JPH03277352A - Ultrasonic diagnostic device - Google Patents

Abstract

PURPOSE:To easily detect a thin blood flow by providing a selecting circuit for selecting preferentially an output from a color interpolation circuit as interpolation data, when it is decided by a deciding circuit to display echo and color data. CONSTITUTION:With regard to each pixel on a scanning line, whether echo data is to be displayed or color data is to be displayed is decided by a deciding circuit 4. On the other hand, by an echo interpolating circuit 12, echo data to be inserted between adjacent ultrasonic scanning lines is generated. Also, by a color interpolating circuit 13, color data to be inserted between adjacent ultrasonic scanning lines is generated. In such a state, with regard to the corresponding pixels on the adjacent ultrasonic scanning lines, when it is decided by a deciding circuit 9 that one and the other are echo and color, respectively, an output from the color interpolating circuit is selected more preferentially than an output of the echo interpolating circuit. Accordingly, in the case one of the scanning lines is color and the other is echo, a color display area is displayed somewhat wide. In such a way, even in the case of a blood flow whose object basin is thin, the color display area is displayed somewhat wide.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an ultrasonic diagnostic apparatus, in particular, which combines echo data obtained from tomographic information with blood flow information based on ultrasonic reflection signals from within a living body. The present invention relates to an ultrasonic diagnostic apparatus that synthesizes and displays obtained color data.

[Conventional technology]

Ultrasonic diagnostic equipment used in the medical field, for example, displays tomographic data (echo data) of the heart on a monitor in real time, or measures the blood flow velocity in a specific region using the pulsed Doppler method, and calculates this distribution in the same way as above. Generally, it is displayed on a monitor. Furthermore, there is also a system that displays echo data on a monitor and also displays the blood flow velocity of a specific region side by side on the monitor on which the echo data is displayed.

Recently, in order to understand the blood flow velocity two-dimensionally, two
A dimensional blood flow tomography method is adopted. This combines echo data with blood flow velocity to express the blood flow velocity two-dimensionally and in real time. That is, the tomographic information and blood flow information are each digitized and combined, and converted into R, C, and B television signals. The blood flow velocity is displayed superimposed on the normal tomographic image, and the average velocity profile of the detected blood flow is displayed in color (color flow mapping).

In this way, in a method of displaying an echo tomographic image and a color flow image in a superimposed manner, for example, in B mode display, the decision as to whether to display echo or color on each pixel forming the image is made based on the echo intensity and It is done according to the color intensity. Based on this determination result, either echo or color is displayed for each pixel.

[Intelligence B to be Solved by the Invention] Generally, in B-mode display, the purpose is to display flow velocity information such as blood flow at an accurate position and at an accurate speed.

On the other hand, this day mode display is often used for the purpose of quickly discovering abnormal blood flow, for example.

However, with conventional ultrasonic diagnostic apparatuses, it is difficult to detect when the target area of ultrasonic diagnosis is a narrow blood flow such as an intragastric blood vessel or a peripheral blood vessel. Therefore, if an abnormal blood flow portion such as a backflow portion occurs in a narrow blood flow, a problem arises in that it is difficult to discover this abnormal blood flow portion.

An object of the present invention is to provide an ultrasonic diagnostic device that can easily detect thin blood flows.

[Means for Solving the Problems] The ultrasound diagnostic device according to the present invention is a device that synthesizes color data with echo data and displays it, and displays either echo data or color data on each pixel on an ultrasound scanning line. It includes a determination circuit that determines whether to display, an echo interpolation circuit and a color interpolation circuit that create echo data and color data to be interpolated between ultrasonic scanning lines, and an interpolation data selection circuit.

When the determination circuit determines that echo data is displayed on one side and color data is displayed on the other side for corresponding pixels on adjacent scanning lines, the interpolation data selection circuit selects the echo data as interpolation data. The output from the color interpolation circuit is selected preferentially over the output from the interpolation circuit.

[Effect]

In the ultrasonic diagnostic apparatus according to the present invention, first, the determination circuit creates echo data to be inserted between adjacent ultrasonic scan lines using an echo path for each pixel on a scan line. Further, a color interpolation circuit creates color data to be inserted between adjacent ultrasonic scan lines. When the determination circuit determines that one of corresponding pixels on adjacent ultrasonic scanning lines is an echo and the other is a color, the output from the color interpolation circuit is higher than the output from the echo interpolation circuit. is selected preferentially.

Therefore, if one of the scan lines is color and the other is echo, the color display area will be displayed wider. As a result, even if the target region is a narrow blood flow, the color display area is displayed in a wide area, thereby making it possible to easily discover the narrow blood flow.

[Embodiment] FIG. 3 shows a schematic configuration of an ultrasonic diagnostic apparatus according to an embodiment of the present invention.

In FIG. 3, a probe 1 is composed of a plurality of micro-oscillators, and is connected to a transmitting/receiving circuit 2. As shown in FIG. The transmitting/receiving port 82 includes a high-frequency pulse oscillator for transmitting an ultrasonic beam, a receiver for receiving and processing reflected echoes, a delay circuit and a delay amount selection circuit for performing electronic scanning, and the like.

The output of the transmission/reception (δ circuit 2) is connected to an echo reception wave shaping circuit 3 and a color Doppler detection and calculation circuit 4.

The echo reception wave shaping circuit 3 is a circuit for obtaining tomographic data (echo data) of a living body. The output of this echo reception wave shaping circuit 3 is connected to a display signal generation circuit 5.

Further, the color Doppler detection and calculation circuit 4 is a circuit for obtaining blood flow data of a living body based on the Doppler shift frequency. The output (here, color data) of the color Doppler detection and calculation circuit 4 is connected to a display signal generation circuit 5. This is a circuit for processing.

The output of the display signal generation circuit 5 is connected to a display 6. The display device 6 is for displaying the combined echo data and color data on the CRT.

FIG. 2 shows a schematic configuration of the display signal generation circuit 5. As shown in FIG. In FIG. 2, echo data output from the echo receiving wave shaping circuit 3 is input to an echo image buffer memory 7. Further, color data output from the color Doppler detection and calculation circuit 4 is input to a color image buffer memory 8. The outputs of the echo image buffer memory 7 and the color image buffer memory 8 are connected to an interpolation and echo/color determination circuit 10, which will be described later. Further, an echo/color determination circuit 9 is connected to the outputs of the echo image buffer memory 7 and the color image buffer memory 8. This echo/color determination circuit 9 is a circuit for determining whether echo data or color data is to be displayed for each pixel on an ultrasonic scanning line. The output of this echo/color determination circuit 9 is connected to an interpolation and echo/color determination circuit 10. The output of the interpolation and echo/color determination circuit 1O is connected to the display signal synthesis circuit 11.

Next, a schematic configuration of the interpolation and echo/color determination circuit IO will be explained using FIG. 1.

In FIG. 1, an echo interpolation circuit 12 is connected to the output of the echo image buffer memory 7. Further, the output of the color image buffer memory 8 is connected to a color interpolation circuit 1.
3 is connected. The echo interpolation circuit 12 is a circuit for creating echo data to be interpolated between adjacent ultrasound scan lines. Further, the color interpolation circuit is a circuit for creating color data to be interpolated between adjacent scanning lines. Echo interpolation circuit 2 and color interpolation circuit 1
The outputs of 3 are connected to echo/color determination circuits 14 and 15, respectively.

The echo/color judgment circuit 14 selects either echo data or color data for the interpolated data of each pixel using the same judgment criteria (threshold values) as the echo/color judgment circuit 9 in FIG. It is something. The echo/color determination circuit 15 also includes the echo/color determination circuit 1
The threshold value is set so that more color data than 4 is selected. In addition, the echo/color judgment circuit 9 (
A discrimination circuit 16 is connected to the output of FIG.

This determination circuit 16 is a circuit that checks whether echo data or color data is displayed for corresponding pixels of adjacent scanning lines. The output of this discrimination circuit 16 is the echo/color discrimination circuit 14 and 15.
It is connected to the. Echo/color judgment circuits 14 and 1
The output of 5 is connected to the selection circuit 17. The selection circuit 17 is a circuit for passing either one of the outputs of the echo/color determination circuits 14 and 15 according to the operator's selection.

Next, the operation will be explained.

First, the high frequency pulse oscillator of the transmitter/receiver circuit 2 is driven,
A high frequency pulse is applied to the probe 1.

As a result, an ultrasonic beam is transmitted from the probe l.

The reflected echo reflected within the living body is received by the probe 1,
The signal is input to the transmitter/receiver circuit 2. The reflected echo signal that has undergone predetermined processing in the transmitter/receiver circuit 2 is input to an echo reception wave shaping circuit 3 and a color Doppler detection and calculation circuit 4. The reflected echo signal input to the echo receiving wave shaping circuit 3 is subjected to signal processing such as amplification and waveform shaping, and then sent to the display signal generating circuit 5.
is input. In addition, color Doppler detection and calculation circuit 4
The reflected echo signal input to the display signal generating circuit 5 is subjected to signal processing such as amplification, waveform shaping, and detection processing, and then input to the display signal generation circuit 5.

In the display signal generation circuit 5, the echo signal from the echo receiving wave shaping circuit 3 is inputted to the echo image buffer memory 7.
Stored as echo data.

Further, the color signal from the color Doppler detection and measurement circuit 4 is input to the color image buffer memory 8 and stored as color data. The echo/color determination circuit 9 is
The echo data and color data stored in the echo image buffer memory 7 and the color image buffer memory 8 are read, and it is determined whether the data on the scanning line should be displayed as echo or color. The output of the echo/color determination circuit 9 is input to an interpolation and echo/color determination circuit 10.

In the interpolation and echo/color determination circuit 1O, the echo interpolation circuit 1
2 reads the echo data stored in the echo image buffer memory 7, and the echo interpolation circuit 12 creates echo data to be interpolated based on the read echo data.

Similarly, the color interpolation circuit 13 reads the color data stored in the color image buffer memory 8 in response to the output from the echo/color determination circuit 9. Then, the color interpolation circuit 13 creates color data to be interpolated based on the read color data.

Now, as shown in FIG. 4, the data of corresponding pixels 20 and 21 on adjacent scanning lines are all color (CL
, C++), color 〇 interpolation is performed. That is, in this case, the echo/color determination circuit 14.1
5 receives the instruction signal from the discrimination circuit 16 and selects the interpolation data output from the color interpolation circuit 13. For example, as shown in FIG.
cL+C,)lN, ((N~2)Ct+2C*)/
N,..., (CL ten (N-1) c, )l
Data weighted as N is used.

Also, as shown in FIG. 5, the corresponding pixels of the scanning line, 20, 2] are all echoes (E,).

In the case of El), echo interpolation is performed. In this case, the echo/color determination circuit 14.15 is the same as the determination circuit 1.
6 selects the interpolated data output from the echo interpolation circuit 12.

For example, as shown in FIG.
N-1) EL + El ) IN, [(N2) E
L +2El)lN,..., (Et+(N1)El
)lN using weighted data.

Next, as shown in FIG.
) and echo (E) will be explained.

In this case, first, as shown in FIG. 7A, the color interpolation circuit 13 receives the color (Ct) from the color image puffer memory 8 as the data of the pixel 20, and the color (cm') as the data of the pixel 21. Load. Note that this (, l is color data that was not selected as the data of the pixel 21 in the echo/power discrimination circuit 9.Then, the color interpolation circuit 13
In the same way as the fourth time, each interpolation data 11. between both pixels 20.21. L, ... as lN-1 C,,C
2. Create CM-1. On the other hand, the echo interpolation circuit 12 extracts the pixel 2 from the echo image buffer memory 7.
The echo (EL') is read out as 0 data, and the echo (IER) is read out as data of the pixel 21. Note that this Et l is echo data that was not selected by the echo/color determination circuit 9 as the data of the pixel 2o. Then, the echo interpolation circuit 12
Similarly to the figure, as each interpolated data I, I2, ... lN-1 between both pixels 20 and 21, Et, Ex...
・Create l EN-1.

Each interpolation data created by the echo interpolation circuit 12 and the color interpolation circuit 13 is sent to the echo/color determination circuit 1.
4.15 entered. Each echo/color judgment circuit 14
．． 15 according to preset selection conditions,
Either C or E is selected as interpolation data I. That is, C1 or E as interpolated data It,
Further, Ct or E2 is sequentially selected as interpolated data r2. In this case, the echo/color determination circuit 15 selects C more often as the interpolation data (2) than the echo/color determination circuit 14 does.

The outputs of the echo/color determination circuits 14 and 15 are input to a selection circuit 17. The selection circuit 17 selects and outputs one of the outputs of the echo/color determination circuits 14 and 15 according to the operator's selection. The output of the selection circuit 17 is input to the display signal synthesis circuit 11. The output of the display signal synthesis circuit 11 is output from the display signal generation circuit 5.
The input signal is input to the 0 display symbol generating circuit 5, which processes the input signal into a signal that can be displayed on the CRT of the display device 6, and outputs a display signal. The display 6 receives this display signal and displays echo information and color information on the CRT.

For example, when diagnosing a narrow blood flow, the output of the echo/color determination circuit 15 passes through the selection circuit 17 by switching the selection circuit 17 to the echo/color determination circuit 15 side according to the operator's selection.

Since the echo/color determination circuit 15 outputs many colors as described above, the narrow blood flow portion, which is a color area, is displayed in a wider area on the CRT of the display 6. This makes it possible to easily find thin blood flows that are difficult to find with conventional devices. Furthermore, when the echo/color determination circuit 15 is selected, the blood flow portion is displayed wider than it actually is.

After discovering a thin blood flow, or when there is no need to discover it, switching to the echo/color determination circuit 14 side results in a display similar to the conventional one.

[Other Embodiments] In the above embodiments, the operator selects either the echo/color determination circuit 14 or the circuit 5 by switching the selection circuit 16. Application is not limited to this.

For example, the echo/color determination circuit 15 and the selection circuit 1
7 may be omitted. In this case, if the data on adjacent scanning lines is color and echo,
The echo/color determination circuit I4 outputs only color as interpolated data. Even in this case, the same effects as in the embodiment described above can be achieved.

〔Effect of the invention〕

According to the ultrasonic diagnostic apparatus according to the present invention, since a selection circuit is provided that preferentially selects the output from the color interpolation circuit, narrow blood flow can be easily discovered.

[Brief explanation of the drawing]

FIG. 1 is a schematic block diagram of an interpolation and echo/color determination circuit that constitutes an ultrasonic diagnostic apparatus according to an embodiment of the present invention, and FIG. 2 is a schematic block diagram of a display signal generation circuit that constitutes the apparatus of the embodiment. , FIG. 3 is a schematic block diagram of the apparatus of the embodiment, and FIGS. 4, 5, 6, 7A, and 7B are diagrams showing an example of generation of interpolation data. 5...Display signal generation circuit, 10...Interpolation and echo/color determination circuit, 12...Echo interpolation circuit, 13.
...Color interpolation circuit, 9,14.15...Echo/color judgment circuit. Figure 4 5EI

Claims (1)

[Claims] (1) In an ultrasound diagnostic device that combines and displays color data obtained from blood flow information with echo data obtained from tomographic information, each pixel on an ultrasound scanning line displays either echo data or color data. an echo interpolation circuit and a color interpolation circuit that create echo data and color data to be interpolated between ultrasound scanning lines; When it is determined that echo data is displayed on one side and color data is displayed on the other side, the output from the color interpolation circuit is given priority over the output from the echo interpolation circuit as the interpolation data. An ultrasonic diagnostic device comprising: an interpolation data selection circuit; and an interpolation data selection circuit.