KR20140038777A - Touch-based three-dimensional ultrasonic diagonostic apparatus - Google Patents

Abstract

The present invention relates to a three-dimensional ultrasonic diagnostic device which generates a three-dimensional volume image by combining user-designated areas of two-dimensional volume images scanned by a three-dimensional ultrasonic diagnostic device. The three-dimensional ultrasonic diagnostic device includes: a scan unit which generates two-dimensional volume images of the inside of a human body using ultrasonic signals; a processing unit which generates a three-dimensional volume image by combining user-designated areas of the two-dimensional volume images scanned by the scan unit and controls images to be displayed by recognizing an inputted control signal; a database unit in which the two-dimensional volume images generated by the scan unit and the three-dimensional volume image generated by the processing unit are stored; a display unit which displays one or more among the three-dimensional volume image generated by the processing unit and the two-dimensional volume images generated by the scan unit; and an interface unit which is to receive a control signal for controlling one or more among the two-dimensional volume images and the three-dimensional volume image to be displayed on the display unit. [Reference numerals] (AA) Input; (BB) (a) Two-dimensional volume image observation mode; (CC) (b) Three-dimensional volume image observation mode

Description

Touch-based three-dimensional ultrasonic diagonostic apparatus

The present invention relates to a three-dimensional ultrasonic diagnostic apparatus, wherein the touch-based three-dimensional for converting a two-dimensional volume image corresponding to a region input through a touch interface among one or more two-dimensional volume images scanned by the ultrasonic diagnostic apparatus into a three-dimensional volume image An ultrasonic diagnostic apparatus.

Generally, the ultrasound imaging system detects ultrasound waves from the human body, detects reflected waves from the body, processes them appropriately, and displays the images on the screen. And is widely used in the medical field.

Ultrasonic imaging devices are moving from analog to digital, from 2D ultrasound to 3D, and from ultrasound to 3D imaging, providing stereoscopic real-time video and remote diagnosis through remote volume imaging networks.

However, in the case of a conventionally used 3D ultrasound diagnostic apparatus, all 2D volume images are converted into 3D volume images regardless of a doctor's intention of diagnosing a 2D volume image scanned through a probe into a 3D volume image. Because of the conversion, there is a problem that the amount of computation and data capacity increases, and the time required for conversion takes a lot.

In the process of diagnosing an image converted into a 3D volume image through a display unit, the 3D volume image is enlarged and moved through a mouse and keyboard operation to diagnose the 3D volume image, which is displayed using a mouse and a keyboard. In the case of diagnosing by manipulating the image, it takes a long time to diagnose and it is difficult to recognize the organ of the patient at a glance.

The present invention has been made in order to solve the problems of the prior art as described above is to reduce the volume, the amount of computation and the time required to convert the data when the converted two-dimensional volume image to a three-dimensional volume image.

In addition, another object of the present invention is to observe the organs of the patient displayed by using a touch screen interface at various angles and the desired magnification through a finger touch.

The object of the present invention is to create a three-dimensional volume image by combining a user-specified region of the scan unit for generating a two-dimensional volume image inside the human body using the ultrasonic signal, the two-dimensional volume image obtained through the scanning unit, A processing unit for controlling the displayed image by recognizing an input control signal, a database unit for storing the 2D volume image generated by the scanning unit and the 3D volume image generated by the processing unit, and through the processing unit At least one of the display unit for outputting any one or more of the generated three-dimensional volume image and the two-dimensional volume image generated by the scanning unit and the two-dimensional volume image and the three-dimensional volume image output to the display unit By the interface unit for receiving a control signal for controlling the .

In addition, another object of the present invention is achieved by a touch screen display comprising a touch module.

Therefore, in the process of converting the scanned 2D volume image into the 3D volume image, the 3D ultrasound diagnostic apparatus of the present invention converts the area selected by the user, thereby reducing the time to be converted and the volume of the converted data. have.

In addition, the three-dimensional ultrasound diagnostic apparatus of the present invention can observe the organ of the patient shown on the display at various angles and the desired magnification has the effect of reducing the diagnostic time and the accuracy of the diagnosis.

1 is a block diagram of a three-dimensional ultrasound diagnostic apparatus according to the present invention,
2 is an exemplary diagram of switching from a two-dimensional volume image observation mode to a three-dimensional volume image observation mode according to the present invention;
3 is an embodiment of converting only a region selected by a user into a 3D volume image according to the present invention;
4 is an exemplary diagram of switching from a 3D volume image observation mode to a 2D volume image observation mode according to the present invention;
5 is an exemplary view for adjusting the angle of the displayed three-dimensional volume image according to the present invention,
6 is an exemplary diagram for adjusting the transparency of the displayed organ image according to the present invention;
7 is an exemplary view of shifting the displayed organ image according to the present invention;
8 is an exemplary diagram for adjusting the size of the displayed organ image according to the present invention;
9 is an exemplary view of retake setting of a displayed organ image according to the present invention;
10 is an exemplary diagram for adjusting the sharpness of the displayed organ image according to the present invention;
11 is an exemplary diagram for adjusting the brightness of the displayed long-term image according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

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

1 is a block diagram of a three-dimensional ultrasound diagnostic apparatus according to the present invention. As shown in FIG. 1, a touch-based 3D ultrasound diagnostic apparatus for converting a 2D volume image corresponding to a region input through a touch interface among the one or more 2D volume images scanned by the ultrasound diagnostic apparatus into a 3D volume image. In this regard, the 3D ultrasound diagnostic apparatus combines a region designated by a user among the scan unit 100 and the 2D volume image acquired through the scan unit 100 to generate a 2D volume image inside the human body using an ultrasound signal. The 3D volume image generated by the processor 300 and the processor 300 to control the displayed image by recognizing an input control signal, and the 3D generated by the processor 300. Database unit 400 for storing the volume image, the three-dimensional volume image generated by the processing unit 300 and the two-dimensional generated by the scanning unit 100 Interface unit 500 for receiving a control signal for controlling any one or more of the display unit 200 and the two-dimensional volume image and the three-dimensional volume image output to the display unit 200 to output any one or more of the volume image )

When the sonographer scans an abnormal part of the patient using the scanning unit 100 to generate a 2D volume image, and the doctor who diagnoses observes the 2D volume image and wants to observe the 3D volume image, 2D Instead of converting the entire volume image into a three-dimensional volume image, the processing unit 300 converts the three-dimensional volume image into a three-dimensional volume image and stores the same in the database unit 400.

The database unit 400 is a two-dimensional volume image database 401 for storing the two-dimensional volume image generated by the scan unit 100 and a three-dimensional volume image for storing the three-dimensional volume image generated by the processing unit 300. The volume image database 402 and a buffer 403 for temporarily storing a non-overlapping two-dimensional volume image frame into a three-dimensional volume image.

The interface unit 500 is composed of various physical input devices such as a keyboard, a mouse, a joystick, and the like, as well as a touch screen, to enhance user convenience.

The display unit 200 includes a touch module for recognizing a control signal by a touch, and the touch module used in the display unit 200 uses a projected capacitive type touch module or a direct patterned window touch module. It recognizes more than a finger motion and can use touch modules other than the two touch modules. Projected capacitive type touch module is a module that combines transparent conductive film with OCA (Optically Clear Adhesive) film on LCD display and attaches window on it.Direct patterned window touch module has OCA film under DPW It is a module in which a polarizing film is located underneath and an LCD or LEC display is located under the polarizing film.

The processor 300 recognizes a touch action of one or more fingers and adjusts the angle, movement, transparency, enlargement and reduction, sharpness, brightness, observation mode switching, reshooting, and length of the long-term image output to the display 200. At least one of the measurement and the volume measurement is performed.

2 is an exemplary diagram of switching from a two-dimensional volume image observation mode to a three-dimensional volume image observation mode according to the present invention. As shown in FIG. 2, when the diagnosing doctor wants to observe the 3D volume image in the process of observing the 2D volume image scanned by the scan unit 100, the mode switching interface in the 2D volume image observation mode. When the signal is input, the keypad 600 for inputting the number of 2D volume image frames to be converted into a 3D volume image is popped up by a popup window, and the 3D volume image is input as many as the number of frames input by the diagnostic doctor. The converted 3D volume image is stored in the database unit 400, and the stored 3D volume image is output through the display unit 200 converted to the 3D volume image observation mode. In this case, the input module window for inputting the number of 2D volume image frames may use various methods such as a jog shuttle and a wheel input method in addition to the keypad. In addition to the touch method, a mouse, a keyboard, and a joystick may be used.

When the observation mode switch signal is received, the processing unit 300 searches for the 3D volume image stored in the 3D volume image database 402 of the database unit 400 to generate only the non-overlapping frame region as the 3D volume image. . The observation mode switch signal is an input signal of touching the long-term image output to the display 400 with one finger twice.

3 is an embodiment of converting only a region selected by a user into a 3D volume image according to the present invention. As shown in FIG. 3, the two-dimensional volume image n frames scanned by the scan unit 100 are stored in the two-dimensional volume image database 401 of the database unit 400, and a doctor who diagnoses the two-dimensional volume is provided. While observing the 2D volume image in the image viewing mode, the keypad 600 window for inputting the number of frames to be converted by inputting the observation mode switching signal in the fourth frame is generated as a popup. When the diagnostic doctor inputs 12 frames into the keypad 600 window, the processor 300 searches for the 3D volume image database 402 of the database unit 400 and duplicates the 3D volume image stored with the first selected frame. It will search if it is stored. If there is no data in which 4 to 12 frame areas are converted to 3D volume images in the 3D volume image database 402, 4 to 12 frame areas are converted to 3D volume images and stored in the 3D volume image database 402. The stored 3D volume image is output through the display 400.

When the diagnostic doctor again observes the 2D volume image, inputs the observation mode switching signal in the 8th frame, and inputs the frame number through the keypad 600 to convert the 3D volume image up to the 20th frame. 300 searches the 3D volume image database 402, and in this process, the data obtained by converting a 4 to 12 frame area into a 3D volume image is searched. The processing unit 300 does not convert the overlapped region of the second selected frame and the first selected frame to the 3D volume image, but converts the non-overlapping 13 to 20 frame regions into the 3D volume image. It is temporarily stored in the buffer 403 of the unit 400, and the 4 to 20 frame region is combined with the 4 to 12 frame region, which is the first converted frame region of the 3D volume image database (DB). It is stored at 402. In addition, the diagnosis doctor may observe the 3D volume image of the second selected region, which is the 8 to 20 frame region, through the display unit 400.

In this case, the input module for inputting the number of frames may use various input windows such as jog shuttle and wheel input method in addition to the keypad. The input method may also use various input methods such as a keyboard, a mouse, and a joystick in addition to the touch method.

4 is an exemplary diagram of switching from a 3D volume image observation mode to a 2D volume image observation mode according to the present invention. As shown in Figure 4, when the diagnostic doctor wants to observe the long-term image as a three-dimensional volume image through the three-dimensional volume image observation mode (a) to observe the two-dimensional volume image for the currently displayed angle, the observation mode When the switching signal is input, the 3D volume image observation mode (a) is switched to the 2D volume image observation mode (b). In this case, the observation mode switching signal is a signal of touching the organ of the patient output through the display unit 400 twice with one finger.

5 is an exemplary view for adjusting the angle of the displayed three-dimensional volume image according to the present invention. As shown in Figure 5, when the diagnostic doctor wants to observe the organ image that is currently being observed in the three-dimensional volume image observation mode from a different angle, the angle of the angle to be observed in the state of touching the three-dimensional volume image with one finger When dragging in the direction, the 3D volume image is rotated in the dragging direction. Figures (a) and (c) of FIG. 5 are three-dimensional volume images currently being observed, and images of (b) of FIG. 5 and (a) of FIG. 5 rotated to the right, and (d) of FIG. Currently observed 3D volume image Image (c) of Figure 5 rotated upward.

6 is an exemplary diagram for adjusting the transparency of the displayed organ image according to the present invention. As shown in FIG. 6, when the diagnostic doctor wants to transparently observe a specific area in the long-term image image currently being output through the display unit 400, if a short touch is made with one finger, the touched area is transparent. The transparency of one area is increased. Fig. 6 (a) shows the long-term image that is currently being observed, and Fig. 6 (b) shows an image where the transparency of the touched area is increased by a short touch of one finger.

7 is an exemplary diagram for shifting the displayed organ image according to the present invention. As shown in FIG. 7, when the organ doctor is observing the organ image observed in a desired direction, the direction to move the organ image output through the display unit 400 with two fingers is touched. If you drag to, the organ image observed in the dragged direction is moved. (A) of Figure 7 is a long-term image image that the diagnostic doctor is currently observing. In this image, when the diagnostic doctor touches with two fingers and drags it to the right, the right side of the image is observed as shown in (b) of Figure 7 Will be moved to. (D) of Figure 7 shows the image that is moved upward by dragging upward while touching (c) of Figure 7 with two fingers.

8 is an exemplary diagram for adjusting the size of the displayed organ image according to the present invention. As shown in FIG. 8, when the diagnosis doctor wants to enlarge or reduce the organ image currently being observed, the image is enlarged when the fingers are opened with two fingers touching the organ image output through the display unit 400. If the finger is narrowed while touching with two fingers, the corresponding image is reduced. When you want to enlarge the organ image that the diagnostic doctor is observing in Figure 8 (a), if you open your finger while touching it with two fingers, the organ image you are observing will be enlarged as shown in Figure 8 (b). .

9 is an exemplary view of re-establishment setting of the displayed organ image according to the present invention. As shown in FIG. 9, the diagnosis doctor currently observes a long-term image image that is not clear or blurred, and needs to be re-photographed. In this case, when the long-term image is touched twice by two fingers on the display unit, a re-shooting setting window 700 for re-taking the currently observed image is output. The retake setting window 700 displays the incident angle, frequency, and gain values of the long-term image currently being observed, and the diagnostic doctor or the sonographer inputs the frequency and gain values necessary for the retake. Will be entered.

In addition to the keypad, the input module window used may use various input windows such as a jog shuttle and a wheel input method. The input method may also use various input methods such as a keyboard, a mouse, and a joystick in addition to a touch method.

In the reshoot settings, increasing the frequency value increases the sharpness, reduces the transmittance, and conversely, decreasing the frequency value decreases the sharpness and increases the transmittance. If the gain value is increased, the re-photographed image becomes brighter, and if the gain value is decreased, the re-photographed image becomes darker.

In addition, the organ image generated by re-photographing is changed from the existing organ image and stored in the database unit and converted into a 3D volume image by the processing unit.

10 is an exemplary diagram for adjusting the sharpness of the displayed organ image according to the present invention. As shown in FIG. 10, in order to adjust the sharpness of the organ image which the diagnostic doctor is currently observing, when the organ image output through the display 400 is touched with three fingers, the sharpness is lowered and the right side is dragged. Drag to to increase sharpness. Fig. 9 (a) is the original image. If the original image is dragged to the left while touching with three fingers, the sharpness is lowered as shown in Fig. 9 (b), and when dragged to the right, as shown in Fig. 9 (c) The sharpness is increased.

11 is an exemplary diagram for adjusting the brightness of the displayed long-term image according to the present invention. As shown in FIG. 11, in order to adjust the brightness of the organ image currently observed by the diagnostic doctor, when the organ image output through the display 400 is touched with three fingers, the brightness is darkened and the upper part is dragged downward. Drag it to increase the brightness. (A) in Figure 10 is the original image. If you drag the original image downward with three fingers touching, the brightness becomes dark as shown in (b) of Figure 10. If you drag upward, as shown in (c) of Figure 10 The brightness becomes brighter.

When the organ image output from the display is touched twice with three fingers, the distance measuring mode is activated, and the distance measuring mode is activated with one finger touching one end of the organ to be measured. In this case, the distance to the end point of dragging is displayed on the display, and the volume of the organ is calculated when you touch the organ to be measured twice with one finger among the organs displayed on the display while the distance measuring mode is activated. Will be.

In addition, the method of processing a long-term image performed by the processor according to an input signal by one or more fingers or drags used in the present invention may be changed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Various changes and modifications will be possible.

100: scan unit 200: display unit
300: processing unit 400: database unit
401: two-dimensional volume image DB 402: three-dimensional volume image DB
403: buffer 500: interface unit
600: Keypad 700: Retake setting window

Claims (15)

In the three-dimensional ultrasound diagnostic machine,
A touch-based three-dimensional ultrasound diagnostic apparatus for converting a two-dimensional volume image corresponding to an area input through a touch interface among the one or more two-dimensional volume images scanned by the ultrasonic diagnostic apparatus into a three-dimensional volume image.
The method according to claim 1,
Touch based 3D ultrasound diagnostics
A scan unit for generating a two-dimensional volume image inside the human body using an ultrasonic signal;
A processor configured to combine a region designated by a user among the 2D volume images acquired through the scan unit to form a 3D volume image, and recognize an input control signal to control the displayed image;
A database unit for storing the two-dimensional volume image generated by the scanning unit and the three-dimensional volume image generated by the processing unit;
A display unit configured to output one or more of the three-dimensional volume image generated by the processing unit and the two-dimensional volume image generated by the scan unit; And
Interface unit for receiving a control signal for controlling any one or more of the two-dimensional volume image and the three-dimensional volume image output to the display unit
Touch-based three-dimensional ultrasound diagnostics, characterized in that comprises a.
3. The method of claim 2,
And the display unit is a touch screen display including a touch module for recognizing a control signal by a touch.
3. The method of claim 2,
The database unit
A two-dimensional volume image DB for storing the two-dimensional volume image generated by the scan unit;
A three-dimensional volume image DB for storing the three-dimensional volume image generated by the processing unit; And
A buffer that temporarily converts non-overlapping two-dimensional volume image frames into the three-dimensional volume images and temporarily stores them.
Touch-based three-dimensional ultrasound diagnostics, characterized in that comprises a.
3. The method of claim 2,
And the interface unit includes any one or more of a keyboard, a mouse, a touch screen, and a joystick.
3. The method of claim 2,
When the processor receives an observation mode change signal in the 2D volume image observation mode output to the display unit, the processor generates a 3D volume image by the frame of the region selected by the diagnosis person from the currently observed 2D volume image. The touch-based three-dimensional ultrasound diagnostics, characterized in that for outputting the generated three-dimensional volume image.
The method according to claim 6,
The processor receives the number of frames to be generated as a 3D volume image through the input module window generated as a pop-up on the display unit, and when an observation mode change signal is received, the 3D stored in the 3D volume image DB of the database unit. Touch-based three-dimensional ultrasound diagnostics, characterized in that for generating a three-dimensional volume image of the non-overlapping frame region by searching the volume image.
3. The method of claim 2,
The processor is configured to display a two-dimensional volume image for the currently displayed angle when the observation mode switch signal is received in the three-dimensional volume image observation mode output to the display unit, the observation mode switch signal is output to the display unit Touch-based three-dimensional ultrasound diagnostics, characterized in that the input signal for touching the organ image twice with one finger.
3. The method of claim 2,
The processor recognizes a touch action of one or more fingers and performs at least one of an angle adjustment, movement, transparency adjustment, enlargement and reduction, sharpness adjustment, brightness adjustment, observation mode switching, re-shooting, volume measurement, and length measurement of a long-term image. Touch-based three-dimensional ultrasound diagnostics, characterized in that performing.

10. The method of claim 9,
When the processor receives a drag input while the display unit touches the 3D volume image with one finger, the processor rotates the 3D volume image output to the display unit in the dragged direction, and displays the long-term image. When a short touch input of one finger is received, the touch-based three-dimensional ultrasound diagnostics, characterized in that to increase the transparency of the touched area.
10. The method of claim 9,
When the processor receives a drag input while touching the organ image with two fingers on the display unit, the processor moves the organ of the patient in the dragging direction and the two fingers while touching the organ image with two fingers. When the input for spreading is received, the long-term image image is enlarged, when the input for narrowing the two fingers is received, the long-term image image is reduced,
10. The method of claim 9,
When the input unit receives an input of touching the long-term image twice with two fingers on the display unit, the processor outputs a reshooting setting window for re-taking an image currently being observed, and the reshooting setting window is currently observed. The angle of incidence, frequency, and gain of the long-term image are displayed, and the touch-based 3, characterized in that the input of the frequency and gain to be applied for reshooting using any one or more of the keypad or wheel input. 3D ultrasound diagnostics.
10. The method of claim 9,
When the input unit receives an input dragging to the left while the organ image is touched by three fingers on the display unit, the processor lowers the sharpness, and when the input dragging to the right is received, the processor increases the sharpness and counts the organ image. The touch-based three-dimensional ultrasound diagnostics, characterized in that the brightness is dark when the input is dragged down while the finger is touched, the brightness is bright when the input is dragged upward.
10. The method of claim 9,
The processing unit activates a distance measuring mode when a signal for touching a long-term image twice with three fingers on the display unit is activated, and touches one end of the long-term image to be measured with one finger while the distance measuring mode is activated. When dragging in one state, the distance to the dragged end point is displayed on the display unit, and in the state in which the distance measuring mode is activated, one finger of the organ image to be measured is selected from the organ images output to the display unit. Touch-based three-dimensional ultrasound diagnostics, characterized in that the volume of the organ image is calculated when the double (double) touch.
10. The method of claim 9,
And a method of processing a patient organ image performed by the processor according to at least one of the touch or drag of the one or more fingers.

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