JP6881629B2 - How to operate ultrasonic diagnostic equipment and ultrasonic diagnostic equipment - Google Patents

Description

The present invention relates to an ultrasonic diagnostic apparatus and a method of operating the ultrasonic diagnostic apparatus .

Conventionally, there is an ultrasonic diagnostic apparatus capable of observing a tissue structure and properties by irradiating the inside of a subject with ultrasonic waves and receiving the reflected waves to image or analyze them. In ultrasonic diagnosis, the subject can be examined non-destructively and non-invasively.

Further, in an ultrasonic diagnostic apparatus, a technique of strain elastography (Strain Elastography) is known, which images a strain distribution generated by applying pressure to an object of a subject using an ultrasonic probe. In strain elastography, the hardness of a subject can be evaluated from the difference in relative strain between the subject (eg, tumor) and the reference (eg, fat).

Stable pressure on the subject is required for a reliable evaluation of hardness. Against such a background, there is known an ultrasonic diagnostic apparatus that links the acquired frame group and the compression direction to simplify the selection of a frame in which uniform compression is performed by the user (see Patent Document 1). ). This ultrasonic diagnostic apparatus can display an elastic image of a frame having a good compression direction.

Japanese Patent No. 4769715

However, although the conventional ultrasonic diagnostic apparatus can confirm the pressing state, it basically displays a single feature amount, and for example, a plurality of compression strengths and compression directions are displayed. If it is desired to make a comprehensive judgment based on the characteristics, it is necessary to switch the display, which may complicate the operation.

An object of the present invention is to make it possible to easily select an elastic image frame having a good pressing state based on a plurality of types of feature quantities.

In order to solve the above problems, the invention according to claim 1 is
An ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmitter that transmits a drive signal to the ultrasonic probe,
A receiving unit that processes the received signal output from the ultrasonic probe, and
An evaluation value calculation unit that generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation unit.
A display control unit that displays the generated stable section information on the display unit,
An elastic image generation unit that generates elastic image data based on the received signal is provided.
In the live mode, the display control unit displays the generated elastic image data and the generated stable section information on the display unit .
The evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and has a cine frame selection bar having a cursor capable of changing the movement. Is generated, and the default display frame corresponding to the cursor is set to the display frame within the stable section .

Invention according to claim 2,
An ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmitter that transmits a drive signal to the ultrasonic probe,
A receiving unit that processes the received signal output from the ultrasonic probe, and
An evaluation value calculation unit that generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation unit.
A display control unit that displays the generated stable section information on the display unit,
An elastic image generation unit that generates elastic image data based on the received signal is provided.
In the live mode, the display control unit displays the generated elastic image data and the generated stable section information on the display unit.
The evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and has a cine frame selection bar having a cursor capable of changing the movement. To generate
When the cursor is in the stable section, the cursor control unit is provided to set the moving speed of the cursor slower than when the cursor is outside the stable section.

The invention according to claim 3,
An ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmitter that transmits a drive signal to the ultrasonic probe,
A receiving unit that processes the received signal output from the ultrasonic probe, and
An evaluation value calculation unit that generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation unit.
A display control unit that displays the generated stable section information on the display unit,
An elastic image generation unit that generates elastic image data based on the received signal is provided.
In the live mode, the display control unit displays the generated elastic image data and the generated stable section information on the display unit.
The evaluation value calculation unit calculates an evaluation value based on the processed received signal, and when calculating the evaluation value, the evaluation value of the frame immediately before the freeze operation is relative to the frame other than the frame immediately before the freeze operation. The information of the stable section is generated by raising the target.

The invention according to claim 4 is the ultrasonic diagnostic apparatus according to claim 3.
A freeze control unit for setting a freeze when the calculated evaluation value satisfies a predetermined condition is provided.

The invention according to claim 5 is the ultrasonic diagnostic apparatus according to any one of claims 2 to 4.
The evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and has a cine frame selection bar having a cursor capable of changing the movement. Is generated, and the default display frame corresponding to the cursor is set to the display frame within the stable section.

The invention according to claim 6
It is a method of operating an ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmission step in which the transmission unit transmits a drive signal to the ultrasonic probe, and
A receiving process in which the receiving unit processes the received signal output from the ultrasonic probe, and
The evaluation value calculation unit generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation step.
A display control step in which the display control unit displays the generated stable section information on the display unit,
The elastic image generation unit includes an elastic image generation step of generating elastic image data based on the received signal.
In the display control step, the display control unit displays the generated elastic image data and the generated stable section information on the display unit in the live mode .
In the evaluation value calculation step, the evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and can perform a movement change operation. A cine frame selection bar having a cursor is generated, and the default display frame corresponding to the cursor is set to the display frame within the stable section .
The invention according to claim 7
It is a method of operating an ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmission step in which the transmission unit transmits a drive signal to the ultrasonic probe, and
A receiving process in which the receiving unit processes the received signal output from the ultrasonic probe, and
The evaluation value calculation unit generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation step.
A display control step in which the display control unit displays the generated stable section information on the display unit,
The elastic image generation unit includes an elastic image generation step of generating elastic image data based on the received signal.
In the display control step, the display control unit displays the generated elastic image data and the generated stable section information on the display unit in the live mode.
In the evaluation value calculation step, the evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and can perform a movement change operation. Generates a cine frame selection bar with a cursor and
The cursor control unit includes a cursor control step of setting the moving speed of the cursor when the cursor is within the stable section, as compared with the case where the cursor is outside the stable section.
The invention according to claim 8 is
It is a method of operating an ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmission step in which the transmission unit transmits a drive signal to the ultrasonic probe, and
A receiving process in which the receiving unit processes the received signal output from the ultrasonic probe, and
The evaluation value calculation unit generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation step.
A display control step in which the display control unit displays the generated stable section information on the display unit,
The elastic image generation unit includes an elastic image generation step of generating elastic image data based on the received signal.
In the display control step, the display control unit displays the generated elastic image data and the generated stable section information on the display unit in the live mode.
In the evaluation value calculation step, the evaluation value calculation unit calculates an evaluation value based on the processed received signal, and when calculating the evaluation value, immediately before the freeze operation rather than a frame other than immediately before the freeze operation. The evaluation value of the frame of is relatively high to generate information on the stable section.

According to the present invention, it is possible to easily select an elastic image frame having a good pressing state based on a plurality of types of feature quantities.

It is an external view of the ultrasonic diagnostic apparatus of embodiment of this invention. It is a block diagram which shows the functional structure of an ultrasonic diagnostic apparatus. It is a conceptual diagram which shows the evaluation value calculation from a plurality of feature quantities. It is a figure which shows the distribution of the evaluation value with respect to time. It is a figure which shows the cine frame selection bar. It is a flowchart which shows the elastic image display processing. It is a figure which shows the display image including the synthetic elastic image.

Embodiments and modifications according to an example of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the illustrated examples.

(Embodiment)
An embodiment according to the present invention will be described with reference to FIGS. 1 to 5. First, the apparatus configuration of the ultrasonic diagnostic apparatus 100 of the present embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is an external view of the ultrasonic diagnostic apparatus 100 of the present embodiment. FIG. 2 is a block diagram showing a functional configuration of the ultrasonic diagnostic apparatus 100.

The ultrasonic diagnostic apparatus 100 is an apparatus that displays and outputs an ultrasonic image of the state of the internal tissue of a subject such as a patient's biological body. That is, the ultrasonic diagnostic apparatus 100 transmits ultrasonic waves (transmitted ultrasonic waves) to the inside of a subject such as a living body, and also transmits the reflected waves (reflected ultrasonic waves: echo) of the ultrasonic waves reflected in the subject. Receive. The ultrasonic diagnostic apparatus 100 converts the received reflected ultrasonic waves into an electric signal, and generates ultrasonic image data based on the electric signal. The ultrasonic diagnostic apparatus 100 displays the internal state in the subject as an ultrasonic image based on the generated ultrasonic image data. In addition, the ultrasonic diagnostic apparatus 100 has a strain elastography function that shows the strain distribution inside the subject under pressure.

As shown in FIG. 1, the ultrasonic diagnostic apparatus 100 includes an ultrasonic diagnostic apparatus main body 1 having an operation input unit 11 and a display unit 20, an ultrasonic probe 2, and a cable 3. The ultrasonic probe 2 transmits transmitted ultrasonic waves to the inside of the subject and receives reflected ultrasonic waves from the inside of the subject. The ultrasonic diagnostic apparatus main body 1 is connected to the ultrasonic probe 2 via a cable 3, and by transmitting a drive signal of an electric signal to the ultrasonic probe 2, the inside of the subject is sent to the ultrasonic probe 2. To transmit ultrasonic waves. Further, the ultrasonic diagnostic apparatus main body 1 receives a received signal which is an electric signal generated by the ultrasonic probe 2 in response to the reflected ultrasonic waves from the subject received by the ultrasonic probe 2. , Ultrasound image data is generated and displayed using the received signal.

The ultrasonic probe 2 includes a vibrator 2a (see FIG. 2) made of a piezoelectric element, and the vibrators 2a are arranged in a one-dimensional array in the directional direction (scanning direction), for example. .. In this embodiment, for example, an ultrasonic probe 2 provided with 192 oscillators 2a is used. The vibrators 2a may be arranged in a two-dimensional array. Further, the number of vibrators 2a can be arbitrarily set. Further, in the present embodiment, the ultrasonic probe 2 is used as the ultrasonic probe 2 to scan the ultrasonic waves by the linear scanning method. However, either the sector scanning method or the convex scanning method can be used. It can also be adopted. The communication between the ultrasonic diagnostic apparatus main body 1 and the ultrasonic probe 2 may be performed by wireless communication such as UWB (Ultra Wide Band) instead of the wired communication via the cable 3.

As shown in FIG. 2, the ultrasonic diagnostic apparatus main body 1 includes, for example, an operation input unit 11, a transmission unit 12, a reception unit 13, a B-mode image generation unit 14, a storage unit 14a, and an elastic image generation unit. 15, storage unit 15a, elastic image synthesis unit 16, feature amount calculation unit 17, evaluation value calculation unit 18, display image generation unit 19 as a display control unit, display unit 20, cursor control unit, It includes a control unit 21 as a freeze control unit.

The operation input unit 11 is, for example, various switches, buttons, trackballs, mice, keyboards for inspectors such as doctors and technicians to input commands for instructing the start of diagnosis and data such as personal information of the subject. Etc., and output an operation signal to the control unit 21. The operation input unit 11 includes a touch panel provided on the display screen of the display unit 20.

The transmission unit 12 is a circuit that supplies a drive signal, which is an electric signal, to the ultrasonic probe 2 via a cable 3 under the control of the control unit 21 to generate a transmission ultrasonic wave to the ultrasonic probe 2. .. Further, the transmission unit 12 includes, for example, a clock generation circuit, a delay circuit, a time and voltage setting unit, and a pulse generation circuit. The clock generation circuit is a circuit that generates a clock signal that determines the transmission timing and transmission frequency of the drive signal. The delay circuit sets the delay time for each individual path corresponding to the transmission timing of the drive signal for each oscillator, delays the transmission of the drive signal by the set delay time, and is a transmission beam composed of transmission ultrasonic waves. This is a circuit for focusing. The time and voltage setting unit is a circuit that sets the voltage of the time and amplitude of the pulse width of the pulse signal generated from the pulse generation circuit. The pulse generation circuit is a circuit for generating a pulse signal as a drive signal according to the time and voltage set by the time and voltage setting unit. The transmission unit 12 configured as described above drives, for example, a continuous part (for example, 64) of a plurality of (for example, 192) vibrators 2a arranged in the ultrasonic probe 2. To generate transmitted ultrasonic waves. Then, the transmission unit 12 scans by shifting the driven vibrator in the directional direction each time the transmitted ultrasonic wave is generated.

The receiving unit 13 is a circuit that receives a received signal, which is an electric signal, from the ultrasonic probe 2 via a cable 3 under the control of the control unit 21, processes the received signal, and generates sound line data. .. The receiving unit 13 includes, for example, an amplifier, an A / D conversion circuit, and a phasing addition circuit. The amplifier is a circuit for amplifying a received signal at a preset amplification factor for each individual path corresponding to each vibrator. The A / D conversion circuit is a circuit for A / D conversion of the amplified received signal. The phase-adjusting addition circuit adjusts the time phase by giving a delay time for each individual path corresponding to each oscillator to the A / D-converted received signal, and adds (phase-adjusting addition) these to the sound line. It is a circuit for generating data.

The B-mode image generation unit 14 performs envelope detection processing, logarithmic amplification, and the like on the sound line data from the reception unit 13 under the control of the control unit 21, adjusts the dynamic range and gain, and converts the brightness. As a result, B (Brightness) mode ultrasonic image data (B mode image data) is generated as tomographic image data. That is, the B-mode image data represents the strength of the received signal by the brightness.

The storage unit 14a is a storage unit composed of a semiconductor memory such as a flash memory. The B-mode image generation unit 14 associates the generated B-mode image data with a frame number (time) and stores the generated B-mode image data in the storage unit 14a in frame units as cine frame cine image data. The B-mode image generation unit 14 reads out the B-mode image data stored in the storage unit 14a and outputs the B-mode image data to the elastic image synthesis unit 16 under the control of the control unit 21.

The elastic image generation unit 15 performs an calculation on the sound line data from the reception unit 13 under the control of the control unit 21, converts it into a distortion amount as elastic information, and color-maps the elastic image data. Generate. The size of the image of the elastic image data generated by the elastic image generation unit 15 is the size of the ROI (Region Of Interest) designated and input by the inspector via the operation input unit 11. It is not limited, and may be the same as the size of the image of the B mode image data. The storage unit 15a is a storage unit composed of a semiconductor memory such as a flash memory.

Here, the amount of distortion will be described. The examiner grasps the ultrasonic probe 2 and applies pressure to the body surface of the subject. At this time, the pressure applied from the ultrasonic probe 2 to the subject changes due to the vibration of the examiner himself or the breathing of the subject. For example, it is assumed that the upper end of an object such as a tumor is located at a distance xr in the depth direction (X direction) from the body surface in contact with the ultrasonic probe 2 in the subject before the compression is applied. .. Further, it is assumed that the width of this object in the depth direction is L. If compression ρ (stress) is applied to the subject and compression ρ is also applied to the object, the upper end position of the object changes to the distance xs in the depth direction, and the depth of the object changes. It is assumed that the width in the direction changes so as to be L−ΔL. Then, by measuring the object in these two states, the strain amount ε = ΔL / L can be obtained.

More specifically, for example, as described in Japanese Patent Application Laid-Open No. 2015-221733, the elastic image generation unit 15 appropriately stores and reads the sound line data from the receiving unit 13 into the storage unit 15a for each frame. Acquires sound line data of two frames that are continuous in time. Of these two frames, the pressurized state of the subject corresponding to the first signal waveform of the sound line data of the first frame is set to the first pressurized state, and corresponds to the second signal waveform of the sound line data of the second frame. The pressurized state of the subject to be subjected to is the second pressurized state. Then, the elastic image generation unit 15 extracts the phase difference component at each time between the first signal waveform and the second signal waveform, and according to the correlation between each time and the phase difference component at each time. , The distortion difference and the initial phase difference related to the difference of each frequency between the first signal waveform and the second signal waveform are calculated, and the distortion amount is calculated based on the distortion difference. The elastic image generation unit 15 calculates the amount of distortion for all the pixels, and generates image data composed of the pixels with the amount of distortion.

Then, the elastic image generation unit 15 colors the image data of the distortion amount by color mapping in which the distortion amount increases in the order of blue → green → yellow → red, and generates the elastic image data. However, in the drawing of FIG. 5 to be described later, in the elastic image, the amount of distortion is expressed in the order of black → white.

Further, the elastic image generation unit 15 associates the generated elastic image data with the frame number (time) and stores the generated elastic image data in the storage unit 15a as cine image data of the cine frame in frame units. The elastic image generation unit 15 reads out the elastic image data stored in the storage unit 15a and outputs the elastic image data to the elastic image synthesis unit 16 under the control of the control unit 21.

Under the control of the control unit 21, the elastic image synthesizing unit 16 determines the elastic image data generated by the elastic image generation unit 15 at the same time with respect to the B mode image data generated by the B mode image generation unit 14. Synthetic elastic image data is generated by synthesizing at the synthesis rate of.

According to the control of the control unit 21, the feature amount calculation unit 17 combines the elastic image data generated by the elastic image generation unit 15, the sound line data generated by the reception unit 13, and the information stored in the storage unit 17a. Using at least one, a plurality of types of feature amounts indicating the pressed state of the subject for each frame of the elastic image data are calculated, and display information of the plurality of feature amounts indicating the calculated feature amounts is generated. The elastic image data and the display information of the plurality of feature amounts are output to the evaluation value calculation unit 18, and the display information of the plurality of feature amounts is stored in the storage unit 17a. The storage unit 17a is a non-volatile storage unit composed of a semiconductor memory such as a flash memory.

As a specific example, an example in which the feature amount calculation unit 17 calculates three types of feature amounts, that is, the strain amount d of the elastic image, the tempo b of the strain amount, and the confidence value s, will be described. However, the types and numbers of the feature amounts calculated by the feature amount calculation unit 17 are not limited to this example.

但し、ＲＯＩ：弾性画像データの全画素、ｘ：弾性画像内の画素の変数ｑにおける歪み量、ｎ：ＲＯＩ内の画素数、である。 The feature amount calculation unit 17 uses the elastic image data generated by the elastic image generation unit 15 to calculate the strain amount d of the elastic image defined by the average strain amount in the elastic image (ROI) by the following equation (1). calculate.

However, ROI: all the pixels of the elastic image data, x: the amount of distortion of the pixels in the elastic image in the variable q, and n: the number of pixels in the ROI.

但し、Ｄ（ω）＝ＦＦＴ（Ｄ（ｔ））、Ｄ（ｔ）：歪み量の時間波形、ｔ：時間・フレーム番号、である。式（２）は、一定の間隔で歪みが生じている場合、特定の周波数が強くなり、分子が大きくなる。この状態をテンポが良い状態と定義している。このとき、分子では周波数成分の最大値を算出するが、単に強い押圧に反応しないよう低周波成分を最大値の算出対象から除き、中周波または高周波成分を最大値の算出対象としても良い。分母は、歪み量に依存しない特徴量として算出するために歪み量の総和で正規化している。また、テンポｂと歪み量とを同時に考慮していい場合に、弾性画像の歪み量のテンポｂは次式（２Ａ）により算出される。

Further, the feature amount calculation unit 17 uses the elastic image data of a plurality of consecutive frames generated by the elastic image generation unit 15 to obtain a sine of the time waveform of the distortion amount of the elastic image (ROI) according to the following equation (2). The tempo b of the amount of distortion of the elastic image defined by the similarity to the waveform / cosine waveform is calculated. At this time, the feature amount calculation unit 17 appropriately writes and reads the elastic image data generated by the elastic image generation unit 15 into the storage unit 17a, and uses it as the elastic image data of a plurality of continuous frames.

However, D (ω) = FFT (D (t)), D (t): time waveform of distortion amount, t: time / frame number. In equation (2), when distortion occurs at regular intervals, a specific frequency becomes stronger and the molecule becomes larger. This state is defined as a state with a good tempo. At this time, the maximum value of the frequency component is calculated for the molecule, but the low frequency component may be excluded from the calculation target of the maximum value and the medium frequency or high frequency component may be the calculation target of the maximum value so as not to simply react to a strong pressure. The denominator is normalized by the sum of the strain amounts in order to calculate it as a feature quantity that does not depend on the strain amount. Further, when the tempo b and the distortion amount can be considered at the same time, the tempo b of the distortion amount of the elastic image is calculated by the following equation (2A).

Further, the feature amount calculation unit 17 uses the sound line data of the continuous frame generated by the receiving unit 13 to obtain an elastic image defined by the correlation value of the sound line data of two consecutive frames by the following equation (3). The reliability value (restoration rate) s is calculated. At this time, the feature amount calculation unit 17 appropriately writes and reads the sound line data of each frame generated by the receiving unit 13 into the storage unit 17a and uses it as the sound line data of continuous frames.
s = AutoCorr (f (x), f _prev (x + Δx))… (3)
However, AutoCorr is an autocorrelation calculation, f (x): signal waveform of sound line data at the position (depth x) in the depth direction of the current frame, f _rev (x + Δx): position in the depth direction of the previous frame ( It is a signal waveform of sound line data at a depth x + Δx).

As other features, the feature amount calculation unit 17 uses the calculated current and past feature amounts, and the current feature amount calculated by the following equation (4) and the maximum value of the past feature amount. The degree of similarity p with the past features defined by the error of may be calculated. At this time, the feature amount calculation unit 17 appropriately writes and reads the calculated feature amount of each frame into the storage unit 17a and uses it as the past feature amount.
p = | y-y _past | ... (4)
However, y is the current feature amount, and y _past is the highest value of the past feature amount. As the feature quantities y and y _past , for example, the strain amount d is used, but the feature quantity is not limited to this. As the feature quantities y and y _past , the tempo b or the confidence value s may be used, or the sum of the values obtained by multiplying a plurality of feature quantities by a weighting coefficient may be used.

As another feature amount, the feature amount calculation unit 17 uses the distribution of the distortion amount in the horizontal direction (scanning direction) of the pixels of the elastic image data (the sum or average value of the distortion amounts of all the pixels for each column in the depth direction). ), A regression line of the strain distribution may be generated, and a score with a perfect score of 0 on the slope of the balance straight line corresponding to the slope of the regression line may be calculated as a feature quantity. In this configuration, the balance straight line may be displayed together with the score of the strain distribution as the feature amount display information.

In addition, the feature amount calculation unit 17 generates display information of each calculated feature amount. For example, the display information of the distortion amount d as the feature amount is the display information of the graph showing the distortion amount from before a predetermined period in the past to the present. At this time, the feature amount calculation unit 17 appropriately reads out the current and past feature amounts from the storage unit 17a and uses them to generate display information of the feature amount. The feature amount calculation unit 17 associates the generated feature amount display information with the frame number (time) and stores it in the storage unit 17a for the cine frame.

The evaluation value calculation unit 18 calculates the evaluation value score using the plurality of feature amounts generated by the feature amount calculation unit 17 under the control of the control unit 21, and generates a cine frame bar based on the evaluation value score. The display information of the plurality of feature amounts generated by the feature amount calculation unit 17 and the generated cine frame bar are output to the display image generation unit 19.

The evaluation value calculation unit 18 calculates the evaluation value score by, for example, the following equation (5).
score = w _d · d + w _b · b + w _s · s ... (5)
However, w _d : the weighting coefficient of the strain amount d, w _b : the weighting coefficient of the tempo b, and w _s : the weighting coefficient of the reliability value s.

FIG. 3 is a conceptual diagram showing the calculation of evaluation values from a plurality of feature quantities. As shown in FIG. 3, the evaluation value calculation unit 18 calculates an evaluation value from a plurality of feature quantities (distortion amount d, tempo b, reliability value s, similarity p) of frames at the same time.

However, the evaluation value calculation unit 18 is not limited to the configuration in which the evaluation value score is calculated by the equation (5), and may be, for example, a configuration in which the evaluation value score is calculated by the equation (6).
score = d ・ b ・ s ... (6)

The evaluation value calculation unit 18 associates the calculated evaluation value with the frame number (time) and stores it in the storage unit 18a for the cine frame. The storage unit 18a is a non-volatile storage unit composed of a semiconductor memory such as a flash memory.

Further, the evaluation value calculation unit 18 generates a cine frame selection bar having a stable section consisting of a frame group having a high evaluation value and being continuous in time, based on the current and past evaluation values stored in the storage unit 18a. Here, the generation of the cine frame selection bar will be described with reference to FIGS. 4A and 4B. FIG. 4A is a diagram showing the distribution of evaluation values with respect to time. FIG. 4B is a diagram showing a cine frame selection bar 300.

The distribution of the evaluation value for each frame with respect to time is shown in FIG. 4A, for example. The time of one frame is, for example, 1/5 to 1/20 [s]. The evaluation value calculation unit 18 calculates the moving average value of the evaluation values for a predetermined time (for example, a section of 1 second) with time for the evaluation values of all the cine frames. Then, the evaluation value calculation unit 18 generates a cine frame selection bar in which a section for a predetermined time when the moving average value becomes equal to or higher than a predetermined threshold value is set as a stable section. It should be noted that the interval for calculating the moving average value and the stable interval may be different in time. The evaluation value calculation unit 18 generates, for example, the cine frame selection bar 300 shown in FIG. 4B corresponding to the distribution of the evaluation values in FIG. 4A. The cine frame selection bar 300 has a stable section 301 and a normal section 302. The stable section 301 is a stable section showing a cine frame in which the moving average value of the evaluation values is equal to or higher than a predetermined threshold value among all the cine frames. The normal section 302 is a normal section indicating a cine frame in which the moving average value of the evaluation values is less than a predetermined threshold value among all the cine frames.

According to the control of the control unit 21, the display image generation unit 19 generates the composite elastic image data generated by the elastic image synthesis unit 16 as display image data in the live mode, and is generated by the elastic image composition unit 16 in the cine mode. The synthetic elastic image data of the cine frame, the display information of the feature amount input from the feature amount calculation unit 17, and the cine frame selection bar input from the evaluation value calculation unit 18 are combined and generated as display image data. To do. The display image generation unit 19 converts the generated display image data into an image signal for the display unit 20 and outputs it to the display unit 20.

A display device such as an LCD (Liquid Crystal Display), a CRT (Cathode-Ray Tube) display, an organic EL (Electronic Luminescence) display, an inorganic EL display, or a plasma display can be applied to the display unit 20. The display unit 20 displays an image on the display screen according to the image signal output from the display image generation unit 19.

The control unit 21 is configured to include, for example, a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory), and reads various processing programs such as a system program stored in the ROM to read the RAM. The operation of each part of the ultrasonic diagnostic apparatus 100 is centrally controlled according to the developed program. The ROM is composed of a non-volatile memory such as a semiconductor, and stores a system program corresponding to the ultrasonic diagnostic apparatus 100, a program that can be executed on the system program, various data such as a gamma table, and the like. These programs are stored in the form of a computer-readable program code, and the CPU sequentially executes operations according to the program code. The RAM forms a work area for temporarily storing various programs executed by the CPU and data related to these programs. In order to prevent the figure from becoming complicated, some control lines from the control unit 21 to each unit are omitted on FIG.

For each part included in the ultrasonic diagnostic apparatus 100, a part or all the functions of each functional block can be realized as a hardware circuit such as an integrated circuit. The integrated circuit is, for example, an LSI (Large Scale Integration), and the LSI may be referred to as an IC, a system LSI, a super LSI, or an ultra LSI depending on the degree of integration. Further, the method of making an integrated circuit is not limited to the LSI, but may be realized by a dedicated circuit or a general-purpose processor, and the connection and setting of the FPGA (Field Programmable Gate Array) and the circuit cell inside the LSI can be reconfigured. A reconfigurable processor may be used. Further, a part or all of the functions of each functional block may be executed by software. In this case, this software is stored in one or more storage media such as ROM, an optical disk, a hard disk, or the like, and this software is executed by an arithmetic processor.

Next, the operation of the ultrasonic diagnostic apparatus 100 will be described with reference to FIG. FIG. 5 is a flowchart showing an elastic image display process.

In the diagnosis of the subject by strain elastography using the ultrasonic diagnostic apparatus 100, the ultrasonic probe 2 is first contacted with the subject in advance as a live mode, B mode image data is generated, and the B mode image is displayed. The examiner appropriately inputs the ROI of the elastic image via the operation input unit 11, and the ultrasonic probe 2 applies pressure to the body surface around the subject.

Then, in the ultrasonic diagnostic apparatus 100, the control unit 21 executes the elastic image display process shown in FIG. Hereinafter, the direct subject of the processing of the step is described as the subject of each step, and the control unit 21 controls the subject of each step.

First, the transmitting unit 12 supplies a drive signal to the ultrasonic probe 2 to transmit and receive ultrasonic waves, and the receiving unit 13 receives the received signal from the ultrasonic probe 2 and generates sound line data ( Step S11). Then, the B-mode image generation unit 14 uses the sound line data generated in step S11 to generate one frame of B-mode image data and store it in the storage unit 14a as a cine frame, and the elastic image generation unit 15 However, using the sound line data generated in step S11 and the sound line data one frame before stored in the storage unit 15a, one frame of elastic image data is generated and stored in the storage unit 15a as a cine frame. , The elastic image synthesizing unit 16 synthesizes the generated B-mode image data and the elastic image data to generate one frame of synthetic elastic image data (step S12).

Then, the feature amount calculation unit 17 uses the sound line data obtained in step S11, the elastic image data obtained in step S12, and the past information stored in the storage unit 17a to perform the feature amount (distortion amount d, The tempo b and the confidence value s) are calculated, and the display information of each feature amount is generated and stored in the storage unit 17a (step S13). Then, the evaluation value calculation unit 18 calculates the evaluation value score of the feature amount using the feature amount calculated in step S13, generates information of the stable section in the cine frame selection bar, and stores it in the storage unit 18a. (Step S14).

Then, the display image generation unit 19 generates one frame of display image data from the one frame of synthetic elastic image data generated in step S12, and displays the display image on the display unit 20 (step S15). The examiner can diagnose the hardness of an object such as a tumor in the synthetic elastic image by visually observing the synthetic elastic image displayed on the display unit 20.

Then, the control unit 21 determines whether or not the freeze input has been input from the inspector via the operation input unit 11 (step S16). If no freeze input has been made (step S16; NO), the process proceeds to step S11. When the freeze input is performed (step S16; YES), the cine mode is started, and the control unit 21 sets the initial display frame number of the cine image data to the B mode image generation unit 14, the elastic image generation unit 15, and the feature amount. It is output to the calculation unit 17 and the evaluation value calculation unit 18 and set (step S17). The default display frame is, for example, a cine frame immediately before freezing among a plurality of cine frames.

Then, the B-mode image generation unit 14 reads the B-mode image data of the input display frame number from the storage unit 14a and outputs it to the elastic image synthesis unit 16, and the elastic image generation unit 15 receives the input display frame number. Is read out from the storage unit 15a and output to the elastic image compositing unit 16, and the elastic image compositing unit 16 synthesizes the input B-mode image data and the elastic image data to generate synthetic elastic image data ( Step S18).

Then, the feature amount calculation unit 17 reads out the display information of the feature amount of the type during the setting of the input display frame number (initially, the initial setting) from the storage unit 17a and outputs it to the display image generation unit 19 (step). S19). The default feature amount is, for example, a distortion amount d. Then, the evaluation value calculation unit 18 reads the information of the stable section from the storage unit 18a, and based on the information of the stable section, generates a cine frame selection bar having a cursor at a position corresponding to the input display frame number. Output to the display image generation unit 19 (step S20).

Then, the display image generation unit 19 synthesizes the composite elastic image data of the input display frame number, the display information of the feature amount, and the cine frame selection bar to generate the display image data, and displays the display image on the display unit 20. Display (step S21). Then, the control unit 21 determines whether or not the cursor movement input has been input by the inspector via the operation input unit 11 (step S22). When the cursor movement input is input (step S22; YES), the control unit 21 sets the changed display frame number corresponding to the cursor movement in step S22 to the B mode image generation unit 14, the elastic image generation unit 15, and the feature amount. Output to the calculation unit 17 and the evaluation value calculation unit 18 for setting (step S23), and the process proceeds to step S18.

When the cursor movement input has not been input (step S22; NO), the control unit 21 determines whether or not the feature amount change input has been input by the inspector via the operation input unit 11 (step S24). When the feature amount change input is input (step S24; YES), the feature amount calculation unit 17 reads out the display information of the type of feature amount corresponding to the changed feature amount in step S24 from the storage unit 17a to generate a display image. Output to unit 19 (step S25), and the process proceeds to step S21. When the feature amount change input is not made (step S24; NO), the elastic image display process ends.

FIG. 6 is a diagram showing a display image 200 including a synthetic elastic image 210. For example, as shown in FIG. 6, in the cine mode, the display image 200 of the display frame number is displayed on the display unit 20. The display image 200 includes a synthetic elastic image 210, a cine frame selection bar 300A, a frame number display field 310, a feature amount display information 400, and a feature amount switching button 410.

The composite elastic image 210 is a composite image of the B-mode image 211 based on the B-mode image data of the display frame number and the elastic image 212 based on the elastic image data of the display frame number. The cine frame selection bar 300A has a stable section 301A, a normal section 302A, and a cursor 303.

The stable section 301A is a part of the bar indicating the stable section in the cine frame of all the cine image data. The normal section 302A is a part of the bar indicating the normal section among all the cine frames. The cursor 303 is an operation display element that is arranged at the position of the display frame number corresponding to the synthetic elastic image 210 and receives the selection input of the cine frame to be displayed from the inspector via the operation input unit 11, and is a stable section 301A. And the movement change input is possible to the left and right on the normal section 302A. The frame number display field 310 is a display field indicating the frame numbers in the order of the synthetic elastic image 210 (cursor 303) out of the number of cine frames of all the cine image data. It is preferable that the display colors of the stable section 301A and the normal section 302A are different.

The feature amount display information 400 is a display column for the distortion amount d as the default feature amount. The feature amount display information 400 has a graph unit 401, a reference area 402, and a frame unit 403. In the graph unit 401, the horizontal axis is the time, the vertical axis is the value of the strain amount d of the feature amount, and the center of the vertical axis of the feature amount display information 400 is the reference value. is there. The right end of the graph unit 401 is the distortion amount d of the frame immediately before the freeze. The reference region 402 is an region indicating an appropriate range of the value of the strain amount d from the center of the vertical axis of the feature quantity display information 400. That is, when the graph portion 401 is within the reference region 402, it indicates that the strain amount d of that portion is appropriate, and when the graph portion 401 protrudes from the reference region 402, the strain amount d of that portion is not appropriate. Shown.

The frame portion 403 is a frame portion of the feature amount display information 400, and the display color is set to determine whether or not the cine frame corresponding to the cursor 303 is a stable section. For example, when the cine frame corresponding to the cursor 303 is a stable section, the frame portion 403 is displayed in the same display color as the stable section 301A.

The feature amount switching button 410 is an operation display element that receives switching input of the type of feature amount displayed by the feature amount display information 400 displayed from the inspector via the operation input unit 11. For example, each time the feature amount switching button 410 is pressed, the feature amount of the feature amount display information 400 is switched as follows: distortion amount d → tempo b → reliability value s → distortion amount d → ... When the feature amount switching button 410 is touch-input via the operation input unit 11 in response to step S24, the control unit 21 outputs the displayed feature amount information after switching to the feature amount calculation unit 17. The feature amount calculation unit 17 reads out the display information of the feature amount corresponding to the input display feature amount information of the same display frame number from the storage unit 17a and outputs it to the display image generation unit 19. The display image generation unit 19 generates display image data by synthesizing the composite elastic image data of the same display frame number, the display information of the feature amount after switching, and the cine frame selection bar, and displays the display image on the display unit 20. Let me. The display information of the feature amount is not limited to the display format of the graph over time, and may be another display format such as a numerical display of the feature amount.

Further, when the display cine frame is selected and input by moving the cursor 303 via the operation input unit 11 in response to step S22, the composite image data, the cine frame selection bar, corresponding to the selected display frame number, The display information of the feature amount after switching and the display image including the display are displayed.

As described above, according to the present embodiment, the ultrasonic diagnostic apparatus 100 supplies the drive signal to the ultrasonic probe 2 and processes the received signal output from the ultrasonic probe 2, and the processed received signal. Based on, a plurality of types of feature amounts indicating the pressed state for each frame of the elastic image are calculated, an evaluation value is calculated from the calculated plurality of feature amounts, and the pressed state is good based on the evaluated value. A cine frame selection bar is generated as information on a stable section composed of frames, and the generated cine frame selection bar is displayed on the display unit 20.

Therefore, the inspector can easily visually confirm and select the frame of the elastic image of the stable section in which the pressing state is good based on a plurality of types of feature quantities.

Further, the ultrasonic diagnostic apparatus 100 generates elastic image data based on the received signal, generates display information of a plurality of calculated feature quantities, and displays the generated elastic image data and the plurality of feature quantities. It is stored in the storage units 15a and 17a, and in the cine mode, it accepts the input of the type of the feature amount to be displayed among the plurality of feature amounts and the input of the display frame of the elastic image data to be displayed, and corresponds to the input display frame. The stored elastic image data and the display information of the stored feature amount corresponding to the display frame and the type of the input feature amount are displayed on the display unit 20. Therefore, the inspector can visually recognize the feature amount of the displayed cine frame.

Further, the feature amount display unit 400 includes a frame unit 403 that indicates whether or not the display frame is a stable section by a display color. Therefore, the inspector can easily recognize the feature amount of the displayed cine frame together with the information on whether or not it is a stable section.

(Modification example)
A plurality of modified examples of the above-described embodiment will be described in order.

In the first modification, in the ultrasonic diagnostic apparatus 100, when the control unit 21 starts the cine mode, the display frame number of the cine image data to be displayed by the initial setting corresponding to the cursor is displayed as a cine frame other than immediately after the freeze. It is a configuration to be set in the frame number. For example, the control unit 21 sets the display frame number of the cine image data to be displayed at the start of the cine mode to the frame number of the cine frame within the stable section (for example, the center of the stable section). According to this configuration, the information of the cine frame of the stable section, which is important for diagnosis, can be confirmed first, the diagnosis can be performed accurately, and the diagnosis time can be shortened.

In the second modification, in the ultrasonic diagnostic apparatus 100, the control unit 21 performs the same movement operation from the inspector via the operation input unit 11 in the movement display of the cursor on the cine frame selection bar within the normal section. The configuration is such that the moving speed of the cursor in the stable section is set slower than that. This configuration facilitates the selection of display cine frames for stable sections, which are important for diagnosis.

In the third modification, in the ultrasonic diagnostic apparatus 100, the evaluation value calculation unit 18 makes it easier to set the cine frame immediately before the freeze of the cine frame selection bar to a stable section than the cine frame other than immediately before the freeze. is there. For example, a configuration in which the evaluation value of the cine frame immediately before the freeze is multiplied by a predetermined coefficient of 1 or more, a configuration in which the threshold value for determining a stable interval with respect to the moving average value of the evaluation value including the evaluation value of the cine frame immediately before the freeze is lowered, etc. There is. According to this configuration, it is possible to easily set the latest frame that the inspector has determined to be important and freeze-operated as a stable section that is important for diagnosis, and the diagnosis can be performed more accurately.

In the fourth modification, in the ultrasonic diagnostic apparatus 100, the evaluation value calculation unit 18 calculates a moving average value corresponding to a predetermined number of frames up to now during the live mode, and a stable section based on the evaluation value. The configuration is such that the information of the normal section is output to the display image generation unit 19, and the display image generation unit 19 displays the input stable section information on the display unit 20 together with the live composite image data. According to this configuration, even in the live mode, the inspector can visually recognize the frame of the elastic image in the stable section in which the pressed state is good based on a plurality of types of features.

In the fifth modification, in the ultrasonic diagnostic apparatus 100, the evaluation value calculation unit 18 calculates the moving average value corresponding to a predetermined number of frames up to now during the live mode, and the stable section based on the evaluation value. The configuration is such that information on the normal section is output to the control unit 21. Further, the control unit 21 determines whether or not the evaluation value satisfies a predetermined condition set in advance, and automatically sets the freeze when the predetermined condition is satisfied. The predetermined condition is, for example, that the moving average value of the evaluation value is equal to or higher than the second predetermined threshold value different from the first predetermined threshold value for determining the stable interval. According to this configuration, even in the live mode, the inspector can easily visually confirm the elastic image frame corresponding to the stable section, which is important for diagnosis, as the elastic image of the still image frame.

The description in the above-described embodiment and modification is an example of an operation method of a suitable ultrasonic diagnostic apparatus and ultrasonic diagnostic apparatus according to the present invention, and is not limited thereto. For example, at least two of the above-described embodiments and modifications may be combined.

Further, in the above-described embodiment and modification, the stable section in the cine frame selection bar is set to the same color, but the present invention is not limited to this. The stable section may have a different display color depending on the height of the evaluation value. For example, the display color of the stable section may be darkened as the evaluation value becomes higher. According to this configuration, the height of the evaluation value of the stable section can be easily confirmed, and each stable section can be easily identified, especially when there are a plurality of stable sections in the cine frame selection bar.

Further, in the above embodiment, the elastic image data is configured to generate and use image data indicating the amount of distortion as elastic data by strain elastography, but the present invention is not limited to this. For example, image data indicating the shear wave velocity as elastic data may be generated and used as elastic image data by Shear Wave Elastography.

Further, the detailed configuration and detailed operation of each part constituting the ultrasonic diagnostic apparatus 100 in the above embodiments and modifications can be appropriately changed without departing from the spirit of the present invention.

As described above, the ultrasonic diagnostic apparatus and the operating method of the ultrasonic diagnostic apparatus of the present invention can be applied to ultrasonic diagnosis using elastic images.

100 Ultrasonic diagnostic device 1 Ultrasonic diagnostic device main unit 11 Operation input unit 12 Transmission unit 13 Reception unit 14 B-mode image generation unit 14a, 15a, 17a, 18a Storage unit 15 Elastic image generation unit 16 Elastic image synthesis unit 17 Feature amount calculation Unit 18 Evaluation value calculation unit 19 Display image generation unit 20 Display unit 21 Control unit 2 Ultrasonic probe 2a Oscillator 3 Cable

Claims (8)

An ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmitter that transmits a drive signal to the ultrasonic probe,
A receiving unit that processes the received signal output from the ultrasonic probe, and
An evaluation value calculation unit that generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation unit.
A display control unit that displays the generated stable section information on the display unit,
An elastic image generation unit that generates elastic image data based on the received signal is provided.
In the live mode, the display control unit displays the generated elastic image data and the generated stable section information on the display unit .
The evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and has a cine frame selection bar having a cursor capable of changing the movement. An ultrasonic diagnostic apparatus that generates an image and sets an initial setting display frame corresponding to the cursor to a display frame within the stable section. An ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmitter that transmits a drive signal to the ultrasonic probe,
A receiving unit that processes the received signal output from the ultrasonic probe, and
An evaluation value calculation unit that generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation unit.
A display control unit that displays the generated stable section information on the display unit,
An elastic image generation unit that generates elastic image data based on the received signal is provided.
In the live mode, the display control unit displays the generated elastic image data and the generated stable section information on the display unit.
The evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and has a cine frame selection bar having a cursor capable of changing the movement. To generate
An ultrasonic diagnostic apparatus including a cursor control unit that sets a slower moving speed of the cursor when the cursor is within the stable section than when the cursor is outside the stable section. An ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmitter that transmits a drive signal to the ultrasonic probe,
A receiving unit that processes the received signal output from the ultrasonic probe, and
An evaluation value calculation unit that generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation unit.
A display control unit that displays the generated stable section information on the display unit,
An elastic image generation unit that generates elastic image data based on the received signal is provided.
In the live mode, the display control unit displays the generated elastic image data and the generated stable section information on the display unit.
The evaluation value calculation unit calculates an evaluation value based on the processed received signal, and when calculating the evaluation value, the evaluation value of the frame immediately before the freeze operation is relative to the frame other than the frame immediately before the freeze operation. An ultrasonic diagnostic device that raises the target and generates information on stable sections. The ultrasonic diagnostic apparatus according to claim 3 , further comprising a freeze control unit that sets a freeze when the calculated evaluation value satisfies a predetermined condition. The evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and has a cine frame selection bar having a cursor capable of changing the movement. The ultrasonic diagnostic apparatus according to any one of claims 2 to 4, wherein the initial setting display frame corresponding to the cursor is set to the display frame in the stable section. It is a method of operating an ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmission step in which the transmission unit transmits a drive signal to the ultrasonic probe, and
A receiving process in which the receiving unit processes the received signal output from the ultrasonic probe, and
The evaluation value calculation unit generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation step.
A display control step in which the display control unit displays the generated stable section information on the display unit,
The elastic image generation unit includes an elastic image generation step of generating elastic image data based on the received signal.
In the display control step, the display control unit displays the generated elastic image data and the generated stable section information on the display unit in the live mode .
In the evaluation value calculation step, the evaluation value calculation unit indicates the frame of the stable section among the plurality of frames as the information of the generated stable section, indicates the display frame of the elastic image, and can perform the movement change operation. A method of operating an ultrasonic diagnostic apparatus that generates a cine frame selection bar having a cursor and sets an initial setting display frame corresponding to the cursor to a display frame within the stable section. It is a method of operating an ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmission step in which the transmission unit transmits a drive signal to the ultrasonic probe, and
A receiving process in which the receiving unit processes the received signal output from the ultrasonic probe, and
The evaluation value calculation unit generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation step.
A display control step in which the display control unit displays the generated stable section information on the display unit,
The elastic image generation unit includes an elastic image generation step of generating elastic image data based on the received signal.
In the display control step, the display control unit displays the generated elastic image data and the generated stable section information on the display unit in the live mode.
In the evaluation value calculation step, the evaluation value calculation unit indicates a frame of the stable section among a plurality of frames as the information of the generated stable section, indicates a display frame of an elastic image, and can perform a movement change operation. Generates a cine frame selection bar with a cursor and
A method of operating an ultrasonic diagnostic apparatus including a cursor control step in which a cursor control unit sets a moving speed of the cursor slower when the cursor is within the stable section than when the cursor is outside the stable section. It is a method of operating an ultrasonic diagnostic device that transmits and receives ultrasonic waves to a target subject that has been compressed by an ultrasonic probe that transmits and receives ultrasonic waves and measures the hardness of the target.
A transmission step in which the transmission unit transmits a drive signal to the ultrasonic probe, and
A receiving process in which the receiving unit processes the received signal output from the ultrasonic probe, and
The evaluation value calculation unit generates information on a stable section consisting of frames with a good pressing state based on the processed received signal, and an evaluation value calculation step.
A display control step in which the display control unit displays the generated stable section information on the display unit,
The elastic image generation unit includes an elastic image generation step of generating elastic image data based on the received signal.
In the display control step, the display control unit displays the generated elastic image data and the generated stable section information on the display unit in the live mode.
In the evaluation value calculation step, the evaluation value calculation unit calculates an evaluation value based on the processed received signal, and when calculating the evaluation value, immediately before the freeze operation rather than a frame other than immediately before the freeze operation. A method of operating an ultrasonic diagnostic device that generates information on a stable section by relatively increasing the evaluation value of the frame.

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