JPS59121461A - (n+1)-dimensional picture processing device - Google Patents

Abstract

PURPOSE:To prevent a picture from moving by providing a one-dimensional filtering part for executing a one-dimensional filter processing, and an n-dimensional filtering part for executing an n-dimentional filter processing, and executing jointly the one-dimensional and n-dimensional digital filterings. CONSTITUTION:A picture data inputted to an n-dimensional data input part 1 is read out to an n-dimensional data sequence storage part 8 under the control of a control part 6, and stored successively in plural memories of this storage part 8. An output of this storage part 8 is provided to a one-dimensional filtering part 3 by the control part 6, brought to one-dimensional filtering processing, and its output is provided to an n-dimensional filtering part 9. An n-dimensional filtering processing is executed by this filtering part 9, and its processed output is provided to an n-dimensional data output part 5. In this state, one-dimensional and n-dimensional digital filtering processings are executed in the sequence direction, by which generation of an artifact in a picture caused by a motion, etc. of a patient is prevented, and a distinct picture is outputted.

Description

Detailed Description of the Invention [Technical Field of the Invention] The present invention relates to a digital radiography device, a digital fluorography device, an NMR-CT rack nuclear medicine imaging device, an X-ray CT device, an ultrasound image cutting device, etc. The present invention relates to a (1+1)-dimensional image processing device that processes a (1)-dimensional image obtained from a 2-dimensional image.

[Technical background of the invention and its problems]

In recent years, for example, in a digital radiography device or a digital fluorography device C2, after injecting a contrast medium into an artery or vein, a mask image is taken from X-ray f2, and then a mask image is taken when the contrast medium reaches the affected area. , X again
Radiography (2 contrast images are taken, and the difference between the contrast image and the mask image is taken (2 subtraction images are obtained, and the blue blood vessel image is emphasized in the area where the contrast agent has arrived. like 17
In subtraction processing between images, the person does not move at all,
Further, only when the affected area does not move at all, the blue area canal image can be favorably enhanced.

However, in reality, during X-ray photography, there are body movements of the patient, and there are periodic movements in the body of the patient, such as the heart and lungs.1. It is difficult to achieve absolute immobility inside and outside the body of a person. therefore,
In the subtraction image obtained by simple subtraction processing C2, artifacts may appear,
In practical terms, this is not necessarily satisfactory.

[Purpose of the invention]

This invention has been made in view of the above-mentioned circumstances, and is capable of preventing the occurrence of artifacts in images due to body movements and internal organs movements of the bereaved person, and clearly displaying a desired emphasized image. It is an object of the present invention to provide an (rL+1)-dimensional image processing device that can significantly improve the diagnostic ability of doctors and the like.

[Summary of the invention]

The outline of the present invention for achieving the above object is to process a plurality of two-dimensional digital images C that change temporally or spatially in a series of sequences, and perform image processing that performs digital filtering processing (in the second case, one-dimensional digital images C). It has a one-dimensional filtering section that performs filter processing and a two-dimensional filtering section that performs two-dimensional filter processing, and has a sequence direction of 3:1.
This method is characterized by performing two-dimensional digital filtering and also performing two-dimensional digital filtering.

[Embodiments of the invention]

An embodiment of the invention will be described with reference to the drawings.

As shown in FIG.
, a one-dimensional filtering section 6 , a two-dimensional filtering section 4 , an image output section 5 , a control section 6 , and an operation console 7 .

The image input unit 1 sequentially inputs digital image data (hereinafter referred to as single C2 image data) for a plurality of images that are economically outputted from a digital radiography device or the like, and The sequence image storage unit 2 outputs image data to the sequence image storage unit 2 in response to the control command (2) from the control unit 6.
It has a plurality of memories 21, 22, and 23, and stores image data for a plurality of images outputted over time from the image input unit 1 for each of the plurality of memories 21, 22, and 23+2 images, After all the dihedral image data in the plurality of memories 21, 22.23 are stored, each memory 21.22
．． 23 simultaneously outputs C dihedral image data for each pixel to the one-dimensional filtering device 6.

Note that multiple images output over time are:
The analogy is 1. A contrast medium is injected into the collapsing canal of a delinquent person, and after the contrast medium reaches the imperial capital, C' is taken at regular intervals. refers to an image of

As shown in FIG.
coefficients of the dimensional digital filter and the plurality of memories 21,
22. The plurality of notes to be multiplied with the image data read from 23! It has a plurality of multipliers 31, 32, and 33 corresponding to each of J21.22.23, and an adder 64 that adds the multiplication results output from the plurality of multipliers 31, 32, and 35 for each pixel. In the sequence image storage unit 2 (2), the frequency characteristics are corrected based on each pixel and C dihedral image data for each stored plural images, and the corrected image data is sent to the two-dimensional filtering unit 4C. As the one-dimensional digital filter, a differential filter, a bypass filter, a Hilbert transform filter, etc. can be used, and the temporal change of image data can be extracted from these one-dimensional digital filters≦2. .

As shown in FIG. 2, the two-dimensional filtering section 4 includes C2,
A first memory 41 that stores image data output from the one-dimensional filtering section 6, and a two-dimensional digital filter 4 that performs filter processing on the image data read out from the first memory 41, such as a two-dimensional differential filter,
It has a bypass filter, a bandpass filter, a Hilbert transform filter, etc., and a second memory 46 for storing the image data after filter processing, and inputs the image data whose temporal change has been extracted by the one-dimensional filtering section 6,
The spatial variation of the image data is suppressed.

The image output section 5 is, for example, a CRT monitor that inputs the image data with spatial variations suppressed by the two-dimensional filtering section 4 and displays the image.

The control section 6 controls the operations of the respective sections in accordance with various commands input from the operation console 7.

Next, in C2, the operation of the above configuration will be described.

For example, output from a digital radiography device,
Image data of the affected area C after the contrast agent has arrived is stored in a plurality of memories 21, 22, and 23 in the sequence image storage unit 2 via the image input unit 1. The storage procedure is as follows. That is, the image data for the first image at time t1+2 is stored in the first memory 21+2, and then the image data for the second image at time t2 (both image data are stored in the first memory 21). (2nd 1st
The image data stored in the second memory 21 is transferred to the second memory 22 and stored therein. Thereafter, in the same way, the time tr
Image data for the 1 images up to the 1st image in L, from the 1st to the 1st memo for each image!
Stored in J21.22.23. Next, the image data stored in the first to second memories 21, 22, and 23 are simultaneously read out pixel by pixel, and the one-dimensional filtering unit 6 (two people) reads out the image data stored in the first to second memories 21, 22, and 23 simultaneously.

In the one-dimensional filtering section 3, multipliers 31.3
2, 53, for each image, multiply the input pixel data by the coefficient of the one-dimensional digital filter.C2, extract the time change, and then add the multiplication result by the adder 34. , are added for each pixel at the same position between the images, and the image data of one image after the addition is outputted to the pixel (22-dimensional filtering unit 4).

In the two-thorn filtering section 4, the input image data is first stored in the first memory 41, and then the image data is read out, and a two-dimensional digital filter 42 performs a filtering process to suppress the variation between nine intervals. The processed image data is stored in the second memory 43C. The image data stored in the second memory 46 is read out, and a dihedral image of the screen C of the image output section 5 is displayed.

The image on the screen of the image output section 5 is processed by a one-dimensional filtering section 3 to extract temporal changes, and a two-dimensional filtering section 4
Since spatial changes are suppressed, there are no artifacts caused by slight movement of the patient or movement of internal organs during X-ray imaging, and the image can be displayed as a collapsing contrast image without using a mask image. .

As mentioned above, one embodiment of this invention has been described in detail, but this invention is not limited to the above-mentioned embodiment C2, and can be practiced with appropriate modifications within the scope of the gist of the invention. Needless to say.

In the above embodiment (2), the image data obtained by the two image input units C was data obtained from the digital radiography device C2, but in addition, C2, the digital fluorography device, the NMR-CT device, Data obtained from C2, such as a nuclear medicine image diagnostic device and an ultrasound diagnostic device, may also be used.

In addition, multiple images output over time are not limited to images of the same affected area over time, as in the above embodiment, but are multiple images obtained by slicing in parallel along the body axis C2 of the patient. It may also be an X-ray tomographic image.

As a second embodiment, as shown in FIG.
The first embodiment C shown in FIG.
In place of the two-dimensional filtering unit 4 in the first embodiment (instead of the two-dimensional filtering unit 4), a one-dimensional filtering unit 6 may be connected.

In addition, as a third embodiment, as shown in FIG.
IC2, instead of the sequence image storage unit 2 in the first embodiment C2 shown in FIG.
The second embodiment uses a two-dimensional data sequence storage unit that stores ≦2 images (two-dimensional ii!Ll image data) for each image, and a two-dimensional filtering unit in the first embodiment C: In place of C6, a C2-dimensional filtering unit 9 may be used.

[Effect of invention]

According to this invention, it is possible to display an image that temporally and spatially emphasizes or suppresses parts that are moving spatially and temporally within the patient's body, so during image diagnosis,
It is possible to provide an image processing device that can reduce the mental and physical burden imposed on patients (2) and further contribute to improving the diagnostic ability of doctors, etc.

For example, according to this invention≦2, without using a mask image as in the digital radiography apparatus C2,
The input image data C is equipped with a one-dimensional filtering section, and performs one-dimensional differential filtering, bypass filtering, bandpass filtering, or Hilbert transform filtering on the time axis (from the second point, the time change component In addition, in the two-dimensional filtering section, 2
By performing dimensional low-pass filter processing, etc., spatial changes are suppressed and spatial noise, artifacts, etc. are removed. Moreover, it can be displayed as an accurate image.

In addition, regarding image data from ultrasound diagnostic equipment, 1
The dimensional filtering section performs one-dimensional differential filter processing,
By performing bypass filter processing, band pass filter processing, low pass filter processing, Hilbert transform filter processing, etc., time-varying components are extracted, and the two-dimensional filtering section extracts two-dimensional differential filter processing, bypass filter processing, band By performing pass filter processing or Hilbert transform filter processing,
By emphasizing spatial changes, for example, it is possible to display an image with clear movements and contours for a moving mitral valve, myocardium, etc.

[Brief explanation of the drawing]

Figures 1 and 2 are block diagrams showing a first embodiment of this invention, Figure 3 is a block diagram showing a second embodiment of this invention, and Figure C: $4 is a block diagram showing a second embodiment of this invention. It is a block diagram showing an example of. 2... Sequence image storage unit, 6... One-dimensional filtering unit, 4... Two-dimensional filtering unit, 8... Le-dimensional data sequence image storage unit, 9.
...Le-dimensional filtering section.

Claims (1)

[Scope of Claims] A one-dimensional filtering section that performs processing and a path-dimensional filtering section that performs linear filter processing, performs sequence direction≦21-dimensional digital filtering, and is a linear \\\X device. (2) One-dimensional filtering section has one or more one-dimensional digital filters selected from the group consisting of one-dimensional differential filters, bypass filters, band-pass filters, and Hilbert transform filters, and n-dimensional digital images ≦ two temporal changes. The n-dimensional filtering unit extracts the n-dimensional Digital image ≦ two sky sky ~) ＼
~ Ruler device. (3) The one-dimensional filtering section has one or more one-dimensional digital filters selected from the group consisting of a one-dimensional differential filter, a bi-pulse filter, a band-pass filter, and a Hilbert transform filter. The two-dimensional filtering unit has a two-dimensional low-pass filter to suppress the spatial variation in the digital image, and eliminates spatial noise.
It is characterized by removing artifacts etc. (4)
) The one-dimensional filtering section has a one-dimensional low-pass filter to suppress the two-dimensional digital image (two-dimensional, temporal rhombic component and remove noise, and the one-dimensional filtering section has a two-dimensional differential filter, a bypass filter, (5) One-dimensional filtering that emphasizes the variation between two walls of the two-dimensional digital image C using one or more two-dimensional digital filters selected from the group consisting of a bandpass filter and a Hilbert transform filter. The IL-order filter section has a one-dimensional low-pass filter to suppress temporal changes and noise removal for the two-dimensional digital image, and the IL-order filter section has a two-dimensional low-pass filter to suppress spatial changes for the two-dimensional digital image. A device that suppresses changes and removes spatial noise and artifacts. (6) Two-dimensional digital images are used in medical digital radiography, X-ray CT, NMR-CT, nuclear medicine imaging equipment, ultrasound imaging equipment, and cineangiography. The image data is output from a medical imaging device selected from the group consisting of: