KR102417757B1 - Medical image conversion system and medical image conversion method - Google Patents

Abstract

The present invention relates to a method for providing a specified and standardized picture, and to a medical picture conversion system capable of converting an automatically generated picture into a picture modified to suit the characteristics of a patient, and a medical picture conversion method using the same.
The medical picture conversion system according to the present invention includes a model calling unit 100 for calling an input model at the user's request; a model providing unit 200 that provides the input model generated by the model calling unit 100 as a basic model 210 representing body parts and a disease model 220 representing a disease; Check the displayed basic model 210 and the disease model 220 , edit the views of the basic model 210 and the disease model 220 , and display the disease model 220 in the basic model 210 . ) provided to insert a picture correction unit 300; The basic model 210 and the disease model 220 modified by the picture correction unit 300 are divided into sectors and a sector setting unit 400 capable of setting divisions; a medical picture providing unit 500 providing medical pictures by separating the basic model 210 and the disease model 220 in which the sector setting unit 400 is divided into those for medical personnel and patients; and a storage unit 600 for storing data executed by the model calling unit 100 , the model providing unit 200 , the picture correction unit 300 , the sector setting unit 400 , and the medical picture providing unit 500 ; Including, wherein the basic model 210 and the disease model 220 are generated in 2D or 3D, characterized in that the mutual conversion from 2D to 3D.

Description

Medical picture conversion system and medical picture conversion method using the same

The present invention relates to a method for providing a specified and standardized picture, and to a medical picture conversion system capable of converting an automatically generated picture into a picture modified to suit the characteristics of a patient, and a medical picture conversion method using the same.

Conventional medical drawings are provided as a method in which a medical person marks the affected area with a pen on a drawing on which a simple shape of the body is drawn. These medical drawings have developed into a form in which medical personnel mark the affected area with a mouse and color it on the basic human body picture drawn on the author chart system in modern times.

Medical drawings drawn with paper and pen are not easy to store, and it was inefficient to draw with a mouse on the EMR while looking at the monitor. Because medical personnel had to draw medical pictures within a limited time while treating patients, it was difficult to display detailed information, and there was a high possibility of inaccurate drawing. In addition, medical pictures were likely to be drawn differently depending on the medical staff even for the same medical information, and were likely to be drawn in various shapes according to body parts. Also, the pictures used were different according to the customs of the department or the user's preference. Therefore, if the method of expressing the type of disease or body part can be specified and quantified on the medical picture, the accuracy of the information that the healthcare provider wants to convey when sharing the picture with other medical institutions or explaining the location or size of the lesion to the patient will be able to increase Being able to draw a picture to know the patient's condition on the progress record or reading sheet formed in this way can be a very big advantage.

The present invention provides a specific and standardized picture that is different from conventional medical pictures. In addition, it provides a basic model 210 that can be variously converted according to the viewpoint (VIEW) observed by the medical staff, the age, sex, etc. of the patient. Here, “conversion” refers to converting an automatically generated picture based on basic information into a picture modified to fit the characteristics of the patient.

The automatically generated picture can be extracted from medical images such as X-Ray, CT image, and ultrasound image, and can also be extracted from text such as medical code or disease name. It can also be extracted from a picture drawn as an interface of This may be drawn by machine learning, may be drawn in the form of calling the disease model 220 data stored in the server, or may be drawn directly by the user. Modifying the automatically generated picture to fit the characteristics of the patient is called transformation, and may be transformed according to characteristics such as gender or age of the patient.

Korean Patent Publication No. 2018-0098869

The present invention has been devised to solve the above problems, and the object of the present invention is a view desired by the user, the needs of medical personnel provided as a medical picture mainly used by the user, or the age, gender and body type of the patient. It is to provide medical pictures suitable for the characteristics of the patient.

The technical problems to be solved by the invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. will be able

Medical picture conversion system according to the present invention,

a model calling unit 100 for calling an input model at the user's request;

a model providing unit 200 that provides the input model generated by the model calling unit 100 as a basic model 210 representing body parts and a disease model 220 representing a disease;

Check the displayed basic model 210 and the disease model 220 , edit the views of the basic model 210 and the disease model 220 , and display the disease model 220 in the basic model 210 . ) provided to insert a picture correction unit 300;

The basic model 210 and the disease model 220 modified by the picture correction unit 300 are divided into sectors and a sector setting unit 400 capable of setting divisions;

a medical picture providing unit 500 providing medical pictures by separating the basic model 210 and the disease model 220 in which the sector setting unit 400 is divided into those for medical personnel and patients; and

The model calling unit 100, the model providing unit 200, the picture correction unit 300, the sector setting unit 400, and the storage unit 600 for storing the data implemented in the medical picture providing unit 500; including,

The basic model 210 and the disease model 220 are generated in 2D or 3D and are characterized in that they are mutually converted from 2D to 3D.

By means of a solution to the above problem, the present invention is a medical picture suitable for the user's desired view, the needs of the medical personnel provided as a medical picture mainly used by the user, or the patient's characteristics such as the patient's age, gender and body type can provide

In addition, by the sectors of the basic model 210 and the disease model 220 provided by the present invention, the disease can be easily expressed according to characteristics such as the scope and accuracy of the disease, and the sector is standardized to determine the individual's onset location and The treatment location can be clearly identified by sector, and it can be used in a variety of ways through statistics.

In addition, the medical figure provided by the present invention can be corrected and converted by the user at one angle automatically in the figure at another angle.

In addition, since the pictures mainly used for each department are different and the areas to be intensively observed and treated are different, the medical pictures can be converted and provided accordingly.

In addition, since it is possible to create a more reliable medical picture through the transformation of various models, the patient can understand more specifically and intuitively about his or her disease, thereby inducing active participation in treatment.

1 is a block diagram showing the configuration of a medical picture conversion system.
2 is a flowchart illustrating a method of converting a picture for medical use.
3 is an exemplary embodiment in which a picture is automatically generated by inputting text.
4 is an exemplary embodiment in which a medical picture is automatically generated through a medical image.
5 is an embodiment in which the user draws a picture on the basic model 210 to automatically create additional basic models.
6 is an embodiment in which the 2D basic model 210 is converted into the 3D basic model 210 .
7 is another embodiment in which the 2D basic model 210 is converted into the 3D basic model 210 .
8 is an embodiment in which the 2D upper body skeleton basic model 210 is provided at various angles.
9 is an embodiment in which the 3D skeleton basic model 210 is provided at various angles.
10 is an embodiment showing a 3D stereoscopic basic model 210 that is changed according to a viewpoint.
11 is an embodiment in which the basic model of the liver 210 is added to the basic model of the whole body 210 (A) and the basic model of the whole body 210 provided in three dimensions (B).
12 is an embodiment showing a 3D basic model 210 converted according to age.
13 is an embodiment showing a 3D basic model 210 in which sectors to be converted according to body types are set.
14 is an embodiment showing a 2D basic model 210 of a liver divided into small sectors.
15 is an embodiment showing a 2D basic model 210 of a liver divided into small sectors.
16 is an embodiment showing baby's liver and man's liver divided into standardized sectors.
17 is an embodiment showing that a sector is designated when a medical practitioner draws a size of a lesion with a mouse on the basic model 210. Referring to FIG.
18 is an embodiment in which sectors are designated on the basic model 210 of the liver having small sectors.
19 shows an embodiment in which sectors are designated on a basic model 210 of a liver having large sectors.
20 shows an embodiment in which, when a sector is designated on the front side, the sector on the back side is also designated.
21 is an embodiment in which the basic model 210 between 3D can be divided into various sectors.
22 is an embodiment showing a liver basic model 210 in which a texture is set on a sector.
23 is an embodiment illustrating a medical picture of a doctor's view and a medical picture of a patient's view that can help the understanding of the patient.
24 is an exemplary embodiment in which a medical practitioner can add a description of a patient's symptoms.
25 is a configuration diagram showing that information sharing between hospitals is possible using the present invention.
26 is an embodiment in which statistics for each organ can be represented using the present invention.

Terms used in this specification will be briefly described, and the present invention will be described in detail.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, which may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

In the entire specification, when a part “includes” a certain element, it means that other elements may be further included, rather than excluding other elements, unless otherwise stated.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein.

Specific details including the problem to be solved for the present invention, the means for solving the problem, and the effect of the invention are included in the embodiments and drawings to be described below. Advantages and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

The present invention relates to a medical picture conversion system and a medical picture conversion method using the same. 400), it is composed of a medical picture providing unit 500 and a storage unit (600).

First, the model calling unit 100 calls the input model at the user's request.

In order to convert a picture, a medical picture that has already been written is required. The medical picture may be an automatically generated picture based on basic information. In the present invention, a picture automatically generated based on basic information is called an input model. 3, 4, and 5 are exemplary embodiments showing a process of generating an input model.

The model calling unit 100 may generate an input model by inputting text, using a medical image, or drawing a picture by a user.

First, FIG. 3 is an example in which the input model is generated through text input. The text may be a sentence, word, medical term, or medical code for a symptom or disease name in each language, and refers to all character data capable of displaying the symptom. When the input model is automatically generated through text input, both the basic model 210 and the disease model 220 may be presented. For example, Figure 3 shows a liver abscess, but it is difficult to accurately display the location of the abscess with text. Therefore, the liver basic model 210 and the abscess disease model 220 are presented separately so that the user can designate the location or size of the disease model 220 through an interface such as a mouse.

In addition, FIG. 4 shows an embodiment of calling the input model using a medical image. The medical image may be medical data such as CT, MRI, X-RAY, etc. may be This image is recognized by the system and an input model is created as closely as possible.

In addition, FIG. 5 shows an embodiment in which a user draws a picture and calls the input model. The user can draw a picture by using an interface such as a mouse. For example, if you want to display a liver abscess, if the user draws a desired location and range on the basic liver model 210, the disease model 220 on the right can be generated.

Next, the model providing unit 200 provides a basic model 210 representing a body part and a disease model 220 representing a disease for the input model generated by the model calling unit 100, and the basic model ( 210) and the view of the disease model 220 are edited.

The model providing unit 200 is provided so that the basic model 210 and the disease model 220 are generated in 2D or 3D and can be converted from 2D to 3D. As shown in FIG. 6 , the basic model 210 may be provided in 2D or 3D, and as shown in FIG. 7 , one basic model 210 may be converted from 2D to 3D. Through this, it is possible to identify a region that is difficult to observe with a view of the 2D basic model 210 .

The model providing unit 200 may be converted differently according to a user's desired view. As shown in FIG. 8 , the basic model 210 can be checked in detail by changing the views not only from the front, but also from the rear and the side, and can be variously converted according to the angle desired by the user. In addition, the user may select a desired viewpoint from among the basic models 210 of several viewpoints stored in the storage unit 600 .

In addition, in the case of modifying the 2D planar drawing basic model 210, if the basic model 210 is modified from one view, it is possible to automatically modify the basic model 210 from another viewpoint. 8 is an embodiment of a basic bone model 210 showing the skeleton of a young male, and shows that a different basic model 210 can be selected and converted according to the age or gender of the patient.

9 and 10 are views showing changes in the viewpoint of the adult skeleton basic model 210 shown in 3D. The 3D basic model 210 is an observation distance or field of view through the interface stored in the storage unit 600 . can be switched In addition, unlike the 2D planar figure model in which one of several views of the basic model 210 has to be selected, in the case of the 3D three-dimensional model, the view is switched by rotating the model using the mouse or keyboard direction keys. can do. The whole body model can be viewed or only a part of the organ model can be observed. The angle of the viewpoint can be adjusted according to the user's needs, and the distance of the viewpoint can also be adjusted. This 3D basic model 210 can be converted into a 2D basic model 210 if necessary.

Next, the picture correction unit 300 is provided to check the displayed basic model 210 and the disease model 220 , and insert the disease model 220 into the basic model 210 .

It is also possible for the picture correction unit 300 to insert the long-term disease model 220 into the whole body basic model 210 . As shown in FIG. 11 , the liver disease model 220 may be inserted, and in addition, it is also possible to insert the disease model 220 of various organs. Through this, it is also possible to collect and observe the organs of a patient having diseases in several parts at a time by inserting various disease models 220 into one whole body basic model 210 .

In one embodiment, as shown in FIG. 12 , the size of the basic model 210 may vary according to age, so when the liver disease model 220 is inserted into the whole body basic model 210, the liver of infants and young children can be found in the entire body. The proportion of the liver and the proportion of the adult male liver are different. Aspects of disease may appear differently according to age, and since the size of an organ is also different, the basic model 210 should be presented differently according to age. In addition, since the patient can grow during the period of treatment, it must be transformed accordingly. That is, as shown in FIG. 12 , when an infant with liver disease becomes an adult while receiving medical treatment in a long-term medical period, it is possible to convert from the basic infant model 210 to the adult basic model 210 .

Next, the sector setting unit 400 sets the division by dividing the basic model 210 and the disease model 220 modified by the picture correction unit 300 into sectors. More specifically, the sector setting unit 400 includes a sector confirmation unit 410 and a sector application unit 420 .

The sector check unit 410 sets the width and length designation of the division in the basic model 210 and the disease model 220, and is provided to select from 2D or 3D to create a sector. The sector check unit 410 is provided to select according to the patient's gender, age, and body type.

The sector application unit 420 provides a user to set a texture among the sectors generated by the sector check unit 410 . That is, when indicating a disease having a range, such as a mass lesion or a case in which the lesion of the affected area is focused, the sector display is essential.

There are two main reasons for the existence of the sector. The first is to facilitate the expression of a disease having a location and an area, and the second is to represent it statistically by collecting sectors of the same location or area. That is, since the sector is standardized on the basic model 210 of all people, such as men, women, infants, and the elderly, statistics such as sectors of individual onset locations and sectors of treated locations are combined into one basic model 210. can be collected and checked.

On the other hand, the disease model 220 is a model that displays the patient's disease. This may be a disease model 220 having an actual shape, such as a tumor or a lump, or a disease model 220 having a wide range, such as burns or inflammation. For example, in the case of a disease having a width and a location, such as cancer, organ inflammation, or skin burn, the region of the basic model 210 , that is, the range may be relatively clearly indicated. In the present invention, the area in which the range can be set is referred to as a sector.

The number of sectors set in the basic model 210 and the disease model 220 is constant regardless of the sizes of the basic model 210 and the disease model 220 . For example, as shown in FIG. 13 , when a patient gains or loses weight during a period of long-term treatment and treatment, the basic model 210 is converted to the basic model by the sector setting unit 400 . The sector size of 210 may vary, but since the number is provided uniformly, it is easy to identify the sector indicating the location of the disease.

As described above, the size of the sector of the basic model 210 may be different. The sector may be divided into small and finely divided sectors as shown in FIG. 14 or large as shown in FIG. 15 . In addition, each sector is A1, A2, A3, B1, C3, ... It can be standardized by generating serial numbers such as, etc. The serial number may be designated by selecting the sector and designating a range through an interface such as a mouse or keyboard direction key. Through this, the location, shape, and size of symptoms can be displayed.

More specifically, the sectors of the basic model 210 are standardized. The sector standardization is achieved by matching the number of sectors. For example, as shown in FIG. 16, assuming that there are a basic model 210 of a baby's liver and a basic model 210 of an adult liver (man's liver), the sector of the basic model 210 is Since it is standardized, the sizes of the two sectors are different, so the sector size is different, but the number of sectors is equal to eight.

The user can easily display the size or location of the lesion by additionally designating the sector. For example, when a medical person needs to indicate infection, as shown in FIG. 17 , if the location and width of inflammation are displayed using a GUI interface, that is, a mouse, etc. on the 2D liver basic model 210, the lesion sector is matched to the range. is specified The location of the designated lesion sector can be changed as needed.

18 and 19 show an embodiment in which a lesion sector is assigned to a sector of the basic liver model 210 of FIGS. 14 and 15 . Serial numbers such as A1, A2, A3 are configured to be all designated at the viewpoint of the front, rear, and side basic model 210 . That is, when designating or modifying the lesion sector in the 2D basic model 210 , as described above, it is not modified only at one viewpoint. For example, as shown in FIG. 20 , when a lesion sector is designated from the front view of the liver basic model 210, the entire 2D plane basic model 210 of various angles including the back and side surfaces of the liver basic model 210 is are corrected together. The basic model 210 modified at various points in time can be converted and used according to the user's needs.

Also, just as the sector size of the 2D basic model 210 presented above can be variously divided, the sector of the 3D basic model can also be divided into various sizes and widths. As shown in FIG. 21 , a different basic model 210 may be selected and used according to characteristics such as the range and accuracy of a disease required by the user.

Next, the sector application unit 420 may designate a texture to the sectors of the basic model 210 and the disease model 220 . In the case of diseases such as inflammation, burns, and cancer that have the location and width of the lesion, it is efficient to designate a sector and display it. However, if only the sector of the basic model 210 is designated, it is difficult to notice which bottle is marked. Therefore, it is necessary to apply a texture after the sector is designated. As shown in FIG. 22 , the texture designation is a step of applying different textures or patterns according to diseases, and the texture may be a checkerboard pattern, a diagonal pattern, or a different color may be applied. The texture is not limited to the presented embodiment and can be expressed using various patterns and colors according to users. If all of the sector designation and texture setting are completed in this way, one medical picture is completed.

The medical picture providing unit 500 provides a medical picture by separating the basic model 210 and the disease model 220 for which the division is set in the sector setting unit 400 for medical personnel and for patients.

Ordinary patients may have a relatively low understanding of the shape of organs and where and how symptoms appear compared to medical professionals. Therefore, it is necessary to separately provide a medical picture at the point of time that a medical person prefers or treats, and a medical picture that is easy for the patient to understand.

For example, suppose a medical staff treats the posterior part of the liver. Ordinary people will not have much knowledge about the liver compared to medical staff who specialize in liver treatment. Therefore, it may be inefficient for medical staff who treat the rear part of the liver to explain to general patients with a picture of the VIEW. However, as shown in FIG. 23 , if a picture for the patient can be provided separately, the location of the symptom onset and the size of the lesion can be explained in much more detail and easily.

In addition, after the modification of the basic model 210 or the disease model 220 is finished, the medical picture providing unit 500 separates the symptoms or frequency of the patient's disease in the description column when it is necessary to separately describe the patient's symptoms. provided for recording.

Next, the storage unit 600 is data implemented by the model calling unit 100 , the model providing unit 200 , the picture correction unit 300 , the sector setting unit 400 , and the medical picture providing unit 500 . save the

When all inputs are completed using the model calling unit 100, the model providing unit 200, the picture correction unit 300, the sector setting unit 400, and the medical picture providing unit 500, as shown in FIG. Likewise, the clinician can store it in the system. At this time, the title of the medical picture can be set, and the patient's name, symptoms, characteristics, date of treatment, etc. can be entered. If you save the picture in detail like this, you can find the medical picture conveniently and quickly when you treat the same patient in the future.

Medical pictures can be shared between medical institutions. It can also be converted when passed on to other health care providers. As shown in FIG. 25 , it can be seen that the model can be transferred from hospital A to hospital B in the completed medical picture. In addition, if the medical staff of Hospital B wants to view the 2D model as a 3D model, it can be converted, and the medical staff can convert and observe the desired type of picture. This makes it possible to share medical pictures with different medical institutions or medical staff, thereby facilitating communication about patient symptoms.

In addition, as shown in FIG. 26 , when variously made medical pictures are stored, statistics of symptoms may be generated. Statistics can be generated according to gender or age, which can be collected and observed in one basic model 210 .

Hereinafter, as shown in FIG. 2 , a method for converting a medical picture using the medical picture converting system according to the present invention will be described.

First, the first step ( S100 ) is a model calling step. In the model calling step, the model calling unit 100 calls the input model at the user's request.

Next, the second step (S200) is a model providing step. In the model providing step, the input model generated by the model calling unit 100 is provided by the model providing unit 200 as a basic model 210 representing a body part and a disease model 220 representing a disease, The views of the basic model 210 and the disease model 220 are edited.

Next, the third step (S300) is a picture correction step. The picture correction step is provided so that the picture correction unit 300 checks the displayed basic model 210 and the disease model 220 , and inserts the disease model 220 into the basic model 210 . .

Next, the fourth step (S400) is a sector setting step. In the sector setting step, the basic model 210 and the disease model 220 modified by the picture correction unit 300 are divided into sectors by the sector setting unit 400 to set the division.

The sector setting step (S400) is composed of a sector confirmation step (S410), a sector confirmation step, and a sector application step, a step 4-2 (S420).

Step 4-1 (S410) is a sector confirmation step. In the sector confirmation step, the sector confirmation unit 410 sets the designation of the width and length of the division in the basic model 210 and the disease model 220, and is provided to select either 2D or 3D to generate a sector.

Step 4-2 (S420) is a sector application step. In the sector application step, the user sets a texture among the sectors generated by the sector application unit 420 by the sector check unit 410 .

Next, the fifth step (S500) is a medical picture providing step. In the medical picture providing step, the sector setting unit 400 separates the basic model 210 and the disease model 220 in which the division is set, and the medical picture providing unit 500 provides a medical picture by dividing it into a medical person and a patient. .

Next, the sixth step (S600) is a storage step. In the storage step, the storage unit 600 is data performed by the model calling unit 100 , the model providing unit 200 , the picture correction unit 300 , the sector setting unit 400 , and the medical picture providing unit 500 . save the

By means of a solution to the above problem, the present invention is a medical picture suitable for the user's desired view, the needs of the medical personnel provided as a medical picture mainly used by the user, or the patient's characteristics such as the patient's age, gender and body type can provide

In addition, by the sectors of the basic model 210 and the disease model 220 provided by the present invention, the disease can be easily expressed according to characteristics such as the scope and accuracy of the disease, and the sector is standardized to determine the individual's onset location and The treatment location can be clearly identified by sector, and it can be used in a variety of ways through statistics.

In addition, the medical figure provided by the present invention can be corrected and converted by the user at one angle automatically in the figure at another angle.

In addition, since the pictures mainly used for each department are different and the areas to be intensively observed and treated are different, the medical pictures can be converted and provided accordingly.

In addition, since it is possible to create a more reliable medical picture through the transformation of various models, the patient can understand more specifically and intuitively about his or her disease, thereby inducing active participation in treatment.

As such, those skilled in the art to which the present invention pertains will understand that the above-described technical configuration of the present invention may be implemented in other specific forms without changing the technical spirit or essential characteristics of the present invention.

Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the above detailed description, and the meaning and scope of the claims and their All changes or modifications derived from the concept of equivalents should be construed as being included in the scope of the present invention.

100. Model call unit
200. Model providing department
210. Basic Model
220. Disease Model
300. Picture Correction Unit
400. Sector setting unit
410. Sector Confirmation Unit
420. Sector Application Department
500. Medical picture provider
600. Reservoir
S100. Model calling step in which the model calling unit 100 calls the input model at the user's request
S200. A model providing step of providing the input model generated by the model calling unit 100 as a basic model 210 representing a body part and a disease model 220 representing a disease by the model providing unit 200
S300. The picture correction unit 300 checks the displayed basic model 210 and the disease model 220, edits the views of the basic model 210 and the disease model 220, and the basic model 210 ) a picture correction step prepared to insert the disease model 220 into
S400. A sector setting step in which the basic model 210 and the disease model 220 modified by the picture correction unit 300 are provided so that the sector setting unit 400 separates them into sectors and sets divisions.
S410. A sector confirmation step in which the sector confirmation unit 410 sets the designation of the width and length of the division in the basic model 210 and the disease model 220, and is provided to select from 2D or 3D to create a sector
S420. A sector application step in which the sector application unit 420 sets a texture among the sectors generated by the sector confirmation unit 410 .
S500. A medical picture providing step in which the sector setting unit 400 separates the basic model 210 and the disease model 220 in which the divisions are set, and the medical picture providing unit 500 provides a medical picture for medical personnel and patients.
S600. The storage unit 600 stores the data executed by the model calling unit 100 , the model providing unit 200 , the picture correction unit 300 , the sector setting unit 400 , and the medical picture providing unit 500 . step

Claims (2)

a model calling unit 100 for calling an input model at the user's request;
The input model generated by the model call unit 100 is provided as a basic model 210 indicating body parts and a disease model 220 indicating a disease, and the viewpoints of the basic model 210 and the disease model 220 are provided. a model providing unit 200 for editing (view);
a picture correction unit 300 provided to check the displayed basic model 210 and the disease model 220 and insert the disease model 220 into the basic model 210;
The basic model 210 and the disease model 220 modified by the picture correction unit 300 are divided into sectors and a sector setting unit 400 capable of setting divisions;
a medical picture providing unit 500 providing medical pictures by separating the basic model 210 and the disease model 220 in which the sector setting unit 400 is divided into those for medical personnel and patients; and
The model calling unit 100, the model providing unit 200, the picture correction unit 300, the sector setting unit 400, and the storage unit 600 for storing the data implemented in the medical picture providing unit 500; including,
The basic model 210 and the disease model 220 are generated in 2D or 3D and are mutually converted from 2D to 3D,
The sector setting unit 400 sets the width and length designation of the divisions in the basic model 210 and the disease model 220, and is provided to select from 2D or 3D sector to generate a sector. ; and
It consists of; a sector application unit 420 that provides a user to set a texture among the sectors generated by the sector check unit 410;
A medical picture conversion system, characterized in that the number of sectors set in the basic model 210 and the disease model 220 is constant regardless of the sizes of the basic model 210 and the disease model 220 . .
a model calling step in which the model calling unit 100 calls the input model at the user's request;
a model providing step of providing the input model generated by the model calling unit 100 as a basic model 210 representing a body part and a disease model 220 representing a disease by the model providing unit 200;
Check the basic model 210 and the disease model 220 displayed by the picture correction unit 300, edit the views of the basic model 210 and the disease model 220, and the basic model 210 a picture correction step provided to insert the disease model 220 into the;
a sector setting step in which the basic model 210 and the disease model 220 modified by the picture correction unit 300 are provided so that the sector setting unit 400 separates them into sectors and sets divisions;
A medical picture providing step in which the sector setting unit 400 separates the basic model 210 and the disease model 220 in which divisions are set, the medical picture providing unit 500 separates them into medical personnel and patients, and provides medical pictures; and
The storage unit 600 stores the data executed by the model calling unit 100 , the model providing unit 200 , the picture correction unit 300 , the sector setting unit 400 , and the medical picture providing unit 500 . step; including,
The basic model 210 and the disease model 220 are generated in 2D or 3D and are mutually converted from 2D to 3D,
The basic model 210 and the disease model 220 are generated in 2D or 3D and are mutually converted from 2D to 3D,
The sector setting step is
a sector confirmation step of generating a sector by providing a sector confirmation unit 410 to set the designation of the width and length of the division in the basic model 210 and the disease model 220, and to select from 2D or 3D; and
performed by the sector application step of the sector application unit 420 setting a texture among the sectors generated by the sector verification unit 410;
The number of sectors set in the basic model 210 and the disease model 220 is constant regardless of the sizes of the basic model 210 and the disease model 220. Method for converting a medical picture, characterized in that .

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