JPH0221261B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an improvement in the display mechanism of an ultrasonic tomography apparatus having a digital scan converter and a television monitor.

Currently, in ultrasonic tomography devices, post-processing is used to clarify the differences in tissue of the lesion in the recorded and displayed ultrasound images, but the results show that it is still clinically effective. has not been obtained. In addition, in order to detect the difference between images with and without post-processing processing, or between two images that have undergone different post-processing processing, it is necessary to use at least two recorded photographs. Can't compare.
In addition, in the case of a television display that is not a documentary photograph,
The screen on which post-processing processing such as γ correction was performed was displayed in a single display, and the screen on which no processing processing was performed was not displayed on the same screen at the same time, making comparison impossible.

The present invention has been made to solve these problems, and its purpose is to provide an ultrasonic tomography system that improves the efficiency of diagnosis by making it easier to simultaneously compare images that have undergone different processing. The goal is to provide equipment.

Another object of the present invention is to provide an ultrasonic tomography apparatus that can carry out a wide variety of processing operations.

Another object of the present invention is to provide an ultrasonic tomography apparatus in which means for achieving the above object are extremely simply configured.

The present invention will be described in detail below along with examples.

FIG. 1 is a diagram showing a general configuration of the present invention,
1 is an ultrasonic probe, 2 is an ultrasonic transmitting/receiving section, 3 is a digital scan converter section, and 4 is a display device such as a television monitor.

FIG. 2 is a diagram showing a specific configuration of the digital scan converter section of FIG. 1. In the diagram, 3
01 is an analog-to-digital converter that converts the video signal from the ultrasonic transmitter/receiver 2 into a digital signal;
302 is a writing sampling buffer memory, the output signal of which is stored in the image memory through a serial/parallel converter 303A. Writing sampling buffer memory 30
2 operates at a timing synchronized with the transmission and reception of ultrasonic waves. The readout signal from the image memory and the parallel/serial converter 303B operate at a timing synchronized with the scanning synchronization signal of the display device 4 such as a television monitor. 3
03A is serial/parallel converter, 303
B is a parallel-serial converter, 304 is an image memory, 305 is an image memory control circuit, 306
307 is a timing control circuit, 307 is a changeover switch for selecting whether to use the first post-processing image or the second post-processing image, 308A is a first post-processing circuit that performs γ correction, etc., and 308B is a first post-processing processing circuit. 2 post-processing processing circuits, 309 is a mixer, and 310 is a digital-to-analog converter.

Next, the operation of this embodiment will be explained.

1 and 2, ultrasonic waves emitted from an ultrasonic probe 1 are reflected by a subject, and the reflected ultrasonic waves are received by an ultrasonic transmission/reception signal 2 and output as a video signal. This video signal is converted into a digital signal by an analog-to-digital converter 301, passes through a writing sampling buffer memory 302, and is input to a serial-to-parallel converter 303A. The output of this serial/parallel converter 303A is written to the image memory 304 at a predetermined timing. When reading out the contents stored in the image memory 304, the number of Y scanning lines corresponding to half of the display screen of the display device 4 such as a television monitor is calculated, and when this predetermined number is reached, the first post-processing is performed. Switching from the processing circuit 308A side to the second post-processing processing circuit 308B side, serial/parallel converter 303A, parallel/serial converter 3
03B at a predetermined sampling timing. In this way, the read content data of the image memory 304 is sequentially converted into image data subjected to first post-processing processing, for example, _γ1 correction, and sent to the mixer 309, where it is digitally converted.
The signal is converted into an analog signal by an analog converter 310, and the _γ1 corrected image is displayed on the left half of the screen of the display device 4, such as a television monitor, as shown in FIG. Similarly, when switching to the second post-processing processing circuit 308B side, the contents stored in the image memory 304 are read out at a predetermined sampling timing through the parallel-to-serial converter 303B, and displayed on a display device such as a television monitor. The data on the right half of the screen of 4 is subjected to a second post-processing process, _e.g.
The data is sequentially converted into corrected image data and sent to the mixer 3.
09, and the digital-to-analog converter 310
As shown in FIG. 3, the γ ₂ corrected image is displayed on the right half of the screen of a display device 4 such as a television monitor.

Note that when an image is not subjected to post-processing processing, the first or second post-processing processing circuit may be configured as a short-circuit circuit.

It is also possible to divide the same display screen into three or more parts and display different post-processed images on each part. The same can be said of preprocessing processing in which images are switched to the left and right before being written into the image memory.

As explained above, according to the present invention, an ultrasound probe detects a reflected echo signal from a subject, and image data from the ultrasound probe is stored in an image memory. Image data obtained by subjecting the contents to different post-processing processes are displayed simultaneously on the same screen. Therefore, images that have undergone different processing processes can be compared simultaneously on the same screen. Therefore, each processed image can be compared simultaneously, and the efficiency of diagnosis can be improved.

Further, according to the present invention, image data obtained by an ultrasound probe is sequentially stored in an image memory, one screen worth of data is captured, and processing processing is performed based on this image data. In order to obtain images of the same object that have undergone different processing, one possible method is to carry out the processing by converting the transmission signal input to the ultrasound probe. , compared to this method, a much wider range of types of processing can be performed. In other words, it is quite conceivable that the range of conversion processing methods (only a few types of processing can be performed) will be limited in the conversion processing of the transmission signal input to the ultrasound probe due to the relationship with the subject. Since performing processing based on the image data stored in the image memory is only a problem in image processing, it can be said that there are almost no restrictions on the processing direction.

Furthermore, in the present invention, the image data from the ultrasound probe is stored in the memory and is immediately displayed after being subjected to post-processing processing.
Only one memory is required. This means that, for example, when post-processing image data from an ultrasound probe, the memory device can be reduced compared to the number of circuits required for post-processing. The configuration can be made extremely simple.

[Brief explanation of drawings]

FIG. 1 is a diagram showing a general configuration of an embodiment of the present invention, FIG. 2 is a diagram showing a specific configuration of the digital scan converter section of FIG. 1, and FIG. FIG. 2 is a diagram showing a screen of a display device such as a television monitor. 1... Ultrasonic probe, 2... Ultrasonic transmitter/receiver,
3...Digital scan converter section, 4...
Display device, 301...Analog-to-digital converter, 302...Sampling buffer memory for writing, 303A...Serial/parallel converter, 303B...Parallel/serial converter, 304...Image memory, 305...Image memory control circuit , 306...timing control circuit, 3
07...Switchover switch, 308A...First post-processing circuit, 308B...Second post-processing circuit, 309...Mixer, 31
0...Digital-to-analog converter.

Claims (1)

[Claims] 1 An ultrasonic probe that detects reflected echo signals from a subject, an image memory that sequentially stores and captures image data from this ultrasonic probe for one screen, and reads image data from this image memory. an ultrasonic tomography apparatus comprising: a display means for displaying image data stored in the image memory; 1. An ultrasonic tomography apparatus comprising display means for simultaneously displaying each image data on the same screen.