JPH0199083A - Image expansion display device - Google Patents

Abstract

PURPOSE: To improve cost performance and operability at the time of executing comparing diagnosis by simultaneously displaying plural sorts of overall pictures and the enlarged pictures of parts set up by their range of interest(ROI) and corresponding to the overall pictures on one display screen. CONSTITUTION: Two sorts A, B of picture data, e.g. the data of XCT images and MRI images, are stored in a picture memory. Two sorts of overall pictures and the enlarged pictures of parts set up by ROT 4 are simultaneously displayed on overall picture display areas 2a, 2b and enlarged picture display areas 3a, 3b obtained by dividing a display screen 1 into four parts. Since comparing diagnosis can be executed without preparing plural display devices and it is unnecessary to previously prepare comparing pictures by other operation, cost performance can be improved and operability can be also improved.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to an image enlargement display device that simultaneously displays an entire image of a subject and an enlarged image of a portion thereof.

(Prior art) In the medical field, original images such as both X and -CT images and MRI images are displayed on a display screen, and a part of the image is set as a ROI and the image of this part is displayed. Diagnosis is performed by switching to an image and displaying it enlarged.

Furthermore, displaying the original image and the enlarged image simultaneously on one display screen is also practiced.

Furthermore, attempts have been made to display images of different modalities, such as X-CT and MRI images, simultaneously on a display screen for comparative diagnosis. In this case, two displays are prepared, both X-CT images and MRI images are displayed on each screen, and diagnosis is performed by comparing the two displays. Alternatively, it is also possible to display both images simultaneously on one display screen, but this requires that both images be created in advance by separate operations before being displayed.

(Problems to be Solved by the Invention) Conventionally, when comparing different types of images for diagnosis, there is a problem in that it is necessary to prepare multiple displays or to create images to be compared in advance using separate operations. be. For this reason, the former has poor cost performance, and the latter has poor operability.

The present invention has been made in response to the above-mentioned problems.
It is an object of the present invention to provide an image enlargement display device that improves cost performance and operability when performing comparative diagnosis.

[Structure of the Invention] (Means for Solving the Problems) In order to achieve the above object, the present invention combines multiple types of whole images and enlarged images corresponding to the whole images of parts set by these ROIs into one image. This feature is characterized in that the images are displayed simultaneously on two display screens.

(For I) A plurality of types of whole images, for example two kinds of whole images, an X-C image and an MRI image, and enlarged images of the portions set by these ROIs are displayed simultaneously on one display screen. Therefore, comparative diagnosis can be performed without preparing a plurality of displays, and there is no need to prepare comparative images in advance in a separate operation, so that cost performance and operability can be improved.

(Embodiment) FIG. 1 is a block diagram showing an embodiment of the image display enlarging device of the present invention, and FIG. 2 is a display example showing a display image on a display screen obtained by the device of this embodiment. As shown in FIG. 2, the image display enlarging apparatus to which the present invention is applied is equipped with one display 1, and the matrix size of this screen is an arbitrary size, for example, 512x512. On the screen of the display 1, a plurality of types of whole images related to the subject, for example two types of whole images, an X-C image and an MRI image, are displayed, each with a display amount t12a.

2b. In addition, both of these image display areas 2a,
2b, regions of interest (ROI) 4a and 4b are set at arbitrary same positions, and enlarged images corresponding to both the X-CT image and the MRI image based on these ROIs are respectively displayed in the display area 3.
It is displayed in a and 3b.

The enlargement ratio of the enlarged image displayed on the enlarged image display amount 1tj, 3a, 3b can be set to any value of 1 or more, and the sizes of the ROIs 4a, 4b will also change according to this setting. According to the present invention, at least two pairs of areas are displayed on the screen of one display 1, with the entire image display amount 12a and the corresponding enlarged image display area 3a being one pair. Become. In the display example shown in Fig. 2, a total of four areas, two types of whole image display areas 2a and 2b and two types of enlarged image display amounts 1fA3a and 3b, are displayed on one screen divided into four parts. Therefore, set the matrix size of display 1 to 512X as in the example above.
512, one area will be displayed with a matrix size of 256×256.

In FIG. 1, an image display device 5 is a conventional CR
It has a display 1 which is composed of a T-display and the like and displays a plurality of pairs of images as shown in FIG.
The display image is formed from a plurality of types of image data such as X-CT images, MRI images, etc. stored in the image memory 16 under the control of the control unit 8. The function key 6 is used to set the magnification rate when displaying the magnified image in the magnified image display areas 3a and 3b. If so, any value of 1 or more can be set, such as 2x enlargement, 4x enlargement, etc. This magnification rate is set in the image display area 3a.

3b at the same time. The position input device 7 is composed of a well-known trackball or the like, and is arranged in the entire image display area 2a.
, ROI 4a shown in 2b.

4b, so that both ROIs can be moved in conjunction with each other to almost the same arbitrary position, and the sizes of both ROIs are determined according to the setting of the magnification using the function key 6. This size becomes the display range of the enlarged image display areas 3a and 3b. For example, if the magnification rate is set to 1 (the matrix size of display 1 remains the same), the size of RO14a, 4b will be 128 x 128 (
The matrix size is 512/4 x 512/4 ), and when the enlargement rate is set to 4, the size of ROIs 4a and 4b becomes a matrix size of 64 x 64 (512/8 x 512/8 ).

The control unit 8 is composed of a dedicated microprocessor and is for performing predetermined data processing according to a control program written in a memory (not shown). Enlargement display means 10. ROI synchronization display means 12. ROI setting means]4. Magnification rate table 11. ROI position information table 13. It is composed of an ROI boundary condition table 15.

The reduced display means 9 divides the screen of the display 1 to display a closed image display area 2a to display the entire image.

2b matrix size and these areas 2a.

This is for displaying an image by performing arithmetic processing on the image data based on the matrix size of the image data stored in the image memory 16 to be displayed on the image memory 16. For example, if the former has a matrix size of 256x256 and the latter has a matrix size of 256x256, the latter image data will be displayed as is,
If the former has a matrix size of 256 x 256 and the latter has a matrix size of 512 x 512, the image data of the latter is either thinned out and displayed in a reduced size, or the image data is processed by averaging the four adjacent image data on the top, bottom, left, and right. It is displayed according to the matrix size of the former display areas 2a and 2b.

The enlargement display means 10 includes an enlargement ratio table 11 into which data from the function key 6 has already been input, and an ROI position information table 13 into which data from the position input device 7 has already been input.・Based on the matrix size of the enlarged image display areas 3a, 3b, the matrix size of the image data, etc., the image data is displayed according to the matrix size of the display areas tIJ7.3a, 3b, as in the case of reduced display. I do. When moving the ROIs 4a and 4b set in the entire image display areas 2a and 2b by the position input device 7 to the target position, the ROI synchronized display means 12 displays a plurality of ROIs based on the data of the ROI position information table 13 obtained thereby. display area 2a.

ROIs 4a and 4b displayed in 2b are displayed in display area 2a.
, 2b are displayed in conjunction with each other at the same position.

The ROI setting means 14 is the entire image display area 2a.

ROI so that ROI4a and 4b do not protrude from 2b
While referring to the ROI boundary condition table 15 that sets the movable range of the RO
This is for checking the positions of I4a and 4b and writing the data into the ROI position information table 13 if appropriate. Here, ROI 4a, 4. which is necessary due to the RO■ boundary condition and part of the ROI position information. The size of b will be determined when the enlargement ratio is input using the function key 6.

Next, the operation of this embodiment will be explained.

As an example, the matrix size of the screen of display 1 is 512X512. Assuming that two types of image data, A and B, are stored in the image memory 16, the matrix size for the image is 512X512. Regarding the case where the matrix size of image B is 256 x 256, and two types of whole image display areas 2a and 2b and two types of enlarged image display areas 3a and 3b are displayed by dividing one display screen into four, the following will be explained. This will be explained with reference to the flowchart in FIG.

First, in step (1), image data A and B in the image memory 16 are displayed in the entire image display areas 2a and 2b on the display 1 screen. In this case, one display screen is divided into four display areas [2a.

The matrix size of 2b is 256 x 256, so image data A's matrix size of 512 x 512 is reduced to 256 x 256 and displayed in the display area 2a, and image data B's matrix size of 256 x 256 is displayed in the display area with the same size. 2b.

Next, as in step (2), the enlargement ratio is set using the function key 6. If the magnification rate is set to 1 here, the size of ROI4a and 4b is 128x 1 as described above.
If the magnification rate is set to 4, the size of the ROIs 4a and 4b will be 64×64. This enlargement rate data is stored in a part of the RO1 position information table 13. Also, ROI4a, 4
The movable range of the ROI position is also determined from the size of b, and it is stored in a part of the ROI boundary condition table 15 and the ROI is
Used for specific I settings. Next, as in step (3), the ROIs 4a and 4b of the size set above are displayed at arbitrary positions in the entire image display areas 2a and 2b, respectively. Usually, it is displayed at the center of each display area 2a, 2b.

Next, as in step (4), the position input device 7
The positions of the OIs 4a and 4b are moved, for example, to the site that the doctor wants to diagnose. Next, ROI4. input as in step (5). When the ROI is displayed using the position data of a and 4b, it is determined whether it protrudes from the display areas 2a and 2b, and if it protrudes from the display areas 2a and 2b, the ROI is not set and the ROI display remains as it was.

If necessary, change the position and repeat the settings. Next, as in step (6), if the ROI setting is OK, the ROIs 4a and 4b are displayed at the moved positions.

Next, as in step (7), the doctor displays the displayed ROI4.
It is determined whether or not a and 4b are in the target region, and if no, the position input device 7 selects the ROI 4a.

Repeat the operation of moving 4b. R on the part you want to display
When the OIs 4a and 4b are displayed, the enlarged image display areas 3a and 3b are displayed as in step (8) by using the function key 6 or by using the image data A and B corresponding to the range of the ROI in conjunction with the display of the ROI. Each is enlarged and displayed. If the magnification is 1, image data A is originally a size that matches the matrix size of one display screen, so only the data in the range of ROIs 4a and 4b is extracted and displayed, and image data B is reduced from the matrix size of one display screen. Because of the size, ROI4a, 4b
Interpolate and display the data in the range. The magnification is 2,
When set to 4, image data A is generated as appropriate using the same principle.
, B, the desired enlarged display can be achieved. When the doctor wants to observe another part for diagnosis, the position input device 6 allows the doctor to observe the ROI4a,
This can be easily realized by moving 4b.

In this way, according to this embodiment, two types of whole side image display areas VX2a, 2b and two types of enlarged image display areas 3a, 3b corresponding to these can be simultaneously displayed on one display screen. When performing comparative diagnosis of different types of images, diagnosis can be performed without preparing two displays, and control operations of the control unit are performed based on image data stored in advance in the image memory without having to prepare comparison images by cutting operations in advance. can be taken out and displayed easily. Therefore, cost performance can be improved and operability can be improved.

In this example, two types of images are X-CT and MRI.
Although an example using images has been shown, the present invention is not limited to these, and images obtained by other diagnostic devices can be arbitrarily used. Furthermore, the number of images to be displayed on the display is not limited to two types, and three or more types can also be selected. In this case, it is sufficient to increase the types of image data stored in the image memory.

[Effects of the Invention] As described above, according to the present invention, multiple types of whole images and their corresponding enlarged images can be simultaneously displayed on one display at -13=, thereby improving cost performance. At the same time, comparative diagnosis can be performed with improved operability.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the image enlargement display device of the present invention, FIG. 2 is an example of a display screen obtained by the device of this embodiment, and FIG. 3 is a flowchart explaining the operation of this embodiment. It is. 1... Display screen, 2.2a, 2b... Entire image display area, 3.3a, 3
b... Enlarged image display area, 4... ROI (region of interest), 6... Function key, 7... Position input device,
8...Control unit, 9...Reduction display means,
10... Enlargement display means, 16... Image memory. Agent Patent attorney Nori Ken Ken Yudo Konfuji Takeshi 84-11 Obu Robu No. 1 Figure 4 Kenni Kuzuhou Figure 2

Claims (1)

[Claims] An image enlargement display device that simultaneously displays an entire image of a subject and an enlarged image of a portion thereof on one display screen includes an image storage means for storing a plurality of types of image data, and a plurality of types of image data for extracting image data from the image storage means. a control means for simultaneously displaying on a display screen a plurality of types of enlarged images of the whole image and a portion set by the ROI on each whole image, and an ROI capable of setting the ROI at an arbitrary substantially same position in each whole image; 1. An image enlargement display device comprising: input means; and enlargement ratio input means for setting the enlargement ratio of an enlarged image to be displayed according to each whole image.