JP2000316859A - Ultrasonic doppler rheometer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To distinguish Doppler shift components generated by bloodstream from Doppler shift components generated by the movement of a living tissue by means of an ultrasonic Doppler rheometer and to display only the Doppler shift components generated by bloodstream as bloodstream images. SOLUTION: This ultrasonic Doppler rheometer is provided with bloodstream image display circuitry 5 which determines whether a Doppler shift component computed as to a received ultrasonic signal is generated by bloodstream or the movement of a living tissue, and which displays the Doppler shift component as a bloodstream image if it is generated by bloodstream but does not display a bloodstream image if it is generated by the movement of the living tissue. Thus, Doppler shift components generated by bloodstream can be distinguished from Doppler shift components generated by the movement of the living tissue, and only the Doppler shift components generated by bloodstream can be displayed as bloodstream images.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to transmitting and receiving ultrasonic waves in a subject, obtaining the two-dimensional dynamics of blood flow using the ultrasonic Doppler effect, and displaying a two-dimensional blood flow image in the subject. Ultrasound Doppler blood flow meter, in particular, discriminates between the Doppler shift component caused by blood flow and the Doppler shift component caused by the movement of living tissue, and only the Doppler shift component caused by blood flow is subjected to a blood flow image. Ultrasonic Doppler blood flow meter that can be displayed as:

[0002]

2. Description of the Related Art A conventional ultrasonic Doppler blood flow meter of this kind is:
For example, as described in Japanese Patent Application Laid-Open No. 61-191346, a probe having a plurality of transducer channels and transmitting and receiving ultrasonic waves to and from a subject, and driving the probe to provide a plurality of channels. An ultrasonic transmission / reception system that transmits ultrasonic waves and receives reflected waves of a plurality of channels from the inside of the subject to generate an ultrasonic reception signal, and receives an ultrasonic reception signal from the ultrasonic transmission / reception system and inputs a tomographic image. A tomographic image display circuit system to be reconstructed as: a blood flow information calculation circuit for inputting an ultrasonic reception signal from the ultrasonic transmission / reception system and calculating a Doppler shift component of the ultrasonic reception signal; A blood flow image storage circuit for storing an output from the arithmetic circuit, and a blood flow tomographic image reconstructed as a two-dimensional tomographic image using the blood flow information output from the blood flow image storage circuit; Tomographic image information from the image display circuit A blood flow image display circuit system for displaying a tomographic image and a blood flow tomographic image on a display device, and inputting an image signal from the blood flow image display circuit system to display a tomographic image and a blood flow tomographic image And a display device.

[0003]

However, in such a conventional ultrasonic Doppler blood flow meter, the blood flow is generated by respiration or the like using an MTI (Moving Target Indication) filter or the like provided in a blood flow information calculation circuit. Although we devised to remove the unnecessary Doppler shift component caused by the movement of the organ in the subject, the Doppler shift component caused by the blood flow and the Doppler shift component caused by the movement of the biological tissue were removed. Since it has not been discriminated, not only signal components that have undergone Doppler shift due to blood flow, but also unnecessary Doppler shift components caused by movement of internal organs in the subject caused by respiration etc. It was what was displayed. Therefore, the user of the ultrasonic Doppler blood flow meter discriminates between the Doppler shift component caused by the blood flow and the Doppler shift component caused by the movement of the living tissue just by looking at the displayed blood flow image. As a result, it was difficult to observe the trend of blood flow in a living body. As a result, the diagnostic ability was sometimes reduced.

In view of the above, the present invention has been made to address such a problem, and distinguishes between a Doppler shift component caused by a blood flow and a Doppler shift component caused by the movement of a living tissue. It is an object of the present invention to provide an ultrasonic Doppler blood flow meter capable of displaying only a shift component as a blood flow image.

[0005]

In order to achieve the above object, an ultrasonic Doppler blood flow meter according to the present invention transmits and receives ultrasonic waves inside a subject, receives reflected waves from inside the subject, and transmits ultrasonic waves. The phasing process is performed on the received sound signal, an ultrasonic tomographic image is formed using the signal obtained by the phasing process, and the Doppler shift component of the received ultrasonic signal is calculated using the signal obtained by the phasing process. Then, a two-dimensional blood flow is obtained, a two-dimensional blood flow image is formed using the obtained two-dimensional blood flow signal, and one of the two-dimensional blood flow image and the ultrasonic tomographic image is obtained. Or an ultrasonic Doppler blood flow meter that outputs both signals and displays this output signal as an image, determines whether the calculated Doppler shift component is caused by blood flow or by movement of a living tissue, The generated Doppler shift component is displayed as a blood flow image. For Doppler shift component caused by the motion of the living tissue it is provided with a means for controlling so as not to appear as a blood flow image.

Then, it is determined whether the calculated Doppler shift component is caused by the blood flow or the movement of the living tissue by using the blood flow information at the time of calculating the two-dimensional dynamics of the blood flow. It is determined whether the blood flow intensity information or the blood flow distribution information for each screen is smaller or larger than a predetermined threshold value, or a difference calculation result obtained by subtracting the blood flow intensity information for each screen or the blood flow dispersion information is used as a difference. The determination may be made based on whether the difference calculation result obtained is smaller or larger than a predetermined threshold value.

[0007]

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a block diagram showing an embodiment of an ultrasonic Doppler blood flow meter according to the present invention. This ultrasonic Doppler blood flow meter transmits and receives ultrasonic waves to and from the subject, obtains the two-dimensional dynamics of the blood flow using the ultrasonic Doppler effect, and displays a two-dimensional blood flow image in the subject. As shown in FIG. 1, a probe 1, an ultrasonic transmission / reception circuit system 2, a tomographic image display circuit system 3, a blood flow calculation circuit system 4, a blood flow image display circuit system 5, and an image display 6.

The probe 1 transmits and receives ultrasonic waves to and from a diagnostic site in a subject. Inside the probe 1, there are provided a plurality of transducers for actually emitting ultrasonic waves and receiving reflected waves from the diagnostic site. Have. The ultrasonic transmission / reception circuit system 2 drives the probe 1 to transmit and receive ultrasonic waves, and performs phasing processing of the ultrasonic reception signal received by the probe 1.
It has a transmitting circuit, a receiving circuit, a phasing circuit and the like inside.

The tomographic image display circuit system 3 forms an ultrasonic tomographic image using the output signal from the ultrasonic transmitting and receiving circuit system 2. The blood flow calculation circuit system 4 calculates the Doppler shift component of the ultrasonic reception signal using the output signal from the ultrasonic transmission / reception circuit system 2 to obtain the two-dimensional dynamics of the blood flow. The two-dimensional dynamics of the blood flow are calculated using blood flow information such as blood flow velocity information, blood flow intensity information, and blood flow dispersion information of the shift component.

The blood flow image display circuit system 5 forms a two-dimensional blood flow image using the output signal of the blood flow calculation circuit system 4 and outputs the two-dimensional blood flow image and the tomographic image display circuit system 3. And outputs one or both of the ultrasonic tomographic images, and outputs the output signal to an image display 6 described later. The image display 6 displays an output signal from the blood flow image display circuit system 5 as an image, and is composed of, for example, a television monitor.

Here, in the present invention, the blood flow image display circuit system 5 is configured so that the Doppler shift component calculated by the blood flow calculation circuit system 4 is generated by the blood flow or by the movement of the living tissue. If it is determined to be a Doppler shift component caused by blood flow, it is displayed as a blood flow image, and if it is determined to be a Doppler shift component caused by movement of a living tissue, it is not displayed as a blood flow image. As shown in FIG. 1, a blood flow image memory circuit 7, a blood flow determination circuit system 8, an encoder circuit 9,
And an image selection circuit 10.

The blood flow image memory circuit 7 is for holding the output signal from the blood flow calculation circuit system 4 for a plurality of screens. The output signal from the blood flow calculation circuit system 4 is, for example, a blood flow speed. Information, blood flow intensity information, and blood flow dispersion information, a blood flow speed information memory circuit 7a for a plurality of screens, respectively.
And a blood flow intensity information memory circuit 7b and a blood flow dispersion information memory circuit 7c.
The blood flow information is sequentially stored in b and 7c.

The blood flow discrimination circuit system 8 uses the output signal of the blood flow image memory circuit 7 to determine whether the Doppler shift component calculated by the blood flow calculation circuit system 4 is caused by a blood flow or a living tissue. The internal configuration of the blood flow determination circuit 1 is determined as shown in FIG.
1, blood flow intensity information averaging circuit 12, blood flow velocity information averaging circuit 13, blood flow variance information averaging circuit 14, AN
D gates 15a, 15b and 15c.

The blood flow discrimination circuit 11 includes a blood flow intensity information memory circuit 7b or a blood flow dispersion information memory circuit 7 for a plurality of screens.
The comparison of the blood flow intensity information or the blood flow dispersion information of an arbitrary pixel of the output of c is performed, and the difference calculation result of the blood flow intensity information or the blood flow dispersion information for each screen, or the blood flow intensity information or the blood flow dispersion information If the value itself is smaller than a predetermined threshold value, it is determined that the blood flow information of the pixel has undergone the Doppler shift due to the blood flow. It is determined that a Doppler shift has occurred due to the movement of the tissue. FIG. 2 shows only the case where the calculation is performed on the blood flow intensity information from the blood flow intensity information memory circuit 7b, and the case where the calculation is performed on the blood flow distribution information is omitted.

The blood flow intensity information averaging circuit 12 improves the temporal connection between blood flow image screens when the blood flow determination circuit 11 determines that a Doppler shift has occurred due to blood flow. First, an averaging process between screens is performed on the blood flow intensity information from the blood flow intensity information memory circuit 7b.
The blood flow velocity information averaging circuit 13 also performs an averaging process between screens on the blood flow velocity information from the blood flow velocity information memory circuit 7a. Further, the blood flow distribution information averaging circuit 14 also includes a blood flow distribution information memory circuit 7c.
Averaging process between screens is performed on the blood flow distribution information from.

The first AND gate 15a performs an AND operation on an output signal from the blood flow discriminating circuit 11 and an output signal from the blood flow intensity information averaging circuit 12, and a second AND gate 15b. Is used to AND the output signal from the blood flow discriminating circuit 11 and the output signal from the blood flow velocity information averaging circuit 13.
5c is an AND operation between the output signal from the blood flow discrimination circuit 11 and the output signal from the blood flow dispersion information averaging circuit 14. Then, the AND gates 15a, 15
The output signals b and 15c are sent to the encoder circuit 9.

The encoder circuit 9 uses the output signal from the blood flow discrimination circuit system 8 to convert the color to a hue corresponding to the blood flow information and outputs a blood flow image signal. Further, the image selecting circuit 10 selects one of the two or uses the signal of the blood flow image from the encoder circuit 9 and the signal of the tomographic image from the tomographic image display circuit system 3 or selects both of them. The image to be superimposed is output and an image to be displayed is selected.

Next, the operation of the blood flow discrimination circuit 8 of the blood flow image display circuit 5 configured as described above will be described with reference to FIG. Here, for simplicity, only a blood flow discrimination method based on blood flow intensity information will be described. Now, as shown in FIG. 3, the blood flow intensity information memory circuit 7b
Stores blood flow information for three screens as shown in (a) to (c), and based on these information, performs blood flow discrimination processing as shown in (d) and blood flow information as shown in (e). Averaging processing is performed. In FIG. 3, the full scale of the blood flow intensity information is set to “100”.

First, in FIG. 2, in the blood flow discriminating circuit 11, among the blood flow intensity information stored in the blood flow intensity information memory circuit 7b at an arbitrary pixel, the screen of the intermediate frame shown in FIG. Blood flow intensity information D ₂ and FIG.
(A) when the difference between the blood flow intensity information D ₁ and D _{3 on} the screen before and after the frame shown in (c) is more than half the full scale of the blood flow intensity information, or , when the blood flow intensity information D ₂ of the screen of the intermediate frame is 2/3 or more with respect to the full scale, the blood flow information of the pixel is the Doppler shift component caused by the motion of the living tissue Judge. On the contrary, the blood flow intensity information D ₁ of the screen before and after the blood flow intensity information D ₂ of the screen of the intermediate frame frame, D
Difference from ₃ is 1/2 of full scale of blood flow intensity information
If smaller, or if the blood flow intensity information D _{2 on} the screen of the intermediate frame is smaller than ／ of the full scale, the blood flow information of the pixel is a Doppler shift component caused by the blood flow. Judge that there is.

If it is determined that the signal has undergone the Doppler shift due to the blood flow at an arbitrary pixel, the output of the blood flow determining circuit 11 at that pixel is set to "1", thereby determining the blood flow. AND gate 15a at the output stage of circuit 8
15b and 15c are blood flow intensity information averaging circuits 1 respectively.
2. The output signals of the blood flow velocity information averaging circuit 13 and the blood flow variance information averaging circuit 14 are sent to the encoder circuit 9 shown in FIG. 1 as they are, and the blood flow information is transmitted through the image selection circuit 10 to the image display 6. The image is displayed on the image display 6 as a blood flow image at the pixel.

On the other hand, if an arbitrary pixel is determined to be a signal that has undergone Doppler shift due to the movement of the living tissue, the output of the blood flow discriminating circuit 11 at that pixel is set to "0", The outputs of the AND gates 15a, 15b, 15c at the output stage of the flow discriminating circuit system 8 become "0", and FIG.
Is transmitted to the encoder circuit 9 shown in FIG.
And the blood flow image is not displayed on the image display 6 at the pixel.

[0022] More specifically, in FIG. 3, at time t2, t3, and the blood flow intensity information D ₂ of the screen of the intermediate frame shown in (b), before and after shown in (a), (c) a frame The difference from the blood flow intensity information D ₁ or D _{3 on} the screen of “1” is “60”, respectively, and there is a difference of 1/2 or more with respect to the full scale “100” of the blood flow intensity information. Judging that the signal has undergone Doppler shift,
Each output of the blood flow discrimination circuit 11 as shown in (d) is "0", the other time t6, a blood flow intensity information D ₂ of the screen of the intermediate frame shown in (b) is "70", Since it is 2/3 or more of the full scale "100" of the blood flow intensity information, the output of the blood flow determination circuit 11 is set to "0". At other times, it is determined that the signal has undergone the Doppler shift due to the blood flow, and the output of the blood flow determination circuit 11 is set to "1" as shown in (d). Thereby, (e)
As shown in (1), the blood flow intensity information averaging circuit 12 performs an averaging process on the blood flow information and outputs the result.

In the same manner as the blood flow discrimination method based on the blood flow strength information, the blood flow discrimination based on the blood flow dispersion information is performed, or both the blood flow strength information and the blood flow dispersion information are combined. It is also possible to perform a blood flow discrimination.

FIG. 4 is a block diagram showing a second embodiment of the present invention. In this embodiment, the blood flow image display circuit 5
In the internal configuration of the above, the blood flow image memory circuit 7 and the blood flow determining circuit system 8 are exchanged, and the output of the blood flow determining circuit system 8 is held by the blood flow image memory circuit 7 for one screen. The system 8 uses the output from the blood flow calculation circuit system 4 and the output from the blood flow image memory circuit 7 to receive a Doppler shift due to a blood flow or a Doppler shift due to the movement of a living tissue. That is, it is determined whether or not the signal is a signal.

Here, the blood flow image memory circuit 7 is for holding an output signal from a blood flow determination circuit system 8 described later for one screen. For example, in the case of blood flow velocity information, blood flow intensity information, and blood flow dispersion information, the blood flow velocity information memory circuit 7a and
A blood flow intensity information memory circuit 7b and a blood flow dispersion information memory circuit 7c are provided, and each of the memory circuits 7a, 7b,
The blood flow information is sequentially stored in 7c.

The blood flow discrimination circuit system 8 uses the output from the blood flow operation circuit system 4 and the output from the blood flow image memory circuit 7 to determine whether the signal has undergone a Doppler shift due to the blood flow or This is for determining whether the signal has undergone the Doppler shift due to the movement of the living tissue, and has an internal configuration as shown in FIG. Blood flow velocity information moving average circuit 13 ', blood flow dispersion information moving average circuit 14', and AND gate 15
a, 15b and 15c.

The blood flow discrimination circuit 11 compares the output of the blood flow intensity information from the blood flow calculation circuit system 4 with the blood flow intensity information of an arbitrary pixel output from the blood flow intensity information memory circuit 7b. Or a comparison between the output of the blood flow distribution information from the blood flow calculation circuit system 4 and the blood flow distribution information of an arbitrary pixel output from the blood flow distribution information memory circuit 7c. Blood flow intensity information from the system 4 and the blood flow intensity information memory circuit 7b or the blood flow calculation circuit system 4 and the blood flow dispersion information memory circuit 7
If the difference calculation result of the blood flow variance information from c or the respective blood flow intensity information or the blood flow variance information itself is smaller than a predetermined threshold value, the blood flow information of the pixel is Doppler deviated by the blood flow. It is determined that the pixel has undergone a shift, and if it is greater than a predetermined threshold, the blood flow information of that pixel is determined to have undergone a Doppler shift due to movement of the living tissue. FIG. 5 shows only the case where the calculation is performed on the blood flow intensity information from the blood flow calculation circuit system 4 and the blood flow intensity information memory circuit 7b, and the case where the calculation is performed on the blood flow dispersion information is omitted.

The blood flow intensity information moving averaging circuit 12 '
When the blood flow discrimination circuit 11 determines that a Doppler shift has occurred due to the blood flow, the blood flow from the blood flow intensity information memory circuit 7b is used to improve the temporal connection between the screens of the blood flow images. The moving average processing between screens is performed on the intensity information. Also, a blood flow velocity information moving average circuit 13 '
Performs moving average processing between screens on the blood flow velocity information from the blood flow velocity information memory circuit 7a. Further, the blood flow variance information moving averaging circuit 14 'performs a moving averaging process between screens on the blood flow variance information from the blood flow variance information memory circuit 7c.

Here, each of the moving average circuits 12 ', 1
3 'and 14' operate as follows. First, if it is determined that information of an arbitrary pixel is a component that has undergone Doppler shift due to blood flow, a moving averaging process is performed based on the following equation (1). Dout = α × Dnew + (1−α) × Dold (1) where Dout: the output of the moving average processing Dnew: the output of the blood flow calculation circuit system 4 Dold: the output of the blood flow image memory circuit 7 α: The weighting coefficient (0 ≦ α ≦ 1) Next, if it is determined that the information of an arbitrary pixel is a component that has undergone Doppler shift due to the movement of the living tissue, the moving average is calculated as in the following equation (2). Set the output of the process to zero. Dout = 0 (2) In this case, the blood flow information is not displayed on the image display 6.

Further, in the moving averaging process of the blood flow information, in the blood flow determination based on the blood flow intensity information, when it is determined that the blood flow information of an arbitrary pixel has undergone a Doppler shift due to the blood flow, The moving average value of the output of the flow image memory circuit 7 is calculated. In the equation (1), α = 0.5.
It should be assumed that

The first AND gate 15a performs an AND operation on the output signal from the blood flow discriminating circuit 11 and the output signal from the blood flow intensity information moving averaging circuit 12 '. The output of the blood flow intensity information is sent to the blood flow intensity information memory circuit 7b. The second AND gate 15b ANDs the output signal from the blood flow discrimination circuit 11 and the output signal from the blood flow velocity information moving averaging circuit 13 ', and calculates the blood flow velocity obtained by taking the AND. The output of the information is sent to the blood flow velocity information memory circuit 7a. The third AND gate 15c is connected to the output signal from the blood flow discrimination circuit 11 and the blood flow distribution information moving average circuit 1
4 'and the output of the blood flow distribution information obtained by the AND operation is sent to the blood flow distribution information memory circuit 7c.

Then, in FIG. 4, the encoder circuit 9
Uses the output signal from the blood flow image memory circuit 7
It converts the color to a hue corresponding to the blood flow information and outputs a blood flow image signal.

Next, the operation of the blood flow discrimination circuit system 8 of the blood flow image display circuit system 5 configured as described above will be described with reference to FIG. Here, for simplicity, only a blood flow discrimination method based on blood flow intensity information will be described. Now, in FIG. 6, the blood flow discrimination circuit 11 includes an output D ₀ of blood flow intensity information from the blood flow calculation circuit system 4 shown in FIG.
Output D ₄ and enters the bloodstream intensity information of a blood flow intensity information memory circuit 7b shown in (b), the blood flow determination process as the basis of the information (c), as (d) It is assumed that moving average processing of blood flow information is performed. In FIG. 6,
The full scale of the blood flow intensity information is set to “100”.

In the blood flow discriminating circuit 11, an arbitrary pixel
The output D of the blood flow intensity information from the blood flow arithmetic circuit 4
₀And blood flow stored in the blood flow intensity information memory circuit 7b
Output of strength information D_FourIs the difference between the full-scale
Of the blood flow calculation circuit 4
When the blood flow intensity information is more than 2/3 of full scale
Indicates that the blood flow information of the pixel
It is determined that the component has undergone the La shift. On the contrary,
Output D of blood flow intensity information from blood flow calculation circuit system 4 ₀And blood flow
Blood flow intensity information stored in the intensity information memory circuit 7b
Output D_FourDifference with the full scale of blood flow intensity information
Less than 1/2 or the blood flow of the blood flow calculation circuit system 4
If the intensity information is smaller than 2/3 of full scale,
The blood flow information of the pixel is the Doppler shift generated by the blood flow.
Judge that it is minutes.

If it is determined that the signal has undergone the Doppler shift due to the blood flow at an arbitrary pixel, the output of the blood flow determining circuit 11 at the pixel is set to "1", thereby determining the blood flow. AND gate 15a at the output stage of circuit 8
Reference numerals 15b and 15c denote output signals of the blood flow intensity information moving average circuit 12 ', the blood flow velocity information moving average circuit 13', and the blood flow dispersion information moving average circuit 14 ', respectively, as they are in FIG.
And the blood flow information is transmitted to the image display 6 via the encoder circuit 9 and the image selection circuit 10.
The image is displayed on the image display 6 as a blood flow image at the pixel.

On the other hand, if an arbitrary pixel is determined to be a signal that has undergone Doppler shift due to the movement of the living tissue, the output of the blood flow discriminating circuit 11 at that pixel is set to “0”, and The outputs of the AND gates 15a, 15b, 15c at the output stage of the flow discriminating circuit system 8 become "0", and FIG.
The zero data is sent to the blood flow image memory circuit 7 shown in FIG.
The zero data is stored in the encoder circuit 9 and the image selection circuit 1
0, the image is sent to the image display 6, and the blood flow image is not displayed on the image display 6 at the pixel.

More specifically, in FIG. 6, at time t2, the output D ₀ of the blood flow intensity information of the blood flow calculation circuit system 4 shown in FIG. 6A and the blood flow intensity information memory shown in FIG. the difference between the output D ₄ of the blood flow intensity information circuit 7b is "6
1 ", which is a difference of 1/2 or more with respect to the full scale" 100 "of the blood flow intensity information. Therefore, it is determined that the signal has undergone the Doppler shift due to the movement of the living tissue, and as shown in FIG. The output of the blood flow discrimination circuit 11 is set to “0” at another time t.
In 5, the output D ₀ of the blood flow intensity information of the blood flow calculation circuit system 4 shown in (a) is “70”, which is ／ or more of the full scale “100” of the blood flow intensity information. Similarly, the output of the blood flow discrimination circuit 11 is set to “0”. At other times, it is determined that the signal has undergone the Doppler shift due to the blood flow, and the output of the blood flow determination circuit 11 is set to "1" as shown in (c). As a result, as shown in (d), the blood flow intensity information moving averaging circuit 12 'performs a moving average process on the blood flow information and outputs the result.

In the same manner as the blood flow discrimination method based on the blood flow strength information, the blood flow discrimination based on the blood flow dispersion information is performed, or both the blood flow strength information and the blood flow dispersion information are combined. It is also possible to perform a blood flow discrimination.

[0039]

The present invention has been configured as described above.
It is determined whether the Doppler shift component calculated with respect to the ultrasonic reception signal is caused by blood flow or movement of living tissue, and in the case of the Doppler shift component caused by blood flow, it is displayed as a blood flow image. Means for controlling the Doppler shift component caused by the movement of the blood flow so that the Doppler shift component caused by the blood flow and the Doppler shift component caused by the movement of the living tissue are provided. Can be determined, and only the Doppler shift component caused by the blood flow can be displayed as a blood flow image. Therefore, it is easy to observe the blood flow trend in the living body, and the diagnostic performance can be improved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of an ultrasonic Doppler blood flow meter according to the present invention.

FIG. 2 is a block diagram showing an internal configuration of a blood flow discrimination circuit system in the blood flow image display circuit system.

FIG. 3 is a time chart for explaining the operation of the blood flow discrimination circuit system.

FIG. 4 is a block diagram showing a second embodiment of the present invention.

FIG. 5 is a block diagram showing an internal configuration of a blood flow discrimination circuit system according to the second embodiment.

FIG. 6 is a time chart for explaining the operation of the blood flow discrimination circuit system in the second embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Probe 2 ... Ultrasonic transmission / reception circuit system 3 ... Tomographic image display circuit system 4 ... Blood flow calculation circuit system 5 ... Blood flow image display circuit system 6 ... Image display 7 ... Blood flow image memory circuit 8 ... Blood flow Discrimination circuit system 9 Encoder circuit 10 Image selection circuit 11 Blood flow discrimination circuit 12 Blood flow intensity information averaging circuit 12 ′ Blood flow intensity information moving averaging circuit 13 Blood flow velocity information averaging circuit 13 ′ Blood flow velocity information moving averaging circuit 14 Blood flow dispersion information averaging circuit 14 'Blood flow dispersion information moving average circuit 15a, 15b, 15c AND gate

Claims (1)

[Claims] 1. An ultrasonic wave is transmitted / received into / from a subject, a reflected wave from the subject is received, a phasing process of an ultrasonic reception signal is performed, and an ultrasonic tomography is performed using the phasing signal. An image is formed, and the Doppler shift component of the ultrasonic reception signal is calculated using the signal subjected to the phasing processing to obtain the two-dimensional dynamics of the blood flow. In the ultrasonic Doppler blood flow meter which configures a two-dimensional blood flow image and outputs one or both of the two-dimensional blood flow image and the ultrasonic tomographic image and displays the output signal as an image, It is determined whether the calculated Doppler shift component is caused by the blood flow or by the movement of the living tissue. In the case of the Doppler shift component caused by the blood flow, it is displayed as a blood flow image, and is generated by the movement of the living tissue. Doppler shift components are not displayed as blood flow images Ultrasonic Doppler blood flow meter provided with means for controlling the blood flow.