JP3343390B2 - Ultrasound diagnostic equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultrasonic diagnostic apparatus for displaying a region of interest frame on an image.

[0002]

2. Description of the Related Art Conventionally, an ultrasonic diagnostic apparatus sometimes simultaneously displays two or more types of images on a certain diagnostic surface.
For example, as shown in FIG. 11, a B-mode image and a tissue property image may be displayed simultaneously. The B-mode image provides morphological information of an organ in the subject, and the tissue characterization image provides information on physical characteristics. Since the same cross section can be observed and diagnosed from two viewpoints, it is very useful for diagnosing a lesion or the like.

[0003] Further, a frame (region of interest) is displayed in a region on the diagnostic screen to be observed in detail, and the statistics therein are also displayed, so that more detailed diagnostic information in the region of interest frame is obtained. be able to. For example, as shown in FIG.
By setting a region of interest frame on a region to be observed on the tissue characterization diagnostic image (b-1) and displaying a histogram within the frame, the tissue characterization parameters displayed on the image are calculated with a certain degree of spread. At a glance. The region of interest frame is configured to be freely enlarged, reduced, or moved so that the position and size of the region to be observed can be freely selected. The display example of FIG. 11 will be briefly described.

FIG. 11A shows a B-mode image.
(B-1) of FIG. 11 shows a tissue property image. here,
The region-of-interest frame for displaying the histogram on the tissue property image of (b-1) is displayed as a thick straight-line rectangle in the drawing, and the histogram in the region-of-interest frame is displayed as a lower bar graph. The dotted line in the figure is a provisional frame for giving the user information to know the size of the target region of interest when changing the size of the region of interest frame. When the dotted-line area frame becomes large to the size desired to be observed, the user gives an instruction to determine the frame, thereby expanding the ROI frame as shown in FIG. 2B and observing the histogram at that time. . (A-2) is a corresponding B-mode image of the (b-2) screen.

[0005] By setting the region of interest frame in this way and displaying statistics such as histograms in the frame, it is possible to see at a glance how wide the tissue property parameter, which is information on physical characteristics, is calculated. Understand, the extent of the spread also becomes diagnostic information and is very useful.

[0006]

The above-mentioned conventional FIG.
In the example, the B-mode image and the tissue property image are simultaneously displayed on the screen, the region of interest is set only on the tissue property image, and the histogram, which is one of the statistics, is displayed in a bar graph as shown in the lower part. Therefore, for example, there is a problem that it is difficult to determine where a region of interest on a tissue property image falls in a B-mode image that provides morphological information. In addition, a tissue property image is often calculated using surrounding data in which one calculated point is spatially spread, and there is a problem in that the range of actually used data cannot be determined.

[0007] The present invention solves these problems,
Display multiple images at the same time to display the region of interest frame on each image, enlarge or reduce the specified region of interest frame,
In response to the movement, enlarge / reduce and move the other region of interest frame, set the size of the region of interest frame to indicate the same region for multiple images with different magnifications, An object of the present invention is to display a used data area frame indicating a range of original data used to generate an image, and to make it easier to observe a correspondence relationship between regions of interest set on a plurality of different images.

[0008]

FIG. 1 is a block diagram showing the principle of the present invention. In FIG. 1, an image processing unit 2 transmits various types of images (B) based on signals returned by transmitting ultrasonic waves to a subject.
Mode image, tissue property image, three-dimensional image, cross-sectional image).

The region-of-interest control unit 3 controls the display, movement, enlargement / reduction, etc. of the region-of-interest frames 11 on each of the plurality of images displayed on the display 9. The display control unit 8 displays a plurality of images and the region of interest frame 1 on the display 9.
1 to control the display.

The display 9 displays a plurality of images .
At the same time, on the plurality of images ,
The original data used to generate the image data on the region of interest 11
And a use data area frame 12 indicating a data area .

[0011]

According to the present invention, as shown in FIG. 1, a transmission / reception unit 1 transmits an ultrasonic pulse into a subject and obtains a reception signal obtained by reflection in the subject. By processing the received signal, a plurality of images (B mode image, tissue property image, 3
The display control unit 8 displays a plurality of images on the display 9 and, based on an instruction from the region of interest control unit 3, displays the region of interest frame 11 on the plurality of images. In addition, a statistic in the region of interest 11 is displayed, and the region of interest 11 on another image is moved in response to the movement of the region of interest 11 on one of the images.

A region of interest frame 11 on any image
Region of interest 11 on another image corresponding to the enlargement or reduction of
Is enlarged or reduced to a corresponding size. At this time, a B-mode image and a tissue property image are included as at least one screen as a plurality of images, and statistics in the region of interest 11 on the tissue property image are displayed.

Further, a plurality of images include at least one screen including a three-dimensional image and a cross-sectional image, and statistics of the cross-sectional image in the region of interest frame 11 are displayed. When the region of interest frame 11 is displayed, the region of interest frame 1
1, a use data area frame 12 indicating the area of the received signal data used for generating the image data is also displayed.

When a plurality of images have the same magnification, the same region of interest 11 is displayed on each image. On the other hand, when a plurality of images are different, the region of interest corresponding to the same region on each image is displayed. 11 is displayed.

Accordingly, a plurality of images are simultaneously displayed to display the region of interest frame on each image, or the other region of interest frames are enlarged or reduced in response to enlargement / reduction or movement of the designated region of interest frame. , Move, set the size of the region of interest frame to indicate the same region for multiple images with different magnifications, and indicate the range of the original data used to generate the image on the region of interest frame By displaying the used data area frame, it is possible to easily observe the correspondence between the interest areas set on a plurality of different images.

[0016]

Next, the configuration and operation of an embodiment of the present invention will be sequentially described in detail with reference to FIGS.

FIG. 1 is a diagram showing the principle of the present invention. FIG.
In, the transmission / reception unit 1 transmits an ultrasonic wave to a subject or receives an ultrasonic wave reflected and returned from the subject. At this time, the transmission and reception of the ultrasonic pulse are sequentially repeated in a fan shape as shown in the figure to obtain a tomographic image.

The image processing unit 2 performs signal processing based on the signal received by the transmission / reception unit 1, and generates a B-mode image 4, a tissue property image 5, a three-dimensional image 6, and a cross-sectional image 7 here. Things.

The B-mode image 4 is an image in which the intensity of a signal (reception signal) when an ultrasonic pulse is transmitted to the subject and returned is displayed as an image. The tissue property image 5 is an image indicating the degree of attenuation of the received signal.

The three-dimensional image 6 is an image in which tomographic images are sequentially superimposed and displayed (see FIG. 9). The cross-sectional image 7 is a three-dimensional image 6
5 is an image displaying an arbitrary cross section of FIG. Region of interest control unit 3
Displays the region of interest frame 11 and the used data region frame 12 on an image, and when the region of interest 11 is moved, enlarged, reduced, etc. on a certain image, similarly moved on another image, It expands and contracts.

The display controller 8 controls the display of an image, a region of interest frame 11, a used data region frame 12, and a histogram which is one of the statistics on the display 9. The statistic 1 includes an average value, a variance (standard deviation), and the like, in addition to the histogram described below.

The display 9 displays an image and the like. Hereinafter, various aspects of the present invention will be described.
Area of interest between the area of interest frame and the used data area frame
Although there is an embodiment in which the frame is described, the present invention
Also in the case of the mode, as shown in FIG.
Display the area of interest frame and the used data area frame together
It is. Next, the operation of the configuration of FIG. 1 in the case of enlarging, reducing and moving the region of interest 11 when two images of the same magnification are displayed in accordance with the order shown in the flowchart of FIG. This will be described in detail with reference to FIG.

In FIG. 2, S1 transmits. In this case, the transmitting / receiving unit 1 in FIG. 1 transmits an ultrasonic pulse toward the subject. S2 receives. This is to receive a signal returned by the ultrasonic pulse transmitted in S1 being reflected by the subject.

At step S3, a B-mode image is displayed. this is,
An image (B-mode image) corresponding to the strength of the received signal received in S2 is displayed on the display 9, for example, as shown in FIG.
(A-1).

In step S4, the position (XL, Y
L) and size (WL, HL). This is because, for example, on the B-mode image displayed on the screen in S3, the operator can set the upper left position (XL, YL) and size (WL) of the region of interest frame 11 on the B-mode image of (a-1) in FIG. , HL)
Instruct.

In step S5, the region of interest frame 11 is displayed on the B-mode image. This corresponds to the upper left position (X
A region of interest frame 11 of size (WL, HL) is displayed at (L, YL) (see (a-1) in FIG. 3 and (a-1) in FIG. 4).

In step S6, the region of interest 11 is displayed on the tissue property image.
Is displayed. This is as shown in (b-1) of FIG.
The region of interest frame 11 is displayed at a corresponding position on the tissue property image.

In step S7, a histogram is displayed. In this case, a histogram is calculated based on the data in the region of interest frame 11 displayed in S6, and the histogram of the lower bar graph in FIG. 3B-1 is displayed.

In S8, when there is a change in the region of interest frame 11, the process returns to S4 and is repeated. This change of the region of interest 11 is performed, for example, when the operator issues a change instruction on the screen with a mouse or the like for the region of interest 11 of (a-1) and (b-1) of FIG. a-2), (b-
As shown in 2), the region of interest frame 11 is changed (for example, enlarged).

As described above, the B-mode image and the tissue property image are simultaneously displayed on the display 9 based on the signal transmitted from the ultrasonic pulse, reflected from the subject, and returned.
On any image (here, on the B-mode image), the position and size of the region of interest 11 are designated, or the region of interest 11 is designated on the image in response to the change, enlargement, or reduction. In addition to displaying the position and size, or the position and size corresponding to the change, enlargement, and reduction, the region of interest frame 11 is displayed at the position and size on another image, and the histogram in the region of interest frame 11 is displayed. By these,
A region of interest frame 11 representing the same region is displayed on a plurality of images (B-mode image, tissue property image) displayed on the screen, and when the position or size is changed on any of the images, the other region is automatically displayed. Region of interest 11 at the corresponding position and size on the image
Is displayed, the corresponding position can be easily observed.

FIG. 3 shows a display example (part 1) of the present invention. This shows an example in which a B-mode image and a tissue property image of the same magnification are displayed on the display 9. FIG. 3A-1 shows an example in which the region of interest frame 11 is displayed on the B-mode image.

FIG. 3 (b-1) shows an example in which a region of interest frame 11 is displayed on a tissue property image, and a histogram in the region of interest frame 11 is calculated to display a histogram of a bar graph. These (a-1) and (b-1) correspond to the upper left position (XL, YL) of the region of interest 11 on any screen.
And sizes (WL, HL) are displayed on both images in response to the designation. At this time, a histogram in the region of interest 11 on the tissue property image (b-1) is obtained and displayed as a bar graph as shown in the figure.

In the state where the solid line region of interest 11 of (a-1) and (b-1) of FIG. 3 is displayed, the operator, for example, displays the solid line of interest on the B-mode image of (a-1). When the region of interest 11 is instructed to be enlarged with the mouse to the region of interest 11 indicated by a dotted line, the region of interest 11 is automatically enlarged as shown in (a-2) and (b-2) of FIG. , (B-2), the histogram in the region of interest frame 11 is calculated, and the histogram of the illustrated bar graph is displayed.

FIG. 3A-2 shows an example in which the region of interest 11 is enlarged on the B-mode image. (B-2) of FIG.
An example is shown in which a region of interest frame 11 is enlarged and displayed on a tissue property image, a histogram in the enlarged region of interest frame 11 is calculated, and a histogram of a bar graph is displayed.

As described above, the region of interest frame 11 is displayed on the B-mode image of (a-1) and the tissue property image of (b-1), respectively, and the region of interest frame 11 of (b-1) is displayed. In the state where the histogram of the data in is displayed, for example, (a
When the operator enlarges the region of interest 11 on the B-mode image of -1) to the region of interest 11 indicated by a dotted line, the region of interest 11 is enlarged and displayed as shown in (a-2) and (b-2). , And (b-2) the histogram of the data in the enlarged region of interest 11 is displayed. As a result, when the operator enlarges any one of the regions of interest 11 on a plurality of images, the region of interest 11 on other images is automatically enlarged, and the histogram of the data in the enlarged region of interest 11 is automatically displayed. It is possible to display it in a typical manner.

FIG. 4 shows a display explanatory diagram of the present invention. This is an explanatory diagram for displaying the region of interest frame 11 when displaying two images of the same magnification. (A-1) of FIG.
(B-1) shows an example in which two images of the same magnification are displayed. Here, it is assumed that the origin (0, 0) is set to the upper left and two images are displayed at a distance of Xoffset. And
The region-of-interest frame 11 on the left image has the following positions: upper left position (XL, YL) size (WL, HL) The region of interest 11 on the image on the right side is: (1) an upper left position (XR, YR); In this way, the region of interest 1 on the right image
The value of 1 can be calculated as shown below.

XR = XL + Xoffset YR = YL WR = WL HR = HL FIGS. 4 (a-2) and (b-2) show enlarged regions of interest 11 on two images of the same magnification. Show the situation. here,
This is when the solid line region of interest 11 is enlarged to the dotted line region of interest 11 on the image of FIG.

Next, the operation of the configuration of FIG. 1 in the case of enlarging, reducing and moving the region of interest 11 when two images of different magnifications are displayed in accordance with the order shown in the flowchart of FIG. This will be described in detail with reference to FIG.

In FIG. 5, S11 transmits. In this case, the transmitting / receiving unit 1 in FIG. 1 transmits an ultrasonic pulse toward the subject. In step S12, the information is received. This is to receive a signal returned by the ultrasonic pulse transmitted in S11 being reflected by the subject.

In step S13, a B-mode image is displayed. This means that an image (B-mode image) is displayed on the display 9 corresponding to the strength of the received signal received in S12, for example, as shown in (a-1) of FIG.

In step S14, an enlarged area is selected. In this case, for example, an enlarged area frame 13 to be enlarged is selected on the B-mode image in (a-1) of FIG. 6 (the upper left position and the lower right position are indicated by a mouse). This corresponds to the position (X at the upper left of the enlarged area frame 13 on the image (a-1) in FIG.
1, Y1) and size (W1, H1).

In step S15, the position (XL,
YL) and size (WL, HL). This is because, for example, on the B-mode image displayed on the screen in S13, the operator sets the region of interest frame 1 on the B-mode image of (a-1) in FIG.
1 indicates the upper left position (XL, YL) and the size (WL, HL).

In step S16, the region of interest 11 is displayed on the B-mode image.
Is displayed. This means that the region of interest frame 1 of size (WL, HL) is located at the upper left position (XL, YL) designated in S15.
1 is displayed (see (a-1) of FIG. 7).

In step S17, the region of interest frame 1 is displayed on the tissue property image.
1 is displayed. This displays the region of interest frame 11 at a corresponding position on the tissue property image of (b-1) in FIG. 6 in which the enlarged region selected in S14 is enlarged.

In step S18, a histogram is displayed. In this case, a histogram is calculated based on the data in the region of interest frame 11 displayed in S17, and the histogram of the lower bar graph in (b-1) of FIG. 6 is displayed.

In S19, when there is a change in the region of interest frame 11, the process returns to S15 and is repeated. This region of interest frame 1
For example, when the operator issues a movement instruction on the screen with a mouse or the like for the region of interest 11 in (a-1) and (b-1) in FIG. 6, (a-2) in FIG. , (B
The region of interest 11 is moved as shown in -2).

As described above, the B-mode image shown in (a-1) of FIG. 6 is displayed on the display 9 on the basis of the signal transmitted from the ultrasonic pulse, reflected from the subject, and returned to the region of interest. In response to the selection of the frame 11 and the enlarged region frame 13, the tissue property image in the enlarged region frame 13 is displayed as (b) in FIG.
As shown in -1), the display and the region of interest frame 11 are displayed, and a histogram is displayed based on the data in the region of interest frame 11. In this state, for example, (a-1) of FIG.
In response to the movement of the region-of-interest frame 11 by the operator on the B-mode image, the region-of-interest frame 11 is moved as shown in FIGS. 6 (a-2) and (b-2). A histogram is displayed based on the data in the region of interest frame 11 in the movement and (b-2), respectively. With these, a plurality of images (B-mode image, tissue property image) on the screen
When the magnifications are different, the region of interest frame 11 corresponding to the same region can be displayed, and a histogram of the data in the region of interest 11 can be displayed.

FIG. 6 shows a display example (part 2) of the present invention. This shows an example in which a B-mode image and a tissue property image at different magnifications are displayed on the display 9. FIG.
(A-1) shows an example in which the region of interest frame 11 and the enlarged region frame 13 are displayed on the B-mode image.

FIG. 6 (b-1) shows a tissue property image in the enlarged area frame 13 of (a-1), and displays a region of interest frame 11 on this image. The example which displayed the histogram of the bar graph by calculating the histogram is shown.

In the state in which the thick solid line region of interest 11 shown in FIGS. 6A and 6B is displayed, the operator, for example, displays a thick solid line on the B-mode image of FIG. When the mouse is instructed to move the interested region frame 11 to the dotted region of interest 11 with the mouse, the interested region frame 11 is automatically moved as shown in (a-2) and (b-2) of FIG. Along with
The histogram in the region of interest 11 of (b-2) is calculated, and the histogram of the illustrated bar graph is displayed.

FIG. 6A-2 shows an example in which the region of interest frame 11 is moved on the B-mode image. (B-2) of FIG.
An example is shown in which the region of interest frame 11 is moved and displayed on the tissue property image, and a histogram in the moved region of interest frame 11 is calculated to display a histogram of a bar graph.

As described above, the corresponding regions of interest 11 are displayed on the B-mode image of (a-1) and the tissue property image of (b-1), respectively, and the region of interest of (b-1) is displayed. For example, in a state where the histogram of the data in the frame 11 is displayed, when the operator moves the region of interest 11 on the B-mode image of (a-1) to the region of interest 11 indicated by the dotted line, (a-
The region of interest 11 is moved and displayed as shown in 2) and (b-2), and a histogram of the data in the moved region of interest 11 shown in (b-2) is displayed. As a result, when the operator moves any of the region of interest 11 on a plurality of images, the region of interest 11 on another image automatically moves, and the histogram of the data in the moved region of interest 11 is automatically displayed. It is possible to display it in a typical manner.

FIG. 7 is an enlarged explanatory view of the present invention. This is to explain the display when the region of interest 11 corresponding to the same region is displayed on images of different magnifications and the region of interest 11 is moved.

FIG. 7A-1 shows a certain image (for example, B
An example in which a region of interest frame 11 and an enlarged region frame 13 are displayed on a (mode image) is shown. Here, the enlarged area frame 13 is determined by designating an upper left position (X1, Y1) and a size (W1, H1).

The region of interest frame 11 is determined by designating an upper left position (XL, YL) and a size (WL, HL).

FIG. 7 (b-1) shows an enlarged image (for example, a tissue property image) in the region of interest 13 in (a-1) and calculates a corresponding histogram in the region of interest 11 in FIG. Here is an example of the display.

Here, the enlarged area frame 13 is determined by designating an upper left position (X2, Y2) and a size (W2, H2).

Here, the region of interest frame 11 is determined by designating an upper left position (XR, YR) and a size (WR, HR).

In the state where (a-1) and (b-1) of FIG. 7 are displayed, for example, when the region of interest 11 on the image of (a-1) is moved to the lower left, (a) of FIG. -2), (b-
It is displayed as shown in 2).

FIG. 7A-2 shows an example in which the region of interest 11 is moved to the lower left on the image of FIG. 7A and displayed.
(B-2) of FIG. 7 shows an example in which the region of interest 11 is displayed on the image of (a-1) in consideration of the enlargement ratio in response to the movement to the lower left.

Here, the position of the region of interest 11 on the enlarged image of (b-2) is obtained as shown below. Woffset = W1 / W2 Hoffset = H1 / H2 WR = WL / Woffset HR = HL / Hoffset (XR-X2) = (XL-X1) / Woffset (YR-Y2) = (YL-Y1) / Hoffset Here, the region of interest frame 11 of (b-2) in FIG. 7 is as shown in the drawing: • Upper left position (WR, YR) and size (WR, HR).

Next, according to the order shown in the flowchart of FIG. 8, when two images of different magnifications are displayed, the operation of the configuration of FIG. This will be described in detail with reference to FIG.

In FIG. 8, S31 transmits. In this case, the transmitting / receiving unit 1 in FIG. 1 transmits an ultrasonic pulse toward the subject. In step S32, the information is received. In this case, the ultrasonic pulse transmitted in S31 is received by the object and reflected and returned.

In step S33, a three-dimensional image is displayed. this is,
An image (for example, a B-mode image) corresponding to the intensity of the received signal received in S32 is displayed as a three-dimensional image while being sequentially shifted on the display 9, for example, as a three-dimensional image as shown in (a-1) of FIG. I do.

In step S34, a cross section is selected. This means that, for example, one cross section is selected on the three-dimensional image of (a-1) in FIG.
For example, one thick line on the three-dimensional image of (a-1) is selected.

At step S35, the position (XL,
YL) and size (WL, HL). This is because, for example, on the three-dimensional image displayed on the screen in S33, the operator indicates the upper left position (XL, YL) of the region of interest 11 on the three-dimensional image of (a-1) in FIG. Size (W
L, HL).

In step S36, the region of interest 11 is displayed on the B-mode image.
Is displayed. This is because the region of interest frame 1 of size (WL, HL) is located at the upper left position (XL, YL) designated in S35.
1 is displayed (see (a-1) of FIG. 9).

In step S37, the region of interest frame 1 is displayed on the tissue property image.
1 is displayed. This displays the region of interest frame 11 at a corresponding position on the cross-sectional image of (b-1) of FIG. 9 displaying the cross-section selected in S34.

In step S38, a histogram is displayed. In this case, a histogram is calculated based on the data in the region of interest frame 11 displayed in S37, and the histogram of the lower bar graph in FIG. 9B-1 is displayed.

In S39, when there is a change in the region of interest frame 11, the process returns to S35 and is repeated. This region of interest frame 1
For example, when the operator instructs to move the region of interest 11 on the screen with a mouse or the like with respect to the region of interest 11 shown in (a-1) and (b-1) of FIG.

As described above, the three-dimensional image shown in (a-1) of FIG. 9 is displayed on the display 9 on the basis of the signal returned from the subject by transmitting the ultrasonic pulse and reflecting the signal. In response to the selection, a cross-sectional image of the selected cross-section is displayed as shown in (b-1) of FIG.
1 and a histogram is displayed based on the data in the region of interest frame 11. Further, in this state, corresponding to the fact that different sections are selected by the operator on the three-dimensional image of (a-1) of FIG. 9, (a-2) and (b-2) of FIG. As described above, a cross-sectional image of a different cross-section is displayed and a histogram is displayed. With these, it is possible to display the region of interest frame 11 on each of a plurality of images (three-dimensional image, cross-sectional image) on the screen and display a histogram of data in the region of interest 11 of the cross-sectional image of the selected cross-section. Becomes

FIG. 9 shows a display example (part 3) of the present invention. This shows an example when a cross-sectional image and a histogram of one cross section on a three-dimensional image are displayed on the display 9. (A-1) of FIG. 9 illustrates an example in which a plurality of images are shifted and displayed three-dimensionally as a three-dimensional image and the region of interest frame 13 is displayed.

FIG. 9 (b-1) shows an example in which a sectional image of one section of the three-dimensional image of (a-1) is displayed, and the region of interest frame 11 and its histogram are displayed. (A) of FIG.
In the state in which the region of interest frame 11 of the thick solid line of (-1) and (b-1) is displayed, the operator, for example, (a-1)
When another cross section is selected on the three-dimensional image of FIG.
2) As shown in (b-2), a cross-sectional image in which a cross-section is selected is displayed, and a histogram in the region of interest frame 11 is calculated and displayed.

FIG. 9A-2 shows an example in which another section is selected on the three-dimensional image. (B-2) of FIG.
An example is shown in which the cross-sectional image selected in 2) and the histogram in the region of interest frame 11 are calculated and displayed as a histogram of a bar graph.

As described above, the region of interest frame 11 is displayed on the three-dimensional image of (a-1) and the cross-sectional image of a certain cross section of (b-1), and the region of interest frame (b-1) is displayed. In the state where the histogram of the data in 11 is displayed, (a-1)
When another section is selected by the operator on the three-dimensional image, the selected section is displayed and the histogram is displayed as shown in (a-2) and (b-2). Thus, it is possible to display a cross-sectional image of an arbitrary cross-section on a three-dimensional image and automatically display a histogram of data in the region of interest 11.

FIG. 10 shows a display example (part 4) of the present invention. This is because, in addition to the region of interest 11, the used data region 1
This is an example in which 3 is also displayed. (A-1) of FIG.
3 shows a B-mode image. Position (XL, YL) and size (WL, HL) designated by the operator on this B-mode image
, The region of interest frame 11 is displayed, and the data region of use frame 13 is also displayed.

FIG. 10 (b-1) shows a tissue property image. On this tissue property image, a region of interest 11 corresponding to the region of interest 11 in (a-1) is displayed, and when a histogram is calculated using data in the region of interest 11, the histogram is used. Since it is necessary to use outer data when calculating points on the boundary, the area of the used outer data is determined and displayed as the used data area frame 13 shown in the figure. The displayed use data area frame 13 is also displayed on (a-1) of another B-mode image.

(A-2) and (b-2) of FIG.
A state of enlarged display of the region-of-interest frame 11 and the used data region frame 13 when the region-of-interest frame 11 is enlarged on the B-mode image of -1) is shown.

As described above, by displaying the used data region frame indicating the range of the original data used to generate the image on the region of interest frame, the range of the original data used for the histogram is displayed on each image. Observation can be easily performed.

[0080]

As described above, according to the present invention,
Multiple images are displayed at the same time, and the region of interest frame and
Display and use data area frame , respectively, and enlarge / reduce / move the other area of interest frame in response to enlargement / reduction / movement of the specified area of interest frame, and the same for multiple images with different magnifications since it uses the squirrel Ru configuration was set the size of the region of interest frame <br/> to indicate areas liable ultrasound observation and different set regions of interest in the image on the corresponding relationship A diagnostic device can be provided.

[Brief description of the drawings]

FIG. 1 is a principle configuration diagram of the present invention.

FIG. 2 is a flowchart of enlargement / reduction / movement of the same magnification according to the present invention.

FIG. 3 is a display example (part 1) of the present invention.

FIG. 4 is a display explanatory diagram of the present invention.

FIG. 5 is a flowchart of enlargement / reduction / movement of different magnifications according to the present invention.

FIG. 6 is a display example (2) of the present invention.

FIG. 7 is an enlarged explanatory view of the present invention.

FIG. 8 shows simultaneous enlargement / reduction / three-dimensional image / cross-sectional image of the present invention.
It is a flowchart of a movement.

FIG. 9 is a display example (part 3) of the present invention.

FIG. 10 is a display example (part 4) of the present invention.

FIG. 11 is a conventional display example.

[Explanation of symbols]

 1: Transmission / reception unit 2: Image processing unit 3: Region of interest control unit 4: B-mode image 5: Tissue property image 6: Three-dimensional image 7: Cross-sectional image 8: Display control unit 9: Display 11: Region of interest 12: Use Data area frame 13: Enlarged area frame

──────────────────────────────────────────────────続 き Continuation of front page (56) References JP-A-63-122437 (JP, A) JP-A-2-196383 (JP, A) JP-A-59-20155 (JP, A) JP-A-3-3 23845 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) A61B 8/00-8/15 A61B 6/00-6/14 A61B 5/05

Claims (5)

(57) [Claims] An ultrasonic pulse is transmitted into a subject, a plurality of images are generated by processing a reception signal obtained by reflection in the subject, and the image or the image is formed on the image. In an ultrasonic diagnostic apparatus for displaying a region of interest frame for calculating a statistic of original data to be generated, a region of interest frame (11) and image data on the region of interest frame (11) are displayed.
Used data area indicating the area of the original data used for data generation
In addition to displaying both the region frame (12) on a plurality of images, and corresponding to the movement of the region of interest frame (11) on one of the images, the region of interest frame (11) on another image is supported. An ultrasonic diagnostic apparatus, wherein the ultrasonic diagnostic apparatus is configured to move to the same position. 2. An ultrasonic pulse is transmitted into a subject, a plurality of images are generated by processing a reception signal obtained by reflection in the subject, and the image or the image is formed on the image. In an ultrasonic diagnostic apparatus for displaying a region of interest frame for calculating a statistic of original data to be generated, a region of interest frame (11) and image data on the region of interest frame (11) are displayed.
Use indicating the area of the received signal data used for data generation
Both the data area frame (12) and the data area frame (12) are displayed on a plurality of images. )
An ultrasonic diagnostic apparatus characterized in that the ultrasonic diagnostic apparatus is configured to be enlarged or reduced to a corresponding size. 3. The method according to claim 2, wherein the plurality of images include at least one screen including a B-mode image and a tissue property image, and a statistic in the region of interest frame (11) on the tissue property image is displayed. The ultrasonic diagnostic apparatus according to claim 1 or 2, wherein: 4. The apparatus according to claim 1, wherein the plurality of images include at least one screen including a three-dimensional image and a cross-sectional image, and a statistic of the cross-sectional image in the region of interest frame (11) is displayed. The ultrasonic diagnostic apparatus according to claim 1 or 2. 5. When the plurality of images have the same magnification, each image is
Display the same region of interest frame (11) on the image, while
When the magnifications of the images are different, the same area on each image
Either one response to the region of interest frame that has been configured to display (11) from claim 1, wherein according to claim 4 1
An ultrasonic diagnostic apparatus according to any of the preceding claims.