JPH087390B2 - Radiation image processing method - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a radiation image processing method suitable for use in a radiation image reproducing system or the like in medical diagnosis, and more specifically, scanning a recording medium for radiation images. Due to
The present invention relates to a radiation image processing method for reading an image recorded on a recording medium and obtaining a reproduced image from the read information.

(Prior Art) Conventionally, an X-ray image is affected by an X-ray tube, an X-ray power source, a variation depending on a lot of film, a change in a developing condition, and the like, and thus the image itself is poor in absolute quantitativeness.
Further, in order to make the finish constant, it was necessary to finely adjust various devices.

On the other hand, in recent years, a radiation image of a subject is recorded on a radiation image storage medium other than film, and the image is read out from this storage medium. Radiation image storage media other than films include, for example, those utilizing a thermostimulable phosphor layer or those utilizing a layer having a PIP effect.
In the former case, the thermostimulable phosphor layer absorbs the radiation that has passed through the subject, accumulates radiation energy corresponding to the intensity of the radiation, and heats it during image reading or excites electromagnetic radiation as excitation energy. Or use as
Taking out the accumulated radiant energy as a light signal,
A radiation image can be obtained by the intensity of this light. When the latter layer having the PIP effect is used,
It is designed to reproduce the image recorded in the PIP layer by irradiating the radiation that has passed through the subject and detecting the induced charges generated in the electrodes by the persistent internal polarization by scanning with a flying spot scanner. .

However, it is hard to say that these signals, like the film, have a quantitative property in the read signal itself due to changes with time of the X-ray source and the image reading unit.

(Object of the Invention) The present invention has been made in view of the above circumstances, and an object thereof is to correct the change with time of a radiation source, the change of a radiation storage medium, an image detection system, and a system for converting into an electric signal. The object of the present invention is to provide a method for rendering a reproduced image to a constant finish, and further a method for providing a quantitative image.

(Structure of the Invention) The present invention that achieves such an object is to store a substance having a known thickness and a radiation image of a subject in a radiation image storage medium and scan the storage medium to scan the radiation in the storage medium. After reading the image and converting it to an image signal, the image signal obtained by scanning the radiation image of the substance of known thickness, the image signal obtained by scanning the radiation image of the subject is corrected, A radiation image processing method characterized by giving quantitativeness to the read radiation image information of a subject, and a radiation image of a subject stored in a radiation image storage medium, and obtained by reading the radiation image. A radiographic image information and a radiographic image information obtained by newly storing the radiographic image after obtaining the radiographic image information and reading the radiographic image are provided with quantitativeness. A radiation image processing method, wherein a radiation image storage medium stores a radiation image including both a portion where a subject is absent and a portion where a subject is present, and the radiation medium in the storage medium is scanned by scanning the storage medium. An object obtained by scanning the radiation image of the subject with an image signal corresponding to the irradiation dose obtained by scanning the radiation image of the portion where the subject does not exist after reading and converting the image signal The radiation image processing method is characterized in that the image signal corresponding to the amount of radiation transmitted through is corrected so that the radiation image information of the subject is given quantitativeness.

(Example) Hereinafter, a circuit for carrying out the method of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a circuit configuration diagram for carrying out the method of the present invention. In the figure, reference numeral 1 is a radiation image storage medium, for example, a stimulable phosphor, and 2 is a deflection optical system activated by a control circuit 3. The deflection optical system 2 is for scanning (main scanning) the storage medium 1 with a light beam emitted from a light source 4 (for example, an Ar laser) and having its light amount adjusted by a light amount adjuster 5 in the Y-axis direction. is there. The storage medium 1 is scanned (sub-scanned) in the X-axis direction by the control circuit 3.
Therefore, the storage medium 1 can be formed by the main scanning and the sub-scanning described above
The surface of will be scanned in two dimensions. The light energy emitted from the surface of the storage medium 1 by the irradiation of the light beam is guided to a photomultiplier (photomultiplier tube) 6 through an optical fiber or the like, converted into an electric signal, and output. Ten
Is a data conversion device for converting this electric signal (image signal) into a thickness conversion value, and 20 is for obtaining corrected data from a radiation image obtained without using a wedge as described later. It is a data conversion device.

In the data conversion device 10, 11 is an amplifier that amplifies the output of the photomultiplier 6 and uses the light amount adjuster 5 and the A / D converter 1
It outputs to 2. A storage device 13 stores a conversion table, that is, a correspondence table of wedge thickness and density value. This conversion table is rewritten for each image scanning, and the wedge thickness is written therein using the density value obtained when the wedge portion is scanned as an address (FIG. 2). The wedge thickness is known in advance corresponding to the scanning position of the beam, and each wedge thickness is given by the control circuit 3 in connection with the scanning. In addition to aluminum, copper, plastic, 3Ca ₃ (PO ₄ ) ₂ , methyl acrylate, etc. can be selectively used as the wedge. Further, the cross-sectional shape is preferably wedge-shaped in order to obtain many relations between the wedge thickness and the image signal (it is necessary to arrange so that the thickness changes in the main scanning direction).

In the data converter 20, 21 is an amplifier for amplifying the output of the photomultiplier 6, 22 is a holding circuit for holding the output of the amplifier 21, 23 is a logarithmic amplifier for logarithmically compressing the output of the amplifier 21,
24 is a logarithmic amplifier for logarithmically compressing the output of the holding circuit 22, 25 is an adder for adding the outputs of the logarithmic amplifiers 23 and 24, and 26 is an A / D.
It is a converter.

Next, through the operation of the circuit in such a configuration,
The method of the present invention will be specifically described. An example of the radiation image in the storage medium 1 is as shown in FIG. Here, the case of beam scanning is described. In this case, in the output of Photomul 6 obtained through amplifier 11,
A signal obtained only when scanning a portion without a subject acts on the light quantity adjuster 5 to automatically adjust the scanning laser beam to a predetermined light quantity. The light amount is not adjusted while scanning the subject portion. When approaching the scanning of the wedge portion 1a, the density value of the wedge image obtained via the amplifier 11 and the A / D converter 12 is given to the storage device 13 as an address,
The wedge thickness at that time (this is given from the control circuit 3) is written. By scanning the wedge portion 1a, a correspondence table (FIG. 2) between the density value and the wedge thickness is created in the storage device 13. Then, the subject image portion 1c
At the time of scanning, the output (density value) of the A / D converter 12 is led to a conversion table as an address, and the conversion table gives image data converted into the equivalent thickness of the wedge, which is generated at the time of image capturing. It is possible to obtain quantitative image data that is completely unaffected by the fluctuation of the device. The equivalent thickness means, for example, when the human body is replaced with a substance other than the human body, for example, aluminum, what is the thickness of the aluminum and the read image signals are equal to each other. Therefore, as a result of converting (correcting) the radiation image into such a thickness-converted value and processing it, the change over time of the radiation source that is simultaneously received by the subject (human body) and the substance (wedge) arranged in parallel with the subject, It is possible to obtain an absolutely quantitative reproduced image (of course, an image with a fixed finish) from which various other effects are completely removed.

A case of performing conversion to an equivalent thickness without using a wedge, that is, conversion to an equivalent thickness when the wedge portion 1a is not recorded as a radiation image will be described below. For this case, the circuit shown in FIG.
Has 20. It is well known that the transmission attenuation of radiation decreases exponentially with respect to the thickness of the subject. Therefore, in the data conversion device 20, the image density signal obtained when the non-subjected portion 1b of the image shown in FIG. 3 is scanned is stored in the holding circuit 22 via the amplifier 21. When scanning the subject image portion 1c of FIG. 3,
A signal −log I obtained by logarithmically compressing the image I is obtained from the logarithmic amplifier 23, and the adder 25 adds the output I ₀ of the holding circuit 22 to the log I ₀ converted by the logarithmic amplifier 24. This makes lo
A signal of g I ₀ −log I is obtained and taken out as a digital signal via the A / D converter 26. By performing such a conversion, the conversion to the equivalent thickness is similarly performed.

The data conversion device 20 may be configured as shown in FIG. That is, immediately after the output of the amplifier 21 is A / D converted, the signal I _{0 of the} part 1b without a subject is held in the holding register 42, and the logarithmic converter 43 holds the signal I of the subject image part 1c and the holding register 42. Received, converted as appropriate, lo
A signal of g I ₀ −log I may be obtained. Further, although the same storage medium has been described in which the substance of known thickness and the radiation image of the subject are recorded, the present invention is not limited to this.

As described above, according to the present invention, a radiation image is read with an equivalent thickness conversion value, and the image is reproduced using this image signal, so that a subject image with a constant finish and constant quantification is always obtained. Obtainable.

[Brief description of drawings]

FIG. 1 is a block diagram showing an example of a circuit for carrying out the method of the present invention, FIG. 2 is an explanatory diagram of contents of a conversion table, FIG. 3 is an explanatory diagram showing an example of a radiation image, and FIG. It is a circuit diagram which shows the other Example of a data converter. 1 ... Radiation image storage medium, 2 ... Deflection optical system 3 ... Control circuit, 4 ... Light source 10, 20 ... Data converter 11, 21 ... Amplifier 12, 26, 41 ... A / D converter 13 ... Memory device, 22 ... Holding circuit 23, 24 ... Logarithmic amplifier, 25 ... Adder

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Junko Okanoya 1 Sakura-cho, Hino-shi, Tokyo Photo by Konishi Roku Photo Co., Ltd. Judging body for referee, Tomoyuki Nakamura Judge, Akira Maruyama Kazuhiro Kosuge (56) Reference Reference JP-A-55-88740 (JP, A) JP-A-57-152268 (JP, A) JP-B-45-13264 (JP, B1)

Claims (7)

[Claims] 1. A radiation image storage medium stores a substance of known thickness and a radiation image of a subject, scans the storage medium to read out the radiation image in the storage medium, and converts it into an image signal. With the image signal obtained by scanning the radiation image of the substance of known thickness, the image signal obtained by scanning the radiation image of the subject is corrected, and the read radiation image information of the subject has a quantitative property. A radiation image processing method, wherein the radiation image processing method is provided. 2. The radiation image processing method according to claim 1, wherein a substance having a known thickness and a radiation image of a subject are stored in the same radiation image storage medium. 3. The correction is performed by previously obtaining a relation between an image signal obtained by scanning the substance having a known thickness and the thickness of the substance, and obtaining the radiation image of the object by scanning the relation. The radiation image processing method according to any one of claims 1 and 2, wherein the obtained image signal is converted into an equivalent thickness of the substance. 4. An image obtained by scanning a radiation image of the object, in which a relationship between an image signal obtained by scanning the substance having a known thickness and the thickness of the substance is created in advance, Access the correspondence table using the signal as an address,
The radiation image processing method according to claim 3, wherein the thickness data stored in the correspondence table is set to an equivalent thickness of the radiation image of the subject. 5. The radiation image processing method according to claim 3, wherein the cross-sectional shape of the substance is wedge-shaped. 6. The material of the substance is aluminum,
6. The radiation image processing method according to claim 1, wherein at least one of copper, plastic, 3Ca ₃ (PO ₄ ) ₂ and methyl acrylate is selectively used. 7. A radiation image of a subject is stored in a radiation image storage medium, and radiation image information obtained by reading the radiation image, and a radiation image newly stored after the radiation image information is obtained, A radiographic image processing method for providing quantitativeness with radiographic image information obtained by reading out the radiographic image, wherein both a portion where a subject does not exist and a portion where the subject exists in the radiation image storage medium And the radiographic image including
After the radiation image in the storage medium is read by scanning the storage medium and converted into an image signal, the image signal corresponding to the irradiation dose obtained by scanning the radiation image of the portion where the subject does not exist, Radiation characterized in that the radiation image information of the subject is quantified by correcting an image signal obtained by scanning the radiation image of the subject and corresponding to the amount of radiation transmitted through the subject. Image processing method.