KR101581785B1 - 3D Biological Data Processing Method And System Thereof - Google Patents

Abstract

The present invention relates to a three dimensional biological information processing method and a system therefor. The three dimensional biological information processing method includes the following steps: a start-up screen displaying step of displaying a three dimensional body model, an input tool type selection unit, and a degree information input bar on a screen; a degree inputting step of receiving degree information that a user selected; a location inputting step of receiving designated location information by the user using the input tool on a surface of the three dimensional body model; a correspondence information displaying step of matching the designated location information and the selected degree information and displaying the same on the screen; and a storing step of storing the designated degree information and the selected location information, thereby effectively displaying and storing all kinds of biological information in the three dimensional modeling.

Description

TECHNICAL FIELD The present invention relates to a 3D biological information processing method,

Disclosure relates to a method and system for three-dimensionally expressing various types of biological information to be input by a user using three-dimensional modeling and processing the three-dimensional data into three-dimensional data.

Herein, the background art relating to the present disclosure is provided, and these are not necessarily meant to be known arts.

Figure 1 illustrates a computer-based pain assessment method as disclosed in U.S. Patent No. 8,046,241. The front and back of the human body are displayed on the screen in order to input the pain the patient is currently experiencing. The patient selects a portion of the human figure. Then go to the next screen and select a color that indicates the degree of pain. In addition, a check box for selecting the kind of pain is displayed, and the user inputs the kind of pain of the user.

 According to the information thus input, the pattern of the pain is displayed on the screen according to the information finally inputted by the patient on the next screen, and the patient is checked to see if it is correct. Through this series of input processes, they can be stored on a computer or sent to a doctor.

Biological information, such as the human body, has a variety of phenomena and causes, and expressions may be required to record accordingly. However, when a two-dimensional limited input screen is given as in the case of FIG. 1, the user can not express information as desired, and the possibility of missing or exaggerating the information is increased. Also, conversely, if there are too many choices for the presentation, it may be confusing in choosing what is the right expression for you, and you may have difficulty with proper input. In addition, there are portions where a three-dimensional position in a real three-dimensional space is difficult to express in a two-dimensional image, or even if it is expressed, it becomes unclear.

The present disclosure enables intuitive expression that corresponds to a user's own body or desired organism. In addition, the content of the input is partially automated to allow the user to quickly and easily input the characteristics of the biometric information.

This will be described later in the Specification for Enforcement of the Invention.

Herein, a general summary of the present disclosure is provided, which should not be construed as limiting the scope of the present disclosure. (Hereinafter referred to as " ).

According to an aspect of the present disclosure, there is provided an information processing apparatus including a three-dimensional body model, an input tool type selection unit and an accuracy information input bar on an initial screen display step, a degree input step of receiving degree information selected by a user, A corresponding information display step of displaying the designated position information and the selected degree information in correspondence with each other on the screen, and a storing step of storing the designated degree information and the selected position information, Dimensional biological information processing method according to the present invention.

This will be described later in the Specification for Implementation of the Invention.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing a prior art relating to a computer-based pain treating apparatus disclosed in U.S. Patent No. 8,046,241.
2 is a view showing a biological information input screen according to an embodiment of the present invention.
3 is a view showing an overlapped biological information input screen according to an embodiment of the present invention;
FIG. 4 is a diagram showing the biological information inputted on a two-dimensional plane according to an embodiment of the present invention; FIG.
Figure 5 shows a display marker for displaying biological information in accordance with one embodiment of the present invention.
6 is a diagram illustrating automatic representation of degree information according to one embodiment of the present invention.
Figure 7 illustrates a representation according to a brush in accordance with an embodiment of the present invention;

The present disclosure will now be described in detail with reference to the accompanying drawings.

2 is a diagram showing one embodiment of a biological information input method according to the present disclosure. A three-dimensional modeling (100, hereinafter referred to as a three-dimensional body model) of a living body as an object appears on the screen. One side of the modeling 100 includes an input tool type selection unit 230 for selecting a type of input tool for inputting biological information on the modeling, a degree information input bar 220 for indicating the degree of biological information intensity, . When the kind of the input tool and the degree of the intensity of the biological information are selected, the input tool 111 can directly specify the position in the three-dimensional body model and input the biological information according to the position.

Biological information relates to physiology, ecology and pathology. It refers to biological (eg, human, animal, plant, insect, carcass, etc.) such as pain, itching, fever, rash, ringworm, wound, abrasion, wound, It may be various kinds of information that may appear.

The user uses the three-dimensional body model 100 to input biological information. In order to input information on the human body, it is possible to select human body modeling for gender discrimination, and to display the related three-dimensional modeling of the organism on the screen in order to input information on animals, plants, insects, and the like.

The three-dimensional body model 100 is easily rotatable in any direction the user desires so that the user can present biological information in the correct location. In addition, it can be enlarged or reduced as necessary. Thus, the user can intuitively see the three-dimensional body model 100, thereby enhancing the precision of display. In addition, the user can confirm the part to be expressed by himself / herself through the three-dimensional body model 100, and can make an input screen so that the input is easy.

In addition, if the user places the input tool 111 on any portion of the three-dimensional body model surface 100, the system can automatically rotate the three-dimensional body model such that the portion is the center of the screen. For example, when the input tool 111 is moved to the dorsal surface on the screen displaying the front side of the three-dimensional body model 100, the three-dimensional body model 100 is automatically rotated .

After the input screen is confirmed through rotation and zooming, the user selects how to input the biological information. The type of the input tool is selected. There may be a display marker mode, a brush mode and an eraser mode.

In the display marker 111 mode, it is possible to determine the range and shape of the biological information to be displayed. In order to make the area display unit on the three-dimensional biological model 100, the display marker 111 has a shape of a circle or an ellipse. The user can arbitrarily designate the length of the width and the height diameter orthogonal to the center of the ellipse by using the input bars 211 and 212 so that the size and shape of the display marker 111 can be varied. Also, there may be a rotation input bar 213 for rotating the display marker 111 with respect to the center. According to another embodiment, the shape of the display marker 111 to be displayed may be specified in various polygonal shapes such as a triangle, a square, etc., according to the user's convenience.

On the other hand, in displaying the biological information on the three-dimensional body model using the display marker 111, it may be necessary to express the local region only with ease while grasping the position of the display marker 111. [ This is because when the size of the screen representing the three-dimensional body model 100 is small, the difference in hue between the color tone of the three-dimensional body model 100 and the display marker 111 is not large or the size of the display marker 111 is small It will be the case where it becomes difficult to estimate the position. 5, in order to solve this problem, a trapezoidal conical column whose area decreases as the display marker 111 approaches the surface from a certain distance on the surface of the three-dimensional body model 100 is made, (511, 512). In this embodiment, a plurality of straight lines are used, but various patterns can be used. The size of the area display portion of the display marker 111 on the three-dimensional body model can be adjusted by adjusting the lateral tilt of the trapezoidal conical column using the conical tilt input bar 214. [ When the inclination is minimized, the area display unit 512 displayed by the marker is minimized. When the inclination is close to 90 degrees, the display marker approaches the cylindrical shape, and the area display unit 511 is formed to the original designated size to display the biological information .

The input tool may be in brush mode. In the brush mode, the biological information is displayed at the position where the user places the brush and inputs the display command.

Also, the input tool may be in eraser mode. If the user thinks that the inputted display information is inappropriate, he can erase only the desired portion. As many different representations as possible are possible, the biological information displayed in the three-dimensional body model can be quite different from the first one. In the eraser mode, the size, shape, and orientation of the eraser can be changed using the size and shape adjustment options 211 and 212 of the display marker 111 and the orientation option 213 thereof.

Biological information can have information about the intensity. For example, in the case of pain, it is expressed in several steps, from no pain to a very sickness, divided into about 10 sections. This may be expressed as a visual analog scale (VAS). The user can adjust the degree information input bar 220 displayed on the screen to input the degree of intensity of the biological information. The degree-of-information input bar 220 is composed of a spectrum of colors, and is defined such that intensity gradually increases from left to right. The user can select more than one intensity. According to another embodiment described with reference to FIG. 6, the color spectrum of the degree information input bars 611 and 621 may be expressed by a palette composed of ten levels of colors according to pain criteria.

The input tool is a display marker 111, and two pieces of information can be input to the accuracy information input bar 220. If necessary, one or more pieces of information may be input, but in the present embodiment, two pieces of information are input. These two values mean the maximum value and the minimum value in a certain range, or they may be the center and the outer of the area to be displayed by the display marker 111. For example, two values are selected on the degree information input bar 220 and the width input bar 211, the height input bar 212, the rotation input bar 213 and then determines the positions of the display markers 111 on the three-dimensional body model 100, the two values become maximum and minimum values at specific positions within the area of the display marker 111, respectively. Depending on the degree of expression of the user, the maximum value may be the center of the inside of the circular area, the minimum value may be the outermost angle, or vice versa (612 and 613 in FIG. 6). When the position corresponding to the maximum value and the minimum value is determined within the area of the display marker 111, the degree information values along the positions excluding the maximum and minimum values are automatically generated at the corresponding positions do. For example, when the first color and the 16th color are selected from the left side of the degree information input bar 220, the first color and the 16th color become the center and the outermost values respectively, will be. The gradual change in intensity will also be represented by the color corresponding to each value and will be displayed at the corresponding position on the screen.

A preview unit 221 may be provided on the side of the degree information input bar 220. When the maximum and minimum values are determined, it is possible to know in advance how the color distribution will appear in the area of the display marker 111 from the center to the outside and vice versa. In addition, it is possible to grasp the point of the color selected at the maximum or minimum with respect to the total size of the color, and to be reflected in the display by the preview and display marker 111.

FIG. 6 shows an embodiment in which the degree information input bars 611 and 621 have 10 levels. The circular area display portion 612 can be displayed by selecting a maximum value in the center portion and a minimum value in the outside portion or vice versa. When the value corresponding to the center portion and the value of the outermost edge are determined, values in the middle on the input bars 611 and 621 are also determined to be displayed within the area of the display marker 111 as well. For example, when the first color and the fifth color are selected from the left side of the input bars 611 and 621, the first color and the fifth color are the center and the outermost values, respectively, and the second and fourth colors are intermediate values will be. This is in order to express in various ways according to the case of actual biological information. In addition, the user may adjust the position of the color selected on the color palette of the degree information input bar 621 to create an area display unit 622 in which the color representation ratio is displayed small.

According to another embodiment, more than two values can be designated in the input bars 611 and 621, and the display can be made only in colors corresponding to the values. For example, when the second color and the sixth color are selected from the left side of the input bars 611 and 621, the second and sixth colors are displayed in the area shape of the display marker 111 in accordance with the ratio selected by the user Will be.

FIG. 7 shows a method of displaying when a user selects the brush mode and only one color is selected in the degree information input bar 622. FIG. Basically, when the user designates display within the area display unit 701 for the first time, the distribution (display) of non-uniform colors is made. When the user desires to express the entirety of the area display unit 701 in the same color, the same portion is superimposed and designated several times (FIG. 7 (b)) so that the area display unit 701) can be made to have the same color representation. Then, another color may be selected as shown in Fig. 7 (c), and then the overcoat may be applied. In this way, it is possible to display biological information that may appear as multiple as in a skin disease in which a large number of spots are present in the local region.

3 is a diagram showing a case where a user has biological information input at a position where at least part of the user is overlapped. When the first marker 312 and the second marker 313 are displayed on the three-dimensional body model by the marker marker 111 and they are displayed in a superimposed manner, the outer markers of the first marker and the second marker are automatically linked do. This allows the first display 312 and the second display 313 to be represented as one biological information. This is because the user can not find an appropriate input method due to the variety of positions of the pain, so that the user can display and supplement the displayed information. This allows the localization of the organism model to be expressed in three dimensions in the form of a group of clusters with the epicenter of two or more biological phenomena (eg, pain). Even if the user adds the third display 314 in a superimposed manner, the same function can be performed.

The user can at least partially overlap the expression by the display marker 111 and the expression by the brush on the three-dimensional body model 100, if necessary. In this case, the intensity of the final degree information is applied to the overlapping positions. If necessary, the average or initial information of the degree information may be maintained at the position.

The information displayed on the screen is also stored in the system as data. The position information indicating the position on the three-dimensional body model, the degree information indicating the intensity of the biological information at the position, and the input time are stored in the system as one data set. In the present embodiment, the position information is information of a three-axis orthogonal coordinate system, and the intensity of the biological information may be intensity of pain.

If necessary, the user can additionally input user description information such as types of biological information, depth information of biological information, and the like, and all values are stored as one data set. A large number of data sets are automatically generated in the region of the three-dimensional body model indicated by the input tool as having biological information.

The plurality of data sets can be made to include area information according to the center position of the display marker 111. [ For example, in one data set, the input date, the surface inclination of the cylindrical markers, the diameter of the ellipse width, the height of the ellipse, the center / outer degree information, the three-dimensional coordinates of the marker center, The position of the point, the degree information of the minimum unit point, and the like. It is possible to expand the contents of the data as needed.

The system can send a collection of this data to the outside in the form of a file with a certain format if the user needs it. The format of the file may be in the form of a biological information data standard defined by an external agency, or it may be its own file format. In addition, you will be able to make output compatible with the file formats of commonly used spreadsheet programs such as Excel, so that they can be handled in a common database.

4 is a screen showing data sets on a two-dimensional plane 410 according to the present disclosure. The position on the surface of the three-dimensional body model is extended to be displayed on the two-dimensional screen. If you spread the data on one plane and examine the flow of data over time, you might find a certain pattern. This allows biometric information of the data set already entered to the user to be used to provide new perspectives on the phenomenon and useful directions and ideas in data processing and analysis.

Such a three-dimensional biological information processing method can be implemented in a computer system. If it meets the purpose of improving user accessibility and simplifying input, it can be implemented in various mobile devices such as personal computer, smart phone, tablet, PC, pad. In addition, the type of the drive system is not limited. For this purpose, it may be stored in the memory of each information device and implemented in the form of an application in order to execute the functions described above.

Hereinafter, various embodiments of the present disclosure will be described.

(1) A three-dimensional biological information processing method, comprising the steps of: displaying a three-dimensional body model, an input tool type selection unit and an accuracy information input bar on a screen, an input step of accepting degree information selected by a user, A position information input step of receiving the position information designated by the input tool on the surface of the three-dimensional body model; a corresponding information display step of displaying the specified position information and the selected degree information on the screen in correspondence with each other; And a storage step of storing the three-dimensional biological information.

(2) The three-dimensional biological information processing method according to any one of (1) to (3), wherein the input tool has a constant area deformable by the user, and the area display unit is generated in the corresponding information display step.

(3) before the corresponding information display step, the selected degree information has a highest value and a lowest value, so that the degree information of change between them is automatically selected in the degree information selection bar. Dimensional biological information processing method.

(4) a step of inputting additional positional information and degree-of-detail information input by the user after the storing step, and when the area display unit by the additional positional information and the area display unit by the previous positional information are overlapped at least partially, And displaying the three-dimensional biological information.

(5) A method for processing a three-dimensional biological information, further comprising the step of accepting and storing the type of biological information from the user prior to the storing step.

(6) The three-dimensional biological information processing method, wherein the position information includes three-dimensional coordinate information, and in the storing step, a data set including a recording time is created by processing.

(7) the step of inputting the position further comprises the step of causing the three-dimensional body model to rotate according to the position of the input tool on the three-dimensional body model.

(8) After the storing step, displaying the one or more stored degree information and the position information on the two-axis plane when the user designates it.

(9) In the step of inputting the position, further step of inputting user description information.

(10) a display module for displaying a three-dimensional body model capable of rotating with multiple axes and an input tool for inputting accuracy information on the screen, an input for receiving position information using two or more degree information selected from the input tool and the surface of the three- Module and a three-dimensional biological information processing application stored in the medium for executing a storage module that processes and stores degree information and location information.

100: Three-dimensional modeling 111: Marker marker, input tool 220: Accuracy information input bar
212: Width Diameter Input Bar 213: Height Diameter Input Bar 221:
230: input tool selection unit 511, 512: display marker

Claims (10)

In a three-dimensional biological information processing method,
An initial screen display step of displaying a three-dimensional body model, an input tool type selection unit and a degree information input bar on a screen;
A degree input step of receiving degree information selected by a user;
A position input step of allowing the user to receive the position information designated by the input tool on the surface of the three-dimensional body model;
A corresponding information display step of associating designated position information and selected degree information with each other on a screen; And
And a storing step of processing and storing the specified degree information and the selected position information,
Prior to the corresponding information display step,
Wherein the selected degree information has a highest value and a lowest value and allows the degree information to be changed therebetween to be automatically selected in the degree information selection bar.

The method according to claim 1,
Wherein the input tool has a constant area that is deformable by the user and the area display unit is generated in the corresponding information display step and the selected degree information is at least one or more in the area display unit.

delete 2. The method of claim 1,
Inputting additional position information and degree-of-detail information input by a user;
Wherein the area display unit is combined and displayed when the area display unit by the additional position information and the area display unit by the previous position information are overlapped at least partially.

The method of claim 1, wherein, prior to the storage step,
And accepting and storing the type of biological information from the user.

The method according to claim 1,
Wherein the position information includes three-dimensional coordinate information, and in the storing step, a data set including a recording time is created by processing.

2. The method according to claim 1,
And automatically rotating the three-dimensional body model according to the position of the input tool on the three-dimensional body model.

2. The method of claim 1,
And displaying at least one of the stored degree information and the position information on a two-axis plane when the user designates the three-dimensional biological information.

2. The method according to claim 1,
Further comprising the step of: inputting user description information to the three-dimensional biological information processing system.

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