JP2008043588A - Image display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To display an image required for the diagnostic reading by monitoring by a simple operation. <P>SOLUTION: An image magnification indicating member 10 is made to face a monitor displaying screen 2a which displays X-ray image data. The magnifying rate of an image for a lesion G of a cancer or the like is made adjustable by making the facing gap L between the monitor displaying screen 2a and the image magnification indicating member 10 adjustable, and the image is magnified and displayed on the monitor displaying screen 2a. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an image display apparatus that is applied to, for example, monitor diagnosis of a subject and performs enlargement processing, window processing, etc. on the subject image data.

  During monitor diagnosis of a subject such as a patient, an X-ray image of the subject is displayed on the monitor of the image display device. This image display apparatus can perform an enlargement process or a window process on an X-ray image of a subject. In the enlargement processing method, on the monitor screen, the pointer is moved by, for example, a mouse operation on the image portion to be enlarged, and the enlargement ratio of the image is designated. As a result, the image portion aligned with the pointer is displayed at the designated enlargement ratio.

  When window processing is performed, the window width (WW) and window level (WL) are input, the slide bar is adjusted, and the mouse is operated. Here, of the output gray level of the detector, a range in which image processing is performed is referred to as a window width (WW), and a center value of the window width (WW) is referred to as a window level (WL).

  For example, a breast X-ray diagnostic apparatus draws X-rays that have passed through a subject on a film, detects X-rays that have passed through the subject with an X-ray detector, and performs image processing on the output signal of the X-ray detector There is a digital method for acquiring X-ray image data. When diagnosing a subject, in a diagnosis using a film, an operator such as a doctor interprets an image drawn on the film, for example. At the time of this interpretation, the operator enlarges a specific part of the image drawn on the film using, for example, a magnifying glass, and diagnoses the specific part.

  On the other hand, in the case of monitor diagnosis in which X-ray image data acquired by a digital device is displayed on a monitor and interpreted, there is a case where a specific part of the X-ray image displayed on the monitor is enlarged for diagnosis. However, the display capability of the monitor is smaller than the display capability of one film. In other words, the information amount of the X-ray image displayed on the monitor is smaller than the information amount of the image drawn on one film.

  For this reason, when diagnosing with an X-ray image displayed on a monitor, in order to obtain the same diagnostic ability as that at the time of film diagnosis, the X-ray image must be read while being enlarged or windowed. However, in the enlargement process, on the monitor screen, the pointer is moved by, for example, a mouse operation on the image portion to be enlarged and the enlargement ratio of the image is specified. On the other hand, in the window process, for example, the window width (WW) and An operation for inputting a window level (WL) or the like must be performed. For this reason, the operation at the time of enlargement processing or window processing is complicated, and the operation takes time. Some operators such as doctors interpret the X-ray image displayed on the monitor as it is without performing the operation during the enlargement process or the window process.

  An object of the present invention is to provide an image display device capable of displaying an image necessary for interpretation on a monitor with a simple operation.

  An image display apparatus according to a first aspect of the present invention includes a display device having a display screen for displaying image data of a subject, and a display screen for displaying an enlarged image of the subject displayed on the display screen. An image enlargement instructing member for confronting the image of the subject, a position detecting unit for detecting at least the facing distance between the display screen and the image enlargement instructing member, and a display screen according to the facing distance detected by the position detecting unit. A display control unit for enlarging and displaying the displayed image data.

  ADVANTAGE OF THE INVENTION According to this invention, the image display apparatus which can carry out monitor display of the image required for interpretation by simple operation can be provided.

Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram of an image display apparatus. A monitor device 2 is connected to the device processing body 1. The apparatus processing body 1 displays X-ray image data of the breast as the subject 4 photographed by the breast X-ray diagnostic apparatus 3 on the monitor device 2, for example. The apparatus processing body 1 is configured by connecting a display control unit 6, a position calculation unit 7, an image memory 8, and a communication line 9 to a main control unit 5 formed of a computer. The main control unit 5 controls the operation of the display control unit 6, the position calculation unit 7, the image memory 8, and the communication line 9, respectively. A breast X-ray diagnostic apparatus 3 is connected to the communication line 9. The communication line 9 receives X-ray image data transmitted from the breast X-ray diagnostic apparatus 3. The main control unit 5 stores the X-ray image data received through the communication line 9 in the image memory 7.

  The apparatus includes an image enlargement instruction member (image enlargement instruction component) 10. The image enlargement instructing member 10 is formed by imitating the shape of a magnifying glass, and is formed of an annular frame 10a and a rod-shaped gripping portion 10b provided on the frame 10a. The image enlargement instruction member 10 is gripped by an operator such as a doctor, and the annular frame 10a is opposed to the monitor display screen 2a of the monitor device 2 at the time of monitor diagnosis.

  Position sensors 11-1 to 11-4 are provided at the four corners of the monitor display screen 2a of the monitor device 2, respectively. Each of these position sensors 11-1 to 11-4 detects a facing distance between the image enlargement instruction member 10 and the monitor display screen 2a facing the monitor display screen 2a, and outputs a detection signal thereof.

  The position calculation unit 7 receives the detection signals output from the position sensors 11-1 to 11-4, and based on these detection signals, the facing interval L between the monitor display screen 2a and the image enlargement instruction member 10; The opposite position of the image enlargement instruction member 10 with respect to the monitor display screen 2a is obtained. The position calculation unit 7 obtains, for example, each distance between each of the position sensors 11-1 to 11-4 and the image enlargement instruction member 10, and based on these distances, the facing interval between the monitor display screen 2a and the image enlargement instruction member 10 L can be calculated. Note that a GPS system can be applied to each of the position sensors 11-1 to 11-4 and the position calculation unit 7.

  The display control unit 6 varies the enlargement ratio of the X-ray image data according to the facing distance L between the monitor display screen 2 a and the image enlargement instruction member 10 obtained by the position calculation unit 7. For example, as shown in FIG. 2, the display control unit 6 narrows the facing distance L, that is, reduces the magnification rate of the X-ray image data as the image enlargement instruction member 10 approaches the monitor display screen 2a, and sets the facing distance L. As the image enlargement instructing member 10 is moved away from the monitor display screen 2a, the enlargement ratio of the X-ray image data is greatly varied. In this case, the display control unit 6 can continuously change the enlargement ratio of the X-ray image data according to the facing interval L. The enlarged display of the X-ray image data by the display control unit 6 enlarges and displays the X-ray image data with the same display ability as the display ability acquired by the enlargement process and the window process that have been conventionally performed.

  The display control unit 6 receives the position of the image enlargement instructing member 10 facing the monitor display screen 2a obtained by the position calculating unit 7, and on the monitor display screen 2a facing the image enlargement instructing member 10 based on this facing position. The magnification of the image data of the image part on the monitor display screen 2a of the lesion G such as cancer viewed through the annular frame 10a of the image enlargement instruction member 10 by an operator such as a doctor is varied.

Next, an image display control operation by the apparatus configured as described above will be described.
The display control unit 6 reads out the X-ray image data stored in the image memory 8 and displays it on the monitor display screen 2 a of the monitor device 2. An operator such as a doctor interprets the X-ray image data displayed on the monitor display screen 2a. At the time of this interpretation, when the operator finds a special treatment site, for example, a site where a lesion G such as cancer has developed from the X-ray image displayed on the monitor display screen 2a, the image of this specific site is enlarged and displayed. Diagnose. Note that a lesion G such as cancer occurring in the breast occurs in a mammary gland tissue that develops around the nipple.

  At the time of this monitor diagnosis, the image enlargement instruction member 10 is gripped by an operator such as a doctor, and the annular frame 10a is opposed to the monitor display screen 2a of the monitor device 2. At this time, the image enlargement instructing member 10 is opposed to the monitor display screen 2a at a position where a lesion G such as cancer can be seen by the operator through the annular frame 10a.

  The position sensors 11-1 to 11-4 at the four corners of the monitor display screen 2a detect the distance L between the image enlargement instruction member 10 facing the monitor display screen 2a and the monitor display screen 2a. Output a signal. The position calculation unit 7 receives the detection signals output from the position sensors 11-1 to 11-4, and based on these detection signals, the facing interval L between the monitor display screen 2a and the image enlargement instruction member 10; The opposite position of the image enlargement instruction member 10 with respect to the monitor display screen 2a is obtained.

  The display control unit 6 receives the confrontation interval L obtained by the position calculation unit 7, and changes the enlargement ratio of the X-ray image data to the confrontation interval L. For example, when the image enlargement instruction member 10 is moved away from the monitor display screen 2a by an operator such as a doctor as shown in FIG. 2, the display control unit 6 increases the facing distance L between the image enlargement instruction member 10 and the monitor display screen 2a. Become. As a result, the display control unit 6 greatly varies the enlargement ratio of the X-ray image data as the facing distance L increases.

  In this case, an operator such as a doctor diagnoses an image site of a lesion G such as cancer displayed on the monitor display screen 2a through the annular frame 10a of the image enlargement instruction member 10. The display control unit 6 receives the facing position of the image enlargement instruction member 10 obtained by the position calculation unit 7 with respect to the monitor display screen 2a. This confrontation position corresponds to the image part of a lesion G such as cancer displayed on the monitor display screen 2a. Therefore, the display control unit 6 varies the magnification of the image data of the image part of the lesion G such as cancer based on the position of the image enlargement instruction member 10 on the monitor display screen 2a.

  On the other hand, when the image enlargement instruction member 10 is brought close to the monitor display screen 2a by an operator such as a doctor, the facing distance L between the image enlargement instruction member 10 and the monitor display screen 2a is reduced. As a result, the display control unit 6 changes the magnification rate of the X-ray image data to be smaller as the facing distance L becomes smaller. Also in this case, the display control unit 6 varies the enlargement ratio of the image data of the image part of the lesion G such as cancer based on the position of the image enlargement instruction member 10 facing the monitor display screen 2a.

As a result, if the image enlargement instruction member 10 and the monitor facing distance between the display screen 2a is L ₁ as shown in FIG. 2, the display control unit 6, for example, lesions G such as cancer that have been enlarged by the enlargement ratio N ₁ Are displayed on the monitor device 2. If the facing distance between the image enlargement instructing member 10 and the monitor display screen 2a is L ₂ (> L ₁ ) longer than the facing distance L ₁ , the display control unit 6 has, for example, an enlargement ratio N greater than the enlargement ratio N _{1. 2} The image part of the lesion G such as cancer enlarged by (> N ₁ ) is displayed on the monitor device 2.

  As described above, according to the first embodiment, the image enlargement instruction member 10 is opposed to the monitor display screen 2a that displays the X-ray image data, and the confrontation interval L between the monitor display screen 2a and the image enlargement instruction member 10 is met. Can be enlarged and displayed on the monitor display screen 2a by changing the magnification rate of the image of the lesion G such as cancer. Thereby, an operator such as a doctor can enlarge and display an image of a lesion G such as cancer necessary for interpretation by a simple operation without performing complicated operations such as X-ray image enlargement processing and window processing. Therefore, an operator such as a doctor only has to face the image enlargement instruction member 10 on the monitor display screen 2a. This is similar to enlarging a specific portion of an image drawn on the film by holding the loupe at the time of film diagnosis. It is possible to make a monitor diagnosis with a sense.

Next, a second embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 3 is a block diagram of the image display apparatus. A breast X-ray diagnostic apparatus 20 is connected to the communication line 9. The mammogram X-ray diagnostic apparatus 20 performs tomosynthesis imaging and performs imaging of the subject 4 to acquire a plurality of tomographic image data, that is, tomosynthesis images. The communication line 9 receives a plurality of tomographic image data transmitted from the X-ray apparatus 20. The main control unit 5 stores a plurality of tomographic image data received through the communication line 9 in the image memory 7. FIG. 4 is a schematic diagram of a plurality of tomographic image data. A plurality of these tomographic image data D ₁ , D ₂ ,..., Dn are acquired between the front F side and the rear B of the patient, for example, an internal organ of the subject 4.

  The image enlargement instruction member 10 is provided with an enlargement ratio change mode instruction switch 21 and a cyclic display mode instruction switch 22. The enlargement ratio change mode instruction switch 21 sends out an instruction of an enlargement ratio change mode that permits changing the enlargement ratio when tomographic image data is enlarged and displayed. The cyclic display mode instruction switch 22 sends out a cyclic display mode instruction for cyclically displaying a plurality of tomographic image data.

  The mode determination unit 23 inputs an instruction of the enlargement ratio change mode sent from the enlargement ratio change mode instruction switch 21 or an instruction of the cyclic display mode from the cyclic display mode instruction switch 22, and enlarges the enlargement ratio change mode or cyclic display. The mode is determined as to whether it is a mode, and the result of this mode determination is sent to the display control unit 6.

  While the display control unit 6 is set to the enlargement ratio changing mode, as shown in FIG. 2, the enlargement ratio of one slice of tomographic image data is continuously reduced as the confrontation interval L is narrowed, and as the confrontation interval L is widened. The enlargement ratio of tomographic image data of one slice is continuously varied greatly. Further, the display control unit 6 receives the position of the image enlargement instruction member 10 facing the monitor display screen 2a obtained by the position calculation unit 7, and the monitor display screen 2a facing the image enlargement instruction member 10 based on the position of the confrontation. The enlargement ratio of the image portion of the specific portion of the tomographic image data viewed through the annular frame 10a of the image enlargement instruction member 10 by an operator such as a doctor is changed.

The display control unit 6 cyclically displays a plurality of tomographic image data stored in the image memory 8 on the monitor display screen 2a while being set in the cyclic display mode. In this case, the display control unit 6 increases one of the tomographic directions of the subject 4 as shown in FIG. 4, for example, as shown in FIG. 4, as the facing distance L is increased, that is, as the image enlargement instruction member 10 is moved away from the monitor display screen 2a. The tomographic image data Dn,..., D ₂ , D ₁ are cyclically displayed in the direction from the rear side B to the front side F. The display control unit 6 also adjusts the other tomographic direction of the subject 4 as shown in FIG. 4, for example, as shown in FIG. 4 as the facing distance L becomes smaller, that is, as the image enlargement instruction member 10 is moved closer to the monitor display screen 2a. The tomographic image data D ₁ , D ₂ ,..., Dn are cyclically displayed in a direction from the front F side toward the rear side B.

Next, an image display control operation by the apparatus configured as described above will be described.
The display control unit 6 reads one piece of tomographic image data from the plurality of pieces of tomographic image data stored in the image memory 8 and displays it on the monitor display screen 2 a of the monitor device 2. An operator such as a doctor interprets the tomographic image data displayed on the monitor display screen 2a. At this time, when the enlargement ratio change mode instruction switch 21 is operated by the operator, the mode determination unit 23 inputs the instruction of the enlargement ratio change mode sent from the enlargement ratio change mode instruction switch 21 and enters the enlargement ratio change mode. The setting is sent to the display control unit 6.

  If the image enlargement instruction member 10 is moved away from the monitor display screen 2a by an operator such as a doctor while the enlargement ratio change mode is set, the facing distance L between the image enlargement instruction member 10 and the monitor display screen 2a is increased. As a result, the display control unit 6 greatly varies the enlargement ratio of the tomographic image data as the facing distance L between the image enlargement instruction member 10 and the monitor display screen 2a increases. On the other hand, when the image enlargement instruction member 10 is brought closer to the monitor display screen 2a, the facing distance L between the image enlargement instruction member 10 and the monitor display screen 2a becomes narrower. As a result, the display control unit 6 varies the enlargement ratio of the tomographic image data as the facing distance L between the image enlargement instructing member 10 and the monitor display screen 2a becomes smaller.

When the cyclic display mode instruction switch 22 is operated by the operator, the mode determination unit 23 inputs the instruction of the cyclic display mode sent from the cyclic display mode instruction switch 22 and is set to the cyclic display mode. To the display control unit 6.
When the image enlargement instructing member 10 is moved away from the monitor display screen 2a by an operator such as a doctor during the setting of the cyclic display mode, the display control unit 6 displays, for example, in FIG. 4 as the image enlargement instructing member 10 moves away from the monitor display screen 2a. As shown, the tomographic image data Dn,..., D ₂ , D ₁ are cyclically displayed in the direction from the rear B of the subject 4 to the front F side.

On the other hand, when the image enlargement instructing member 10 is brought close to the monitor display screen 2a by an operator such as a doctor, the display control unit 6 makes the subject 4 as shown in FIG. 4 as the image enlargement instructing member 10 gets closer to the monitor display screen 2a. front F each tomographic image in the direction towards the rear side B from the side data D _1, D _{2, ...,} cyclically displays the Dn.

As described above, according to the second embodiment, the tomographic image data Dn,..., D ₂ , D ₁ of the subject 4 are obtained by moving the image enlargement instruction member 10 away from or close to the monitor display screen 2a. Are cyclically displayed in the order of each tomographic image data Dn,..., D ₂ , D _{1 in} the direction from the rear side B of the subject 4 to the front side F, or from the front side F to the rear side B of the subject 4. The tomographic image data Dn,..., D ₂ , D ₁ can be cyclically displayed in the direction of heading. As a result, the same effects as in the first embodiment can be obtained, and an operator such as a doctor can obtain any one of the tomographic image data Dn,..., D ₂ , D ₁ necessary for diagnosis in a short time. Can be displayed.

Next, a third embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 5 is a block diagram of the image display apparatus. The apparatus processing body 1 is provided with a window selection unit 30. The window selection unit 30 is provided with a plurality of selection end portions for changing the window width (WW) and window level (WL) for the X-ray image data, for example, first to third selection buttons 31 to 33. The first selection button 31 is a button for displaying a portion where the gray level of the X-ray image data is large. The second selection button 32 is a button for displaying a portion where the gray level of the X-ray image data is small. The third selection button 33 is a button for displaying so that the entire X-ray image data can be seen.

  The display control unit 6 has a window width (WW) that becomes a contrast corresponding to the operated first, second, or third selection button 31, 32, or 33 among the first to third selection buttons 31-33. X-ray image data is displayed on the monitor display screen 2a of the monitor device 2 at the window level (WL). In this case, the display control unit 6 automatically changes the window width (WW) and window level (WL) according to the operated first, second or third selection button 31, 32 or 33, and displays the monitor display screen. 2a.

  The display control unit 6 is instructed to specify a specific image part on the monitor display screen 2a displaying X-ray image data with a contrast corresponding to the first, second or third selection button 31, 32 or 33. Then, the X-ray image data of the specific image portion is displayed on the monitor display screen 2a at the window width (WW) and the window level (WL) so that the contrast is adjusted around the specific image portion. Also in this case, the window width (WW) and window level (WL) are automatically changed according to the periphery of a specific image region, and the CT value is converted into a density (gray level) for displaying as a grayscale X-ray image. Displayed on the monitor display screen 2a.

Next, an image display control operation by the apparatus configured as described above will be described.
The display control unit 6 reads out the X-ray image data stored in the image memory 8 and displays it on the monitor display screen 2 a of the monitor device 2. An operator such as a doctor interprets the X-ray image data displayed on the monitor display screen 2a.

  At the time of interpretation, for example, when the operator operates the third selection button 33, the display control unit 6 determines that the third selection button 33 has been operated, and the window corresponding to the third selection button 33 is displayed. X-ray image data is displayed on the monitor display screen 2a of the monitor device 2 at the width (WW) and window level (WL), that is, the window width (WW) and window level (WL) at which the entire image can be seen. FIG. 6 is a schematic diagram showing an example of X-ray image data displayed at a window width (WW) and a window level (WL) where the entire image can be seen. In the case of this X-ray image, for example, the outline of the breast 4 and the mammary gland tissue 4a that develops around the nipple are thinly projected.

  Next, for example, when the operator operates the first selection button 31, the display control unit 6 determines that the first selection button 31 has been operated, and the window width corresponding to the first selection button 31. X-ray image data is displayed on the monitor display screen 2a of the monitor device 2 at (WW), window level (WL), that is, window width (WW) and window level (WL) for displaying a portion with a large gray level. FIG. 8 is a schematic diagram showing an example of X-ray image data displaying a portion with a large gray level. In the case of this X-ray image, for example, the outline of the breast 4 is projected in white with high contrast.

  Next, for example, when the second selection button 32 is operated by the operator, the display control unit 6 determines that the second selection button 32 has been operated, and the window width corresponding to the second selection button 32 is determined. X-ray image data is displayed on the monitor display screen 2a of the monitor device 2 at (WW), window level (WL), that is, window width (WW) and window level (WL) for displaying a portion with a small gray level. FIG. 7 shows a schematic diagram of an example of X-ray image data displaying a portion with a small gray level. If the contrast X-ray image is white, for example, the mammary gland tissue 4a that develops around the nipple is clearly projected.

  As described above, the monitor display screen 2a is displayed with the X-ray image data displayed at the window width (WW) and the window level (WL) corresponding to the first, second or third selection button 31, 32 or 33. In the above, when a specific image part, for example, an image part of a lesion G such as cancer is instructed, the display control unit 6 sets the specific image with a contrast matched to the periphery of the specific image part such as a lesion G such as cancer. The X-ray image data of the part is displayed on the monitor display screen 2a.

  As described above, according to the third embodiment, the first selection button 31 for displaying a portion with a high gray level of X-ray image data and the second for displaying a portion with a low gray level of X-ray image data. And a third selection button 33 that displays the entire X-ray image data so that the entire X-ray image data can be seen, and a window width corresponding to the first, second, or third selection button 31, 32, or 33 (WW), X-ray image data is displayed at the window level (WL). Thereby, in addition to the effect of the first embodiment, an operator such as a doctor can perform an X-ray image with a simple operation of operating the first, second or third selection button 31, 32 or 33. For example, the black part, the white part, or the whole of the data can be displayed.

Next, a fourth embodiment of the present invention will be described with reference to the drawings. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 9 is a block diagram of the image display apparatus. The apparatus processing main body 1 is provided with an image selection unit 40. For example, a mouse 41 is provided in the image selection unit 40. The image selection unit 40 selects, for example, two image parts in response to an operation of the mouse 41 on the monitor display screen 2a displaying X-ray image data.

  The display control unit 6 displays the X-ray image data on the monitor display screen 2a in a density range that matches the density of, for example, two image portions selected by the image selection unit 40. In this case, the display control unit 6 displays the X-ray image data on the monitor display screen 2a by automatically changing the window width (WW) and the window level (WL) according to, for example, the densities of two image portions.

  When the X-ray image data is displayed on the monitor display screen 2a, the display control unit 6 is instructed on the monitor display screen 2a to specify a specific image part, for example, an image part of a lesion G such as cancer. X-ray image data of a specific image region is displayed on the monitor display screen 2a at a window width (WW) and a window level (WL) that match the periphery of the specific image region such as a lesion G such as cancer.

Next, an image display control operation by the apparatus configured as described above will be described.
The display control unit 6 reads out the X-ray image data stored in the image memory 8 and displays it on the monitor display screen 2 a of the monitor device 2. An operator such as a doctor interprets the X-ray image data displayed on the monitor display screen 2a.

At the time of this interpretation, the mouse 41 is operated by the operator, and, for example, two image points P ₁ and P ₂ are selected on the X-ray image displayed on the monitor display screen 2a as shown in FIG. . Point P ₁ is near the surface of breast 4. Point _{P 2} is the mammary gland 4a.

The display control unit 6 performs window processing in a density range that matches, for example, the density of the _two image points P ₁ and P ₂ selected by the image selection unit 40, and displays the window-processed X-ray image data on the monitor. It is displayed on the screen 2a. FIG. 11 is a schematic diagram of X-ray image data that has been subjected to window processing in a density range that matches the density of the image portions at two points P ₁ and P ₂ . In this X-ray image data, the density (gray level) difference between the image points of the two points P ₁ and P ₂ is clearly shown. For example, the part of the mammary gland tissue 4a is projected with high contrast. The part of the breast 4 around the breast tissue 4a is projected with a contrast lower than that of the breast tissue 4a.

Thus, in the state where the X-ray image data showing the gray level between the _two image points P ₁ and P ₂ is displayed, a specific image region such as a lesion such as cancer is displayed on the monitor display screen 2a. When the image part of G is instructed, the display control unit 6 displays the X of the specific image part at the window width (WW) and the window level (WL) around the specific image part such as the lesion G such as cancer. The line image data is displayed on the monitor display screen 2a.

As described above, according to the fourth embodiment, when, for example, two image points P ₁ and P ₂ are selected on the X-ray image on the monitor display screen 2a, these two points P ₁ and P 2 are selected. Window processing is performed in a density range that matches the density of the image part ₂ , and the X-ray image data is displayed on the monitor display screen 2a. Thereby, in addition to the effect of the first embodiment, X-ray image data in which the gray level between the image portions at the two points P ₁ and P ₂ is displayed can be displayed. For example, the part of the mammary gland tissue 4a can be projected with higher contrast than the surrounding part. Since the lesion G such as cancer often develops in the mammary gland tissue 4 a, it is suitable for diagnosis of cancer that develops in the breast 4.

Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.
For example, the display control unit 6 reduces the magnification rate of the X-ray image data as the image enlargement instruction member 10 is brought closer to the monitor display screen 2a, and the X-ray image data as the image enlargement instruction member 10 is moved away from the monitor display screen 2a. The enlargement ratio is greatly varied. On the contrary, the enlargement ratio of the X-ray image data is increased as the image enlargement instruction member 10 is brought closer to the monitor display screen 2a, and the image enlargement instruction member 10 is displayed on the monitor display screen 2a. The magnification rate of the X-ray image data may be changed to be smaller as the distance from the camera increases.

When the display control unit 6 moves away from the monitor display screen 2a during the setting to the cyclic display mode, the tomographic image data Dn,... In the direction from the rear B of the subject 4 to the front F side. , D ₂ , D ₁ are cyclically displayed, and the image enlargement instruction member 10 is brought close to the monitor display screen 2 a, the tomographic image data D ₁ , D _{2 in the} direction from the front F side to the rear side B of the subject 4. .., Dn are cyclically displayed. On the contrary, when the image enlargement instructing member 10 is moved away from the monitor display screen 2a, each tomogram is moved in the direction from the front F side to the rear B of the subject 4. When the image data D ₁ , D ₂ ,..., Dn are cyclically displayed and the image enlargement instruction member 10 is brought close to the monitor display screen 2a, each tomographic image data in the direction from the rear side B of the subject 4 to the front F side. _Dn, ..., _D 2, D ₁ may be displayed cyclically.

A first selection button 31 for displaying a portion with a high gray level of the X-ray image data, a second selection button 32 for displaying a portion with a low gray level of the X-ray image data, and the entire X-ray image data. Although the third selection button 33 for displaying the image is provided, another selection button for contrast may be provided.
X-ray image data is displayed in a density range that matches the density of the image parts at two points P ₁ and P ₂ , but X-ray image data is displayed in a density range that matches the density of the image parts at a plurality of points. Is also possible.
The image enlargement instructing member 10 may be formed such that the annular frame 10a has a size that is easy for an operator such as a doctor to use, or is not limited to an annular shape but may be formed in another shape. Further, if the image enlargement instructing member 10 is formed to have the same weight as the actual loupe, it can be handled in the same manner as using the actual loupe.

1 is a block configuration diagram showing a first embodiment of an image display apparatus according to the present invention. The figure which shows the variable of the expansion ratio of the image according to the opposing space | interval of the image expansion instruction | indication member and monitor display screen in the same apparatus. The block block diagram which shows 2nd Embodiment of the image display apparatus which concerns on this invention. The schematic diagram of several tomogram data in the same apparatus. The block block diagram which shows 3rd Embodiment of the image display apparatus which concerns on this invention. FIG. 3 is a schematic diagram of X-ray image data displayed with an intermediate (overall) contrast in the apparatus. The schematic diagram of an example of the X-ray image data which is displaying the part with a small gray level in the same apparatus. The schematic diagram of an example of the X-ray image data which is displaying the part with a large gray level in the same apparatus. The block block diagram which shows 4th Embodiment of the image display apparatus which concerns on this invention. The schematic diagram which shows two points selected on the monitor display screen in the same apparatus. FIG. 3 is a schematic diagram of X-ray image data subjected to window processing in a density range in accordance with the density of two image parts in the apparatus.

Explanation of symbols

  1: device processing main body, 2: monitor device, 2a: monitor display screen, 3: breast X-ray diagnostic device, 4: subject, 5: main control unit, 6: display control unit, 7: position calculation unit, 8: Image memory, 9: communication line, 10: image enlargement instruction member, 10a: annular frame, 10b: gripping part, 11-1 to 11-4: position sensor, 20: breast X-ray diagnostic apparatus, 21: magnification change Mode indication switch, 22: Cyclic display mode indication switch, 23: Mode determination unit, 30: Window selection unit, 31: First selection button, 32: Second selection button, 33: Third selection button, 40 : Image selection unit, 41: Mouse.

Claims (15)

A display device having a display screen for displaying image data of the subject;
An image enlargement instruction member for confronting the subject image on the display screen when the subject image displayed on the display screen is enlarged and displayed;
A position detection unit for detecting at least a facing interval between the display screen and the image enlargement instruction member;
A display control unit that enlarges and displays the image data displayed on the display screen according to the facing interval detected by the position detection unit;
An image display device comprising:   The image display device according to claim 1, wherein the image enlargement instruction member includes an annular frame and a rod-shaped grip portion provided on the frame. The position detection unit includes a plurality of position sensors provided at each corner of the display screen;
A position calculation unit for obtaining the facing distance and the facing position based on the detection results of these position sensors;
The image display apparatus according to claim 1, further comprising:   The image display device according to claim 1, wherein the display control unit varies an enlargement ratio of the image data in accordance with the confronting interval detected by the position detection unit.   5. The display control unit according to claim 4, wherein the display control unit reduces the enlargement ratio of the image data as the confronting interval decreases, and increases the enlargement ratio of the image data as the confronting interval increases. Image display device.   The image display apparatus according to claim 3, wherein the display control unit varies an enlargement ratio of image data of an image part facing the image enlargement instruction member based on the facing position.   The image display apparatus according to claim 4, wherein the image enlargement instruction member includes an enlargement ratio change mode instruction section that permits a change in an enlargement ratio of the image data. The image data of the subject has a plurality of tomographic image data of the subject,
The image enlargement instructing member has a mode instructing unit in a cyclic display mode,
The display control unit cyclically displays the plurality of tomographic image data on the display device when the cyclic display mode is set by an operation on the mode instruction unit.
The image display device according to claim 1. While the cyclic display mode is set, the display control unit cyclically displays the plurality of tomographic image data toward one tomographic direction of the subject as the confronting interval becomes wider, and the confronting interval becomes narrower. The plurality of tomographic image data is cyclically displayed toward the other tomographic direction that is the opposite direction to the one of the cross-sectional directions as it becomes.
The image display device according to claim 8. The mode instruction unit includes a first mode selection unit that performs cyclic display in one direction, and a second mode selection unit that performs cyclic display in the other direction opposite to the one direction,
When the first mode selection unit is operated, the display control unit cyclically displays the plurality of tomographic image data toward one tomographic direction of the subject, and the second mode selection unit When operated, the plurality of tomographic image data are cyclically displayed toward the other tomographic direction opposite to the one tomographic direction.
The image display device according to claim 8. A plurality of selection ends for changing the window width and window level of the image data,
The display control unit displays the image data on the display device at the window width and the window level corresponding to the operated selection end;
The image display device according to claim 1.   Each selection end displays a first selection end for displaying a portion with a large gray level, a second selection end for displaying a portion with a small gray level, and the entire image data The image display device according to claim 11, further comprising a third selection end for performing the operation. When a specific image region is indicated on the display screen of the display device displaying the image data at the window width and the window level corresponding to the selected end, the display control unit is configured to display the specific image. Displaying the image data of the specific image part on the display device at the window width and the window level according to the periphery of the part;
The image display apparatus according to claim 11. An image selection unit that selects at least two image parts on the display screen displaying the image data;
The display control unit displays the image data on the display screen in a density range in accordance with the density of the at least two image portions selected by the image selection unit;
The image display device according to claim 1. When a specific part is indicated on the display screen displaying the image data,
The display control unit displays the image data on the display device at a density adjusted around the specified specific part.
The image display device according to claim 14.

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