JPH08336532A - Ultrasonic diagnostic system - Google Patents

Abstract

PURPOSE: To improve operability and diagnostic efficiency by simplifying the change of an image condition in a screening test. CONSTITUTION: The image condition is stored in an image condition memory circuit 64 at every step in sequence of execution of a main controller via a panel I/F circuit 62. The main controller executes the image condition in every step and obtains an image by reading out a stored image condition by the operation of a multi-operation controller 65, setting it on the main controller via a panel controller 63, and starting photographing. In this way, it is possible to change the image condition of photographing in every step in the screening test with a simple operation, which improves the operability.

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 and, more particularly, to a screening test for conducting a series of tests by changing various test modes, test conditions such as focus depth, and image processing conditions such as dynamic range. The present invention relates to a suitable ultrasonic diagnostic apparatus.

[0002]

2. Description of the Related Art An ultrasonic diagnostic apparatus transmits ultrasonic waves to a subject 20 with a probe 10 and receives ultrasonic waves reflected from the subject 20. This transmission / reception is controlled by the transmission / reception circuit 30. The ultrasonic wave received by the probe 10 is input to the signal processing circuit 40 via the transmission / reception circuit 30, is subjected to signal processing such as delay, and is then converted into a digital signal by the A / D converter 51. This digital signal is written / read-controlled to the line memory by the scan converter 52, further stored in the image memory, the data in the image memory is converted into an analog signal by the D / A converter 53, and an ultrasonic image is displayed on the display 70. indicate.

Transmission / reception circuit 30 and scan converter 5
2 is controlled by the main controller 54. When obtaining an ultrasonic image with such a device, first, some image conditions are set by the operation panel 61,
This set value is input to the transmission / reception circuit 30 via the main controller 54 to control the ultrasonic waves from the probe 10. For setting image conditions, various settings such as a display depth of 18 cm in B mode and area calculation on one screen are selected directly on the operation panel 61 or from a menu screen displayed on the display 70. It was

[0004]

In the above-mentioned conventional apparatus, the operation panel 61 is used to set the image conditions necessary for obtaining an image.
Since it is selected directly from the menu screen displayed on the display 70, the operation is complicated. In addition, since the contents that are frequently used (changed) differ depending on the user, if such frequently used contents are selected on the menu screen, the operation takes a long time. Also, when measuring the area or distance of the diagnostic region from the image, the software for measurement cannot be set before imaging, and the software for measurement can be executed only after freezing the image,
It was annoying.

Further, when performing a screening test in which a plurality of images are taken with different image conditions or shooting positions, it is necessary to set image conditions that are changed for each shooting. That is, the first image condition is selected from the operation panel 61 or the menu screen, and the image condition that is not changed at the time of setting the next image condition remains unchanged and only the image condition that is changed is selected. For the second and subsequent images, it is only necessary to select the image conditions to be changed. However, if the number of image conditions to be changed is large and the number of selections on the menu screen is large, not only the operation becomes complicated like the above, but also the change is required. The time is long and the diagnosis efficiency is low.

As described above, in order to eliminate the complication of the operation due to the change on the menu screen, the image condition according to the menu screen which is frequently changed is registered in the function key of the operation panel 61, and the image condition can be set by pressing the function key. There are things that can be changed, but if there are many imaging tests to be performed and the number of image conditions to be changed, the number of operations will end up being large, and not only will diagnostic efficiency drop due to complications, but you may forget to change them. There was a fear that the image of would not appear. Moreover, if the order of operations is wrong in the image conditions, the target image may not appear, and in a screening test in which there are many image conditions to be changed, it becomes inevitable to be cautious, resulting in poor operability.

Therefore, an object of the present invention is to simplify the change of the image conditions in the screening test and to improve the operability and the diagnostic efficiency.

[0008]

In order to achieve the above object, the present invention provides a probe for transmitting and receiving ultrasonic waves, a signal processing circuit for performing delay processing and addition on the received ultrasonic signals, and a signal. A scan converter that converts the processed ultrasonic signal into an image and performs image processing, a display that displays the image from the scan converter, and control each of these means, and an inspection mode such as B mode and a display depth. It has a control unit that executes image conditions such as inspection conditions, and performs imaging of the number of steps determined by the image conditions determined for one subject, and changes the image conditions for each step In an ultrasonic diagnostic apparatus that performs a screening test for capturing an image, an image condition storage unit that stores the image condition for each step, and operation of storing and reading the image condition and setting the control unit are operated. And an image condition operation means.

Further, there is provided an execution procedure setting means for inputting the read-out image conditions and setting the image conditions to the control section in the order of execution, and further, the image condition from the image condition storage means and the control section. An image condition comparing means for comparing the set image condition with each other and outputting the comparison result to the executing means setting means. In particular, the image storage means stores only the image conditions for changing or changing the image conditions in the order of execution.

[0010]

The image condition is stored in the image condition storage means step by step only in the order in which the image condition is changed or changed in the control unit. Then, the stored image conditions are read out by the operation of the image condition operation means and set in the control unit, and by starting the photographing, the control unit executes the image conditions to obtain the image. As a result, it is possible to change the image conditions of the imaging in each step during the screening test with a simple operation, and the operability is improved.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram showing a schematic configuration of this embodiment, and FIG. 2 is a diagram showing contents stored in an image condition storage circuit in this embodiment. First, the configuration of this embodiment will be described. The probe 10 is in contact with the subject 20 to transmit an ultrasonic wave, and also receives an ultrasonic echo reflected at a boundary in the subject 20 having a different acoustic impedance. Transceiver circuit 30
Consists of a pulser, transmission delay circuit, amplifier, etc.
An ultrasonic beam transmitted from the probe 10 is formed by a pulsar and a transmission delay circuit, and an ultrasonic echo is amplified by an amplifier. The signal processing circuit 40 includes a wave receiving delay circuit, a phasing circuit including an adder, a gain control circuit, and a LOG.
The transmission / reception circuit 3 is composed of an amplifier circuit, a dynamic range setting circuit, a full-wave rectification circuit, an envelope circuit, and the like.
Signal processing such as forming a received ultrasonic beam by aligning and adding the phases of the echo signals from 0 and detecting the phase-combined echo signals is performed.

The A / D converter 51 digitally converts the signal-processed echo signal. Scan converter 52
Has a line memory and an image memory, and repeatedly writes and reads the digitally converted echo signal to and from the line memory for each scanning line or plural scanning lines of the ultrasonic beam, and stores it in the image memory as an image. The D / A converter 53 is an analog signal (video signal) capable of displaying an echo signal from the image memory of the scan converter 52.
Convert to. The display 70 inputs the video signal of the D / A converter 53 and displays an ultrasonic image. Further, the image memory of the scan converter 52 is provided with two of L and R,
Images of L and R can be simultaneously displayed on the display 70, and either L or R can be displayed on the entire display 70. That is, the display device 70 can perform one-screen display and two-screen display.

The main controller 54 includes a wave transmitting / receiving circuit 3
With respect to 0, the transmitting / receiving direction of the ultrasonic beam is changed, the ultrasonic beam is transmitted / received by changing the image condition, each parameter of the signal processing circuit 40 is set, and writing / reading of the line memory of the scan converter 52 is performed. Control.

Further, the multi-operation control unit 60
Is composed of an operation panel 61, a panel I / F circuit 62, a panel controller 63, an image condition storage circuit 64, and a multi-operation operator 65. Operation panel 61
Sets inspection modes such as B mode, M mode, and color Doppler mode, inspection conditions such as display depth and focus depth, or various image conditions such as image processing conditions such as dynamic range, enhancement, and frame correlation. The operation keys of are arranged in a matrix. The panel I / F circuit 62 recognizes which operation key, switch, or volume of the operation panel 61 is being executed. The panel controller 63 is a panel I /
The image condition of the signal recognized by the F circuit 62 is transferred to the main controller 63. The image condition storage circuit 64 stores the image conditions for each imaging of the screening examination in the order of input. Multi-operation controller 65
Registers the image condition in the image condition storage circuit 64 or reads the image condition.

Next, the operation of this embodiment will be described. The probe 10 is brought into contact with the diagnostic site of the subject 20 and ultrasonic waves are transmitted to the diagnostic site. At this time, the transmitted ultrasonic waves are controlled by the transmission delay circuit of the transmission / reception circuit 30 so that a thin ultrasonic beam is formed. After transmitting the ultrasonic wave, the probe 10 receives the ultrasonic echo signal, and the transmitting / receiving circuit 30
Amplify with the amplifier. The phase of the amplified echo signal is combined by the phasing circuit of the signal processing circuit 40 to form a received ultrasonic beam. Then, the transmission / reception direction of the ultrasonic beam is changed, and the process is repeated to scan the diagnostic region.

The operation of the signal processing circuit 40 will be described in detail. The echo signal from the transmission / reception circuit 30 is compared with the echo signal of each channel so that the echo signal is optimally focused at the depth observed by the phasing circuit. The delay time is controlled and phase synthesis is performed. The sensitivity of the phase-synthesized echo signal is adjusted by the gain control circuit. Also,
The echo signal normally has a dynamic range of 60 to 90 dB, but since the display device 70 has only a dynamic range of about 20 to 30 dB, the optimum compression rate is set by the LOG amplifier and the dynamic range setting circuit.
Further, the carrier component of the high frequency echo signal is removed by full wave rectification and envelope detection.

The echo signal processed by the signal processing circuit 40 is converted into a digital signal by the A / D converter 51 and input to the scan converter 52. In the scan converter 52, switching control is performed by the main controller 54 each time the transmitting / receiving direction of the ultrasonic beam changes.
Writing to and reading from the line memory. The echo signals read from the line memory are sequentially stored in the image memory so as to form one ultrasonic tomographic image with the transmitting and receiving directions corresponding to each ultrasonic beam.

When the scanning of one image is completed by the probe 10, the scanning direction is returned to the initial direction, the transmission / reception is repeated, and the echo signals are sequentially stored in the image memory. The image data stored in the image memory is analog-converted by the D / A converter 53 and sequentially output to the display device 70 for brightness modulation or the like to display an ultrasonic image.

Further, when taking a picture, from the operation panel 61 of the multi-operation control unit 60, B mode, M
Modes, inspection modes such as color Doppler mode, inspection conditions such as display depth, number of display screens, and focus depth, image processing conditions such as dynamic range, (edge) enhancement, and frame correlation are set. When the image conditions are set on the operation panel 61, the panel I
The operation key set by the / F circuit 62 is recognized and output to the panel controller 63. The panel controller 63 outputs the input signal from the operation panel 61 to the main controller 54, and when the operation key of the operation panel 61 is set based on the information from the main controller 54, whether or not the set function is executed. Control processing such as reception processing and lighting of set operation keys is performed.
Such an operation is repeatedly performed for each photographing.

Next, the operation of the multi-operation controller 60 during the screening test will be described. First,
Before the screening inspection is performed, a plurality of image conditions used in each imaging are stored in the image condition storage circuit 64. This image condition is stored in the order of shooting and the order of execution.
For example, when imaging the liver first, the left and right kidneys, and the gallbladder, it is necessary to set image conditions for four steps as shown in FIG.

First, in the first step, the examination mode is B mode, the display depth (the range of the subject displayed on the screen) is 18 cm, and the number of display screens (the number of images displayed on the display 70) is one screen. , The display screen L / R (the image memory that stores the image to be displayed) on the L side, the body mark (the position and direction of the probe at the time of shooting) a mark that specifies the liver, the comment display in the order of LIVER, and image conditions It is stored in the memory circuit 64. In the second step, there is printer recording (recording the image of the previous shooting), canceling the freeze and setting the display depth to 15c.
m, the number of display screens is 2, the display screens L / R are on the L side, the body mark is a mark for designating the right kidney, the comment display is R-Kidney, and in the third step,
Display screen L / R on the R side, freeze is released, body mark is a mark that specifies the left kidney, and comment display is LK
The idney and the measurement item are stored in order with the area. further,
In the 4th step, there is a printer record, the freeze is released, the display depth is 12 cm, the number of display screens is 1, the display screen L / R is on the R side, the body mark is a mark that specifies the gallbladder, the comment display is GB, and the measurement is performed. Store items in order with area.

Here, although the inspection mode is not set in the second, third, and fourth steps, if there is no setting, the first setting is continued. Further, the setting of the display depth, the number of display screens, the display screen L / R, the body mark, and the comment display is continued. Regarding printer recording, freeze release, and measurement items, the order of operations is fixed (for example, printer recording is for recording the previous image and must be performed at the beginning of each step), so settings cannot be continued. It has become. In addition, the measurement item is not executed by the measurement software when the image is displayed, but it is executed after the operator freezes and the range is specified using a trackball etc., and the calculation is automatically performed. It is like this.

This storage is done in advance on the operation panel 6 before photographing.
The value is input directly from No. 1 or selected by the multi-operation operation unit 65 from the menu screen and stored. Further, the image condition may be manually stored or the final parameter of each image condition may be automatically stored while actually photographing.

When the image conditions thus stored are executed, that is, when the screening inspection is performed, the multi-operation operating device 65 is operated (for example, a button is pressed).
Then, the image conditions of the first step are read in the order of storage,
Main controller 5 via panel controller 63
Set to 4 and execute in order. For example, when the image conditions of the image condition storage circuit 64 as shown in FIG. 2 are executed by the multi-operation operator 65, the inspection mode is set to B mode, the display depth is set to 18 cm, and the number of display screens is set to 1 screen. The setting is made so that the L side of the image memory is used, the body mark for designating the liver is set to be displayed, and the liver is set to be displayed. And
When the operator abuts the probe 10 on the diagnostic region of the subject 20 and starts imaging, the above-described image conditions are sequentially executed, and as a result, a tomographic image of the liver within a range of 18 cm from the body surface is the L side of the image memory. The tomographic image is displayed in real time on the entire screen of the display 70, and a body mark indicating the position of the liver and a comment of LIVER are displayed on the screen. Then, the operator arbitrarily freezes this tomographic image to draw an image, and the execution of the image condition of the first step is completed.

When moving to the second-step photographing, the multi-operation operating device 65 is operated to sequentially set the image conditions of the second step in the main controller 54. Then, when the operator abuts the probe 10 on the next diagnosis site (right kidney) and starts photographing, the image condition of the second step is sequentially executed. First, a tomographic image of the frozen liver is recorded in the printer in the image memory on the L side at the first step, and then the freeze is released. When the freeze is released, the display depth is 15 cm, the number of display screens is 2,
The display screen L / R is sequentially executed with the L side. As a result, a tomographic image of the right kidney within a range of 15 cm from the body surface is displayed in the L of the image memory.
This tomographic image is stored on the left side of the display 70 in real time, and a body mark indicating the position of the right kidney and a comment called R-Kidney are displayed on the left screen. Then, similarly to the above, the operator arbitrarily freezes this tomographic image to complete the execution of the image condition of the second step.

At the time of shifting to the photographing of the third step, the image condition of the third step is sequentially set in the main controller 54 by operating the multi-operation operating device 65. Then, when the operator abuts the probe 10 on the next diagnosis site (left kidney) and starts imaging, the image conditions of the third step are sequentially executed. First, the R side of the image memory is set and the R side is unfrozen. At this time, the L side has not been unfrozen and is set to the two-screen display, so that the tomographic image at the second step is displayed as it is. When the freeze is released, the body mark and comment display are executed, but since the inspection mode of the second step and the display depth continue, the tomographic image of the left kidney in the range of 15 cm from the body surface is first stored in the image memory. Stored on the R side. Then, this tomographic image is displayed in real time on the right side of the screen of the display 70, and the body mark indicating the position of the left kidney and the comment L-Kidney are displayed on the right screen. Furthermore, when the tomographic image of the left kidney is frozen, the software for measuring the area is executed, and the operator inputs data (the kidney is drawn with a trackball etc.) to the drawn image to calculate the area. The image is displayed on the display 70, and the execution of the image condition of the third step ends. That is, a tomographic image of the frozen right kidney is displayed on the left screen of the display 70, and a tomographic image of the frozen left kidney is displayed on the right screen at the same time. , The area within the range is displayed.

When moving to the fourth step of photographing, the multi-operation operator 65 is operated to sequentially set the image conditions of the fourth step in the main controller 54. Then, the operator places the probe 1 on the next diagnostic site (gallbladder).
When 0 is abutted to start photographing, the image conditions of the fourth step are sequentially executed. First, the tomographic images of the left and right kidneys displayed on the two screens are recorded on the printer, and then the freeze is released. When the freeze is released, the display depth is 12 cm and the number of display screens is 1 screen in sequence. Then, a tomographic image of the gallbladder within a range of 12 cm from the body surface is stored on the R side of the image memory, the tomographic image is displayed in real time on the right side of the screen of the display 70, and a body mark indicating the position of the gallbladder and GB are displayed. The comment is displayed on the screen.
Then, when this image is frozen, the software for measuring the area is executed in the same manner as described above, and the area is obtained if the operator inputs the range of the gallbladder. This area value is displayed on the display 70 and the fourth step is displayed. The execution of the image condition ends.

In this embodiment, a plurality of image conditions set for each photographing (step) in the screening test are executed in the order of execution, and only the image condition to be changed is stored in the image condition storage circuit 6.
4 and the multi-operation controller 65 is operated to read and set the image conditions at the time of each shooting in the order of execution, and the image conditions are sequentially executed to obtain an image. Therefore, a large number of image conditions are changed for each shooting. However, the image condition can be changed only by operating the multi-operation operating device 65. In addition, since the image conditions are stored in the order of execution, the target image can be surely obtained. Further, since the measurement software can be preset to automatically execute after the image freeze, the number of operations after drawing the image is reduced. Furthermore, since only the image condition to be changed is stored, the input work for storing the image condition can be reduced.

Here, the image condition storage circuit 64 stores the inspection mode, the inspection condition, the presence / absence of printer recording, the execution of the measurement software, etc., but the start timing and the end timing of the timer may be stored. . If the start and end timings of this timer are stored, the elapsed time from any step can be displayed on the display 70, which is effective for drug administration, inspection of the progress after exercise load, and the like. Further, the printer recording is set to be performed after the operator abuts the probe 10 on the next diagnostic site. However, printing is performed immediately after the operation of the multi-operation operator 65, and then the freeze is released to set the image condition. Even if it is set, the same effect can be obtained. At this time, depending on the printer, it may not be possible to cancel the freeze immediately after printing.
In that case, it may be set so that a certain waiting time is provided. Furthermore, image processing such as frame correlation may be set as an image condition.

Next, a second embodiment will be described with reference to FIGS. FIG. 3 is a block diagram showing a schematic configuration of the multi-operation control unit of this embodiment, and FIG. 4 is a diagram showing the contents stored in the image condition storage circuit and the order of execution in this embodiment. In the present embodiment, the operation of displaying an image by receiving an ultrasonic wave and performing signal processing and image processing is the first
This is the same as the embodiment. Further, description of the same reference numerals as those in the first embodiment will be omitted. The multi-operation control unit 60 of this embodiment includes an operation panel 61 and a panel I.
The / F circuit 62, the panel controller 63, the image condition storage circuit 64, the multi-operation operator 65, and the execution unit setting circuit 66. The execution procedure setting circuit 66 sets the execution order of each image condition read from the image condition storage circuit 64 and outputs it to the panel controller 63.

The storage and execution of image conditions in the screening test of this embodiment will be described. In this embodiment, the inspection mode, the display depth, the number of display screens, the display screen L / R, the display start depth (the distance from the body surface of the displayed image), the comment display, the printer record, the measurement item, The nine image conditions of the body mark are set, and shooting is performed for 6 steps. The image condition storage circuit 64 includes an operation panel 61 and a multi-operation operator 6.
5 is used to set and store all image conditions from the first step. For example, as shown in FIG. 4, in the first step, the inspection mode is B mode, the display depth is 18 cm,
The number of display screens is 1, the display screen L / R is on the L side, the display start depth is 0 mm, the comment display is LIVER, the printer record exists, the measurement item is set, and the body mark stores the mark that specifies the liver. .

In the second step, the inspection mode is B mode, the display depth is 12 cm, the number of display screens is 1, the display screen L / R is on the L side, the display start depth is 10 mm, the comment display is GB, and the printer record is available. , The measurement item is the area, and the body mark is the mark that specifies the gallbladder. In the third step, the inspection mode is B mode and the display depth is 12
cm, the number of display screens is 2, the display screen L / R is on the L side, the display start depth is 0 mm, and the comment display is R-Kidne.
y, there is a printer record, the measurement item is a distance, and the body mark is a mark for designating the right kidney. In the fourth step, the inspection mode is B mode, the display depth is 12c.
m, the number of display screens is 2, the display screen L / R is on the R side, the display start depth is 0 mm, the comment display is L-Kidney,
A printer record is made, and the contents such as a measurement item for distance and a body mark for designating the left kidney are stored.

In the fifth step, the inspection mode is B / M mode, the display depth is 15 cm, the number of display screens is 2, the display screens L / R are both sides, the display start depth is 0 mm, the comment display is PORTAL, and the printer. There is a record, there is no measurement item, and the body mark is a mark that specifies the portal vein. In the sixth step, the inspection mode is CFM mode, the display depth is 15 cm, the number of display screens is 1 screen, and the display screen L / R. L side, display start depth is 0 mm, comment display is LIVE, printer recording is done, measurement item is done, and body mark is a mark designating the liver.

When the storage of the image conditions in the image condition storage circuit 64 is completed and the photographing is started, the multi-operation operator 65 is operated to read the image condition of the first step. The read image conditions are set in the main controller 54 via the panel controller 63 in a predetermined order by the execution procedure setting circuit 66, and when the probe is brought into contact with the subject to start imaging, the first step The image conditions of are executed in the order determined by the execution procedure setting circuit 66. In this embodiment, printer recording, number of display screens, display screen L / R, inspection mode, display depth, display start depth, body mark, comment display, and measurement item are set and executed in this order.

Here, the measurement item is automatically calculated by the measurement software being executed after the operator freezes and the range designation or the like being performed as described above. Further, after the so-called image is frozen after the photographing in each step is completed, it is necessary to cancel the freeze in the next step. for that reason,
Although not described in this embodiment, the freeze is released after the printer recording. However, when displaying two screens using images of two steps, the freeze is released after the display screen L / R is executed, that is, after the image memory is designated.

The execution of the first step is (1) printer recording. (2) Set the number of display screens to one screen.
(3) Set the L side of the image memory. (4) Set the inspection mode to B mode. (5) Set the display depth to 18 cm. (6) Set the display start depth to 0 mm.
(7) Display the body mark that specifies the liver.
(8) Display the comment of LIVER. (9) No measurement is set. That is, the image frozen in the previous screening test or the like is printed, and after the freeze is released, the image is stored in the image memory L side and displayed on the display unit 70. In the image at this time, a tomographic image of the liver 18 cm from the body surface is displayed on one screen, and a body mark designating the liver and a comment called LIVER are simultaneously displayed. Then, the operator freezes an arbitrary image and the first step ends.

The execution of the second and subsequent steps is performed in the same manner as the first step, and is executed in the order set by the execution procedure setting circuit 66. Here, if the measurement items include area and distance settings, the measurement software executes when the displayed image is frozen as in the first embodiment, and the operator automatically inputs the range to be measured. The calculation result is displayed on the display 70.

In the present embodiment, a plurality of image conditions set for each photographing (step) in the screening test are stored in the image condition storage circuit 64, and the image conditions are executed in the order determined by the execution procedure setting circuit 66. Therefore, even if a large number of image conditions are changed for each photographing, the image conditions can be changed only by operating the multi-operation operator 65. Moreover, since the execution order is predetermined by the execution procedure setting circuit 66, it is possible to store the image condition from any image condition when storing the image condition. Is improved.

Next, a third embodiment will be described with reference to FIGS. FIG. 5 is a diagram showing the contents stored in the image condition storage circuit in the present embodiment, and FIG. 6 is a block diagram showing a schematic configuration of the multi-operation control unit in the present embodiment. In this embodiment, the operation of receiving an ultrasonic wave and performing signal processing and image processing to display an image is the same as in the first embodiment. Further, description of the same reference numerals as those in the first and second embodiments will be omitted. The multi-operation control unit 60 of this embodiment includes an operation panel 61, a panel I / F circuit 62, a panel controller 63, and an image condition storage circuit 6.
4, a multi-operation operator 65, an execution procedure setting circuit 66, and an image condition comparison circuit 67. The image condition comparison circuit 67 compares the image condition between steps, that is, the image condition set in the main controller 54 with the image condition read from the image condition storage circuit 64,
If the read image condition contains the changed parameter, the new parameter is set, and if the read image condition does not contain the parameter, the main controller 54 is set to continue the image condition. .
Further, the execution procedure setting circuit 66 sets and executes in the same order as in the second embodiment.

For example, in the present embodiment, when the screening inspection is performed with the same contents as those in the second embodiment, the image condition storage circuit 64 first sets the inspection mode as B mode and the display depth as 18 cm as the first step image condition. The number of display screens is 1, the display screen L / R is on the L side, the display start depth is 0 mm, the comment display is LIVER, the printer record exists, the measurement item is set, and the body mark stores the mark that specifies the liver. . In the second step, 1
Image condition different from the step eye, that is, display depth is 12 cm, display start depth is 10 mm, comment display is GB,
It has a gallbladder body mark, a printer record, and stores measurement items as area. Here, regarding the printer recording, the conditions are the same as those in the first step, but the image condition that can be continued between the steps is only the image condition from the release of the freeze to the execution of the freeze. Is stored at every step.

In the third step, the inspection mode,
Since the display depth and the display screen L / R are the same as those in the second step, they are not stored. The number of display screens is 2, the display start depth is 0 mm, the comment display is R-Kidney, and the printer record is. The distance and the body mark of the right kidney are stored respectively. Hereinafter, only the changed image condition is stored for each step.

When starting the screening test,
By operating the multi-operation operator 65 as in the first and second embodiments, the image condition is read from the image condition storage circuit 64 and input to the image condition comparison circuit 67. When the first step is executed, all the image conditions have been set in the sense that new image conditions are set, so the image condition comparison circuit 67 inputs the read image conditions to the execution procedure setting circuit 66 and determines them in advance. The order is set in the main controller 54 via the panel controller 63, and the image conditions are sequentially executed in the same manner as in the second embodiment to obtain an image.

When the second step is executed, the image condition storage circuit 64 inputs the image condition of the second step, the main controller 54 inputs the image condition executed in the first step to the image condition comparison circuit 67, and the second step is input. The image conditions in which the parameters are not stored are continuously input to the execution procedure setting circuit 66 for the image conditions of the first step, and the image conditions in which the new parameters are stored are newly set and executed. Input to the setting circuit 66. Then, in the third step, image conditions of new parameters are set by comparing with the image conditions executed in the second step, and this is repeated for each imaging step.

In the present embodiment, only the image condition to be changed among the plurality of image conditions set for each photographing (step) in the screening examination is stored in the image condition storage circuit 64 and determined by the execution procedure setting circuit 66. Since the image conditions are executed in order to obtain an image, even if a large number of image conditions are changed for each photographing, the image conditions can be changed only by operating the multi-operation operator 65. In addition, since the execution sequence setting circuit 66 predetermines the order of execution and stores only the image condition to be changed, it is possible to store any image condition when storing the image condition. The input work to be stored can be reduced, and the operability is further improved.

[0045]

The image conditions necessary for obtaining an arbitrary image are stored in the image condition storage means for a plurality of images and in the order of execution of the image conditions, and the image conditions are read from the image condition storage means by the operation of the image condition operation means. Since it is set in the control unit together with the above, the image condition during the screening test can be easily changed. Further, the image conditions are arbitrarily stored in the image condition storage means, and the image conditions read out by the image condition operation means are set in the control section in the order of execution by the execution procedure setting means. This can be done easily and can be done quickly without having to consider the order of storage when storing image conditions. Further, only the image condition to be changed is arbitrarily stored in the image condition storing means, and the image condition read out by the image condition operating means and the image condition set in the control section are compared by the image condition comparing means, and different. Since only the image condition is set in the control unit via the execution procedure setting means, the image condition can be easily changed, and only the condition for changing the image condition can be stored, which enables quicker storage.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of a first embodiment.

FIG. 2 is a diagram showing the contents stored in an image condition storage circuit in the first embodiment.

FIG. 3 is a block diagram showing a schematic configuration of a multi-operation control unit according to a second embodiment.

FIG. 4 is a diagram showing the contents to be stored in an image condition storage circuit and the order of execution in the second embodiment.

FIG. 5 is a diagram showing the contents stored in an image condition storage circuit in the third embodiment.

FIG. 6 is a block diagram showing a schematic configuration of a multi-operation control unit according to a third embodiment.

FIG. 7 is a block diagram showing a schematic configuration of a conventional ultrasonic diagnostic apparatus.

[Explanation of symbols]

 10 probe 20 subject 30 transmitting / receiving circuit 40 signal processing circuit 51 A / D converter 52 scan converter 53 D / A converter 54 main controller 60 multi-operation control unit 61 operation panel 62 panel I / F circuit 63 panel controller 64 Image condition storage circuit 65 Multi-operation operator 66 Execution procedure setting circuit 67 Image condition comparison circuit 70 Display

Claims (5)

[Claims] 1. A probe for transmitting and receiving ultrasonic waves, a signal processing circuit for delaying and adding the received ultrasonic signals, and an image processing for converting the signal-processed ultrasonic signals into an image. There is a scan converter for performing, a display device for displaying an image from the scan converter, and a control unit for controlling each of these means and executing image conditions such as inspection modes such as B mode and inspection conditions such as display depth. Then, in the ultrasonic diagnostic apparatus for performing a screening test for photographing an arbitrary image by changing the image condition for each step by photographing the number of steps determined by the image condition determined for one subject. An ultrasonic wave, comprising: an image condition storing means for storing the image condition for each step; and an image condition operating means for operating the storing, reading of the image condition and setting to the control section. Cross-sectional devices. 2. A probe for transmitting and receiving ultrasonic waves, a signal processing circuit for performing delay processing and addition on the received ultrasonic signals, and converting the signal-processed ultrasonic signals into images and performing image processing. There is a scan converter for performing, a display device for displaying an image from the scan converter, and a control unit for controlling each of these means and executing image conditions such as inspection modes such as B mode and inspection conditions such as display depth. Then, in the ultrasonic diagnostic apparatus for performing a screening test for photographing an arbitrary image by changing the image condition for each step by photographing the number of steps determined by the image condition determined for one subject. An image condition storing means for storing the image condition for each step, an image condition operating means for operating the storing, reading and setting of the image condition in the control section, and an input of the read image condition. Ultrasonic diagnostic apparatus characterized by comprising an execution procedure setting means for setting an image condition in order of execution to the control unit and. 3. A probe for transmitting and receiving ultrasonic waves, a signal processing circuit for delaying and adding the received ultrasonic signals, and an image processing for converting the signal-processed ultrasonic signals into an image. There is a scan converter for performing, a display device for displaying an image from the scan converter, and a control unit for controlling each of these means and executing image conditions such as inspection modes such as B mode and inspection conditions such as display depth. Then, in the ultrasonic diagnostic apparatus for performing a screening test for photographing an arbitrary image by changing the image condition for each step by photographing the number of steps determined by the image condition determined for one subject. An image condition storing means for storing the image condition for each step, an image condition operating means for operating the storing, reading and setting of the image condition in the control section, and an input of the read image condition. An image processing condition setting means for setting image conditions to the control unit in the order of execution and an image condition for comparing the image condition from the image condition storage unit with the image condition set in the control unit and outputting the comparison result to the executing unit setting unit. An ultrasonic diagnostic apparatus comprising: a comparison unit. 4. The ultrasonic diagnostic apparatus according to claim 1, wherein the image storage means stores image conditions in the order of execution. 5. The ultrasonic diagnostic apparatus according to claim 1, wherein only the image conditions to be changed are stored in the image storing means.