area holding unit 16 on the display screen of the display device 19.
A two-dimensional plane is displayed, and the area on the screen is designated by the user by the pointing device by designating two points on the diagonal of the quadrangle. That is, the upper left point is designated by the pointing device and dragged to the lower right point to designate the rectangular area. Here, it is assumed that the aspect ratio of the designated area is maintained. Note that the magnification rate may be fixed or can be specified, and only one point (either the center or the four corners) of the rectangular area may be designated, and the area determined by the magnification rate and the designated point may be determined. Good.

The display area changing unit 15 supplies the data of the two-dimensional plane of the area designated by the area designating unit 14 to the area holding unit 16. For this reason, since the area newly designated by the area designating unit 14 is designated on the display screen, the designated area of which part of the area of the original projection plane held by the two-dimensional plane holding unit 13 is determined. Calculate whether to hit the area. The area held by the two-dimensional plane holding unit 13 is normalized so that the entire initial plane is distributed to 0 to 1 on the x axis and the y axis, respectively, while the entire display screen is 400 × 400 pixels, for example. Since the area specified on the display screen is, for example, x: 20-140,
If y: 140-260, then this is x: 20/40 in the initial plane held by the two-dimensional plane holding unit.
0-140 / 400, y: 140 / 400-260 / 4
00. The data of the designated area in the two-dimensional plane held in the two-dimensional plane holding section 13 determined based on the calculation result is transferred to the area holding section 16. The area holding unit 16 holds the two-dimensional plane information of the information element held in the transferred two-dimensional plane holding unit 13.

The distribution status calculation unit 17 includes the area designating unit 1
The distribution status of the information elements in the area specified by No. 4 and held in the area holding unit 16 is calculated. In this embodiment, the display screen is divided into meshes and the number of information elements in each cell divided by the meshes is used to represent the distribution status. As the number of divisions, an appropriate number is selected according to the number of information elements contained in the whole, the size and resolution of the display screen. For the first mesh division for the initial screen where no area is specified, the total number of information elements is 10,000 here.
It was decided that the number of information elements in one cell should not exceed 100 when dividing into cases. As an example of division, the entire display screen is 400 × 4 as described above.
When it is set to 00 pixels, each axis is divided into 50 and one cell has 8 × 8 pixels. Since the number of information items displayed in the subsequent division after the area is specified for the initial screen is small, set a certain criterion to increase the mesh size so that the difference in the number of information items does not become too small. To do. For example, one cell has 20 × 20 pixels. Here, a method of fixing the same size may be adopted.

The display information generation unit 18 performs processing for displaying the distribution status. The maximum number and the minimum number of each cell of the newly given mesh are obtained, and the range of the difference between the maximum number and the minimum number (hereinafter referred to as the number difference) is divided into several steps to determine the concentration step. The size of the step changes according to the size of the range of the number difference,
About 1/5 to 1/10 of the difference in the number of pieces is suitable, and about 1 significant digit is appropriate. For example, if the number difference range is 38, then 4 to 8
Take the steps around. If the number difference is 723, 7
One significant digit between 80 and 90 between 2.3 and 144
Will be either 00. In this way, the concentration of each cell is determined. Note that this is just a guideline, and it is possible to select another method. For example, using a logarithmic scale is also effective depending on the distribution method. Further, the display information generation unit 18 assigns a display for visibly identifying the density of each cell obtained as described above. That is, the color is made to correspond to the information density (the number of information) levels in each cell and displayed on the display device. For example, when displaying the density level of 10, the density is displayed for each color. For example, the display color of the display screen is assigned to the density levels such as density level 1: white, density level 2: light yellow, density level 3: yellow, density level 4: orange, and so on. Display device 19
Displays the display information generated by the display information generation unit 18.

FIG. 2A shows an example of the above display, in which five levels of color (indicated by black and white shading in the figure are shown for a cell of a mesh in which each axis of a screen of 400 × 400 pixels is divided into 10). It has been assigned and displayed.
In this example, a designated area is shown, and the coordinate range of the designated area is x: 20-140, y: 140.
It is -260.

The information density level may be displayed not only by different colors but also by different patterns or by a single gray scale display. The mesh division number and the number difference are linked. That is, the relationship between the maximum number and the minimum number decreases as the number of mesh divisions increases. In this embodiment, the calculation is performed automatically, but the user may specify either one and calculate the other.

(Second Embodiment: Label Display and Display) In the second embodiment, a label generator 20 (shown by a broken line in FIG. 1) is added to the configuration of the first embodiment, and the label is displayed on the screen. Is also displayed. Here, it is assumed that the label generation unit 20 attaches a label to the place showing the maximum density. The maximum density is in any cell where the density (the number of information elements included in a cell) of a certain cell (partial area) is the surrounding (4 in the upper, lower, left, right, or 8 in the upper right, including those adjacent in 45 degree units). Say greater than. In this case, labels may be attached at intervals of one cell, and the label intervals may be too narrow depending on the relationship between the label size and the cell size. In this case, the maximum restriction may be further tightened, and the restriction may be made such that there is no case where the density is higher than the target cell in the peripheral plus / minus n range. Further, not only the condition of the maximum value but also a constraint that the concentration is 10% or more higher than that of the surrounding area may be set.

After determining the cell having the maximum density, the label generating section 20 extracts the information of the information element in the cell from the information element set holding section 11 and uses it as a label. As an example of a label generation method, a method of using a title when an information element has a title will be described. Here, one piece of information is randomly selected from the cell showing the maximum of the concentration, and the title is used. If there is no title, the most identifiable attribute will be used. When the grades of all students are used as information elements, the names of the students can be used as labels. When the two axes of the two-dimensional plane onto which the n-dimensional space is projected are close to the axes of the original dimension, those values can be used for the label. It is also possible to select other axes. For example, it is also possible to select the one with the smallest variation by looking at the values of the other axes of the element in that cell, and use "axis name (attribute name) = its average value" as the label.

(Third Embodiment: Determination of Coordinates of Two-Dimensional Plane Based on Similarity) In the third embodiment, the similarity between information elements is calculated from the attribute value in the first or second embodiment, and the information element The coordinates in the two-dimensional plane are determined according to the similarity of. The degree of similarity between information elements is given to the information elements stored in the information element set holding unit 11 in advance. This similarity may be given by human judgment, but it may be automatically given.

As a method of automatically giving a similarity between information elements, a conventionally known method may be used. For example,
G. FIG. Salton, "Automatic Text P
processing "Addison-Wesley
(1989) (reference (6)) has a similarity calculation method using a word vector. This considers a vector space in which each word of the vocabulary used in a certain document set has one dimension. For a certain document or text information, a vector having the frequency of a word used therein (or represented by 1 if present in the document and represented by 0 if not present) as an element of the vector is given. When two documents are considered, each vector is normalized and the inner product is taken to obtain the similarity of these vectors.

It is desirable that the method of calculating the degree of similarity can be changed. One method is to change the weighting for each word when calculating the dot product of the vectors. Several sets are defined in which the important words and their weights are defined, one set is selected, and the word frequency in the text is multiplied by the weight. The weight setting is changed according to the viewpoint. Also, the weight can be changed depending on the position in the sentence. For example, the elements in the main clause can be heavily weighted and the elements in the sub-sentence can be light. Also,
The abstract structure and conclusion part can be weighted by using the logical structure of the document.

The two-dimensional plane map section 12 projects these information elements onto a two-dimensional plane. This projection is called attachment, and there is the Kruskal method (the second method in the above-mentioned reference (5)).
chapter). As a result, the coordinates on the two-dimensional plane are determined. The subsequent processing is the same as in the first embodiment.

In the second embodiment, a method is used in which one piece of information is randomly selected from the cell showing the maximum density and the title is used as the label. In the present embodiment using the word frequency, another label is generated. Method can be used. The method uses the word frequency for label generation. Label the most frequent individual word in the cell. Alternatively, the top few words are used as labels. In addition,
In the case of simple frequency, the same word may appear in many labels displayed as the filtering progresses. tf ・ i
This can be avoided by using the df product. tf is the word frequency. idf (inverted docu
mentfrequency) is log, where N is the number of elements in the entire set and df is the frequency of documents having that word.
It is represented by (N / df) (reference (6)).

(Embodiment 4: Contour line display) In the first embodiment, the screen display is configured to display the distribution density of cells by shading, but in the fourth embodiment, the distribution density of cells is displayed by contour lines. Is. For example, as shown in FIG. 2B, the display screen is one in which contour lines of density are drawn and the inside thereof is represented by shading of colors. The density of each cell is calculated as a contour line assuming that the density value is at the center of the cell. FIG. 2C is a diagram for explaining a method of calculating contour lines. The density value at the position where the contour line is drawn, that is, the boundary, is determined so that the maximum density and the minimum density of the cell are divided by appropriate steps. This is the same as when determining the cell boundaries in the case of the grayscale display in the first embodiment. A contour line is calculated when the density difference from the density of the adjacent cell exceeds the boundary. As a neighboring cell, a boundary point, that is, a contour line position, is calculated between the neighboring cells in four or eight directions from the cell of interest. FIG. 2C shows the case of four directions. In the calculation of the boundary point, linear interpolation is performed between the centers of two adjacent cells, and the point exceeding the boundary value is set as the boundary point.
In the example of FIG. 2C, the boundary value is 80. The boundary points thus obtained are sequentially connected to form a contour line. It may be connected as a Bezier curve when connecting points. Between contour lines, fill with a color or pattern according to the density.

(Fifth Embodiment: Zoom In) In the fifth embodiment, the display information generating section 18 and the display device 19 are modified so that the screen display in the first embodiment has the effect of zooming in. That is, in addition to the configuration of the first embodiment, the display information generation unit 18 sequentially changes the image expressing the distribution density of the elements of a certain fixed area on the two-dimensional plane designated by the area designating unit 14. A plurality of intermediate images are generated, and the display device 19 is configured to sequentially display the generated images. This allows the effect of zooming in. Therefore, a plurality of display buffers IB (0) to IB (9) are prepared in the display information generation unit 18 of FIG. 1 (not shown). It is assumed that the screen currently displayed is stored in the display buffer IB (0). The image finally created in the first embodiment is stored in the display buffer IB (9). Further, an interpolator (not shown) is provided to generate a plurality of intermediate images between the display buffers IB (0) and IB (9).

Here, as an example, a case where the interpolation section is configured to perform two-step interpolation will be described. The two-step interpolation includes a display range interpolation and a grayscale display interpolation. In the interpolation of the display range, first, the area given by the area designating unit 14 is expanded to the entire display area of the display device. In this example, the IB is used as a display buffer for interpolation of the display range.
(0) to IB (4) are used. These share the display buffer IB (0) as a base layer. The base layer is a portion excluding the designated area (portion indicating the area) in the grayscale display shown in FIG. Part of the designated area is placed on the upper layer, and the base layer is hidden in sequence while expanding. That is, in FIG. 2A, the upper left corner (20, 260) of the designated area spreads toward the upper left corner (0, 400) of the display area, and the upper right corner (140, 260) of the designated area becomes the display area. Toward the upper right corner (400, 400) of the designated area, the lower right corner of the designated area (140, 140) extends toward the lower right corner of the display area (400, 0), and the lower left corner of the designated area. (20, 140) spreads toward the lower left corner (0, 0) of the display area. The region has an initial value (x0, y
0) and the final value is (x4, y4), it can be calculated by x (i) = x0 + i * (x4-x0) / 4 y (i) = y0 + i * (y4-y0) / 4. The upper left corner has an initial value x0 = 20, y
Since 0 = 260, the final value x4 = 0, and y4 = 400, interpolating the middle stage, (20, 260),
(15,295), (10,330), (5,36)
5) and (0, 400). Similarly, similar calculations may be performed for the other three corners. The size is interpolated as follows. For enlargement, here, a method of simply enlarging a figure may be adopted. 120 * 120, 190 * 190, 260 * 260, 3
30 * 330, 400 * 400

Next, the gradation display is interpolated. The area expanded as described above maintains the density of the initial screen. Display buffers IB (5) to IB (8) are used as buffers for holding the grayscale display interpolation result.
When changing the density of the initial screen to the density of the final screen held in the display buffer IB (9), interpolation is performed so that the density naturally changes. One simple method of this interpolation is
Interpolation is performed for each pixel. Each pixel is R
It is expressed using the three primary colors of GB. For each color, the difference between the values of the display buffers IB (4) and IB (9) is calculated and linearly interpolated to display buffers IB (5) to IB.
The value is (8). Do this for each color of every pixel. This method is also effective for the contour line display of the fourth embodiment.

Label interpolation can also use this method. In the second stage, the label on the initial screen disappears naturally, and the label on the final screen appears to appear naturally. However, in the first step, the font can be enlarged or a font of the same size can be selected. When enlarging the font, it is desirable to use the outline font.

It is also possible to change the density at the same time as expanding the display range in one step. In the interpolation in that case, the method shown in the two-step interpolation is combined to change the density simultaneously with the expansion. Morphing (Morph
ing) technique is also used to interpolate two images. The image in the display buffer thus obtained can be sequentially displayed by the display device so that the image can be smoothly changed. When making such a change, the contents of the display buffer are displayed at equal time intervals using a timer. The interval can be made user-specified.

(Sixth Embodiment: Two-Screen Display) In the sixth embodiment, when two display screens are prepared in the first embodiment and the designated area is changed on one screen, the designated area is enlarged on the other screen. It is configured so that an image is displayed, and a function for displaying the contents of the information elements in the enlarged image is added. Furthermore, the display history is retained so that the previous display can be returned. FIG. 3 shows an outline of the configuration of the sixth embodiment, which is different from the embodiment of FIG. 1 in that a configuration for the above-described function is added to the display information generation unit 38. Other configurations are almost the same as those of the first embodiment. A screen of the user interface displayed on the display device 39 is illustrated in FIG. This screen is the area designation screen 41, the next screen 42,
It includes a screen return instruction button 43, a history icon 44, and an information content display window 45.

FIG. 5 is a diagram showing the area instruction screen 41, the next screen 42 and the screen return instruction button in FIG. 4 in more detail. The area designation screen 41 is a control screen for area designation, and the result of enlarging and displaying the rectangular area 411 is the second display screen on the right side, that is, the next screen 42. In this example, in the area instruction screen 41, the detailed contents of the lower level corresponding to the rectangular area 411 designated in the area labeled “Use Computer” are displayed on the next screen 42.

In order to obtain such a display, the display information generating section 38 is provided with a display screen buffer 381 for area instruction and a display screen buffer 382 for next screen, as shown in FIG. The area designating display screen buffer 381 holds the distribution density or distribution density of the element and the label in a certain area on the two-dimensional plane, and the image representing the area given by the area designating unit 14. The next screen display screen buffer 382 displays the image obtained by calculating the distribution density of elements or the distribution density and label of only the area indicated by the area designating section 34 among the areas held by the area designating display screen buffer 381. store. The recalculation of the distribution concentration is performed by the distribution status calculation unit 37.

The display device 39 displays the images held in these two buffers. That is, the image 31 of the display screen buffer for area designation is displayed on the left screen, and the image 32 of the next screen display buffer is displayed on the right screen. Further, the user continues to search for information while repeatedly instructing a new area while looking at the display screen. In this example, the area change instruction for instructing the new area is performed by double-clicking. When double-clicking on the display screen of FIG. 5, the image on the right screen 42 moves to the left, and a new area designation screen 4 is displayed.
The image is 1. In order to do that, the display area changing unit 3
5 responds to the user's double-click instruction,
The image held in the next screen display screen buffer 382 is moved to the area designation display screen buffer 381. By displaying this on the display device 39 as a control screen, it is possible to further narrow down the designated area using this.

In the process of narrowing down the search for such information, it may be necessary to go back and change the designated area. Therefore, in this embodiment, the display information generation unit 38 is provided with a history holding unit 383 that sequentially holds the history of displayed images. An icon display image corresponding to the held image is generated, and the history icon 4 is displayed.
Displayed as 4. Further, the screen return instruction pattern 43 is displayed on the display screen of FIG. 5, and by clicking this, the screen in the previous state held in the history holding unit 383 is displayed. That is, when the screen return instruction button 43 is clicked with the mouse, the display information generation unit 38 moves the image held in the area instruction display screen buffer 381 to the next screen display screen buffer 382, and the history holding unit 38.
The image immediately before that held in No. 3 is moved to the area designation display screen buffer 381 and displayed on the display device 39. Then, in the display screen of FIG. 5, the image displayed on the control screen 41 on the left moves to the next screen on the right, and the image held in the history holding unit 383 immediately before the image moves to the left. It is displayed on the area designating screen 41, and returns to the previous state.

The screen return instruction button 43 can be used to return to the display at the stage immediately preceding the current display in the history of image display, but the history icon at an appropriate stage can be selected from the plurality of history icons 44. It is possible to return to any stage in the history by clicking with the mouse.

As the narrowing down progresses and it becomes possible to specify the document, it is necessary to make the display form suitable for it. At this point, it is important to be able to see each piece of information on the display screen, not as a group of pieces of information. FIG. 4A shows the next screen when the number of information items in the cell is one or less and the labels (in this example, the title is used as a label) 47 of the individual information elements 46 are narrowed down to such an extent It is a display example.

When one of the information elements 46 in the screen of FIG. 4B is clicked to specify, the information reading section 384 obtains the address of the specified information element, and the information element set holding section 31 is obtained from the address. Read the document contents along with the corresponding bibliographic data. Then, the display information generation unit 38 creates an information content display window 45 as shown in FIG. This content may include not only text but also graphic data such as charts and image data.

(Embodiment 7: Two-dimensional plane recalculation) In each of the embodiments described above, the display area changing unit is designated by the area designating unit based on the information held in the two-dimensional plane holding unit. The area is taken out and held in the area holding unit. On the other hand, in the seventh embodiment, instead of using a part of the area of the already mapped information element set held in the two-dimensional plane holding unit for the next display, the information element set holding is performed. 2) by reading the information element set of the specified area from the information element set holding section for each area specification
A two-dimensional plane is recalculated by giving it to the three-dimensional plane map section. FIG. 6 shows a configuration of the seventh embodiment, in which the display area changing unit 65 addresses each address in the information element set holding unit 61 of the information element group existing in the partial area of the display area designated by the area designating unit 64. Based on the address, the information element is taken out from the information element state number holding section 61 as a new information element set and given to the two-dimensional plane map section 62. The two-dimensional plane map unit 62 calculates the coordinates on the two-dimensional plane when each information element of the given information element set is projected on the two-dimensional plane as in the other embodiments. The calculated coordinates are held in the two-dimensional plane holding unit 63. Distribution status calculation unit 67 and label generation unit 60
Displays distributions and labels for the entire two-dimensional plane held in the two-dimensional plane holding unit 63, generates these display images in the display information generation unit 68, and displays them on the display device 69.

[0044]

According to the present invention, since the distribution density of information elements is graphically presented by using the shades and contour lines on a two-dimensional plane, the entire information can be displayed even when a large amount of information is received. It is possible to grasp. Further, according to the present invention, a user can easily specify desired subsets of information presented as a set and search for desired information while performing narrowing down. Therefore, the present invention can support obtaining desired information without special knowledge or know-how of information retrieval.

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic configuration of a first embodiment.

FIG. 2A is a grayscale display example of a two-dimensional plane, FIG. 2B is a contour line display example, and FIG. 2C is a diagram showing how to obtain contour lines.

FIG. 3 is a diagram showing a schematic configuration of a sixth embodiment.

FIG. 4A is a diagram showing an example of a screen layout displayed in the case of Example 6, and FIG. 4B is a diagram showing an example of a next screen display.

FIG. 5 is a diagram showing an example of a region designation screen and a next screen in the sixth embodiment.

FIG. 6 is a diagram showing a schematic configuration of a seventh embodiment.

[Explanation of symbols]

11 ... Information element set holding unit, 12 ... Two-dimensional plane map unit, 13 ... Two-dimensional plane holding unit, 14 ... Region designating unit, 15
... display area changing unit, 16 ... area holding unit, 17 ... distribution status calculating unit, 18 ... display information generating unit, 19 ... display device, 20
... Label generator.

Claims (5)

[Claims] 1. An information element set holding means for holding a set of information elements, a two-dimensional plane map means for calculating coordinates of a two-dimensional plane for each information element of the information element set, and the two-dimensional plane map means. The coordinates of the information element calculated by the above and the address of the information element are stored in association with each other. 2
Dimensional plane holding means, area designating means for designating an arbitrary partial area of the two-dimensional plane stored in the two-dimensional plane holding means, and a distribution state of information elements in the area designated by the area designating means is calculated. An information presenting apparatus comprising: a calculation unit and a display unit that displays the distribution status calculated by the calculation unit. 2. An information element set holding means for holding a set of information elements, a two-dimensional plane map means for calculating coordinates of a two-dimensional plane for each information element of the information element set, and the two-dimensional plane map means. The coordinates of the information element calculated by the above and the address of the information element are stored in association with each other. 2
Dimensional plane holding means, area designating means for designating an arbitrary partial area of the two-dimensional plane stored in the two-dimensional plane holding means, and a distribution state of information elements in the area designated by the area designating means is calculated. A calculation means, an interpolation means for interpolating between the distribution status of the information elements in a certain area and the distribution status of the information elements in the newly set area, and the calculation means for calculating and interpolating by the interpolation means. An information presenting apparatus comprising: a display unit configured to generate a plurality of images displaying each distribution state and sequentially display the images. 3. An information element set holding means for holding a set of information elements, a two-dimensional plane map means for calculating coordinates of a two-dimensional plane for each information element of the information element set, and the two-dimensional plane map means. The coordinates of the information element calculated by the above and the address of the information element are stored in association with each other. 2
Dimensional plane holding means, area designating means for designating an arbitrary partial area of the two-dimensional plane stored in the two-dimensional plane holding means, and a distribution state of information elements in the area designated by the area designating means is calculated. A calculating means, a display means for generating an image displaying the distribution status calculated by the calculating means, and displaying the image; a history holding means for holding the history of the image generated by the display means; and a history holding means. An information presenting apparatus, comprising: a designating unit that designates the held image, wherein the display unit displays the image when the history image is designated by the designating unit. 4. An information element set holding means for holding a set of information elements, a two-dimensional plane map means for calculating coordinates of a two-dimensional plane for each information element of the information element set, and the two-dimensional plane map means. The coordinates of the information element calculated by the above and the address of the information element are stored in association with each other. 2
Dimensional plane holding means, area designating means for designating an arbitrary partial area of the two-dimensional plane stored in the two-dimensional plane holding means, and a distribution state of information elements in the area designated by the area designating means is calculated. Calculation means, display means for displaying the distribution status calculated by the calculation means, information element designating means for designating an information element in the image representing the distribution status displayed on the display means, and designation by the information element designating means Read means for reading the content of the specified information element from the information element set holding means, the display means, when the information element is designated by the information element designating means, the content of the information element read by the reading means. An information presentation device characterized by displaying. 5. An information element set holding means for holding a set of information elements, and each time an information element set is input, the information element set is mapped onto a two-dimensional plane to obtain the coordinates of each information element. Dimensional plane map means, two-dimensional plane holding means for storing the coordinates of the information element obtained by the two-dimensional plane map means and the address of the information element in association with each other, and information held in the two-dimensional plane holding means Calculation means for calculating the distribution status of the elements, display means for displaying the distribution status calculated by the calculation means, area designating means for designating an arbitrary partial area of the displayed two-dimensional plane, and area designating Area changing means for reading out the information element group in the information element set holding means corresponding to the area designated by the means and inputting it to the two-dimensional plane map means as a new information element set. An information presentation device characterized by the above.