JPS6148144B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a radiation image recording method using a stimulable phosphor material. (hereinafter referred to as "instantaneous light emission"),
The present invention relates to a radiation image recording method in which characteristics of an image to be recorded are determined in advance and operations are performed at the stage of reading out stored images based on the characteristics.

When a stimulable phosphor is applied to record radiation images, for example, as in the method disclosed in U.S. Pat. In cases where the previously accumulated image is read out by exciting it with heat rays or visible light such as laser light, and this is recorded on a photographic material, the final image can be observed in the most effective way for the viewer. It is desirable to output it in a format that is easy to read.

In order to obtain such an output, the image stored in the stimulable phosphor is excited by a laser beam, etc., and read out.
Convert this into an electrical signal, find the maximum value, minimum value, average value, etc. from this electrical signal, and use these values to determine the characteristics of the image, such as whether the image is low-key or high-key, and whether the contrast is high or low. It is conceivable to conduct an analysis of

However, in order to analyze an image using this method and output and record it on a photosensitive material, it is necessary to temporarily store all the data of a single read image before performing the image analysis described above. There is,
For this purpose, a large capacity storage device is essential.
For example, the capacity of the storage device is 50 for 30cm square images.
Assuming that we measure with a μ-angle aperture,
It is necessary to be able to store a huge amount of data, 3.6×10 ⁷ pieces, which results in a significant increase in the cost of the device.

Furthermore, in this case, since the image is reproduced (output) after reading out this huge amount of data and then analyzing the image characteristics, there is a drawback that there is a considerable time delay before image formation.

As a result of intensive research aimed at resolving this issue, the inventors of the present invention discovered that the stimulable phosphor stores a part of the absorbed radiation energy while at the same time transmitting the other part to the non-storable light (the above-mentioned "instantaneous luminous light"). '') and that the amount of this instantaneous emitted light is exactly proportional to the amount of stored energy. By detecting this instantaneous emitted light, the present invention is completed in which, during radiation irradiation, the radiation image is accumulated and recorded in the stimulable phosphor and at the same time information regarding the characteristics of the image is obtained from this instantaneous emitted light. This is what led to this.

The present invention is a radiation image recording method using a stimulable phosphor, in which a radiation image is accumulated and recorded in the stimulable phosphor during radiation irradiation by detecting the instantaneous light emitted by the stimulable phosphor during radiation irradiation, etc. At the same time, information regarding the characteristics of this image is obtained from the above-mentioned image analysis using the instantaneous emitted light, and this information is applied in the subsequent step of reading out the accumulated image from the stimulable phosphor. There is no need to store the entire image information in the storage device or wait until the entire image has been read out.
By applying a transformation to this signal, it is possible to obtain a desired image without delay from readout.

In the present invention, a storage phosphor refers to a phosphor that is irradiated with optical, thermal, mechanical, chemical, or electrical energy after being irradiated with the first radiation (X-rays, α-rays, β-rays, γ-rays, ultraviolet rays, etc.). A phosphor that exhibits so-called photostimulability, which, when stimulated by a target, re-emits light corresponding to the initial dose of radiation.

A photodetector for receiving the instantaneous light emitted by the stimulable phosphor is arranged to obtain information of a certain range of the image. For example, photodetectors are arranged in a matrix to detect the light emitted from each part of the stimulable phosphor. In this case, the number of photodetectors may be significantly smaller than in the case of the device for reading out the image described above, and the number of photodetectors is sufficient to detect the characteristics of the image (e.g., one photodetector per 1 cm ² to 25 cm ² of image area). ) is fine.

Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

FIG. 1 is a block diagram showing a part of an X-ray image recording apparatus which is an embodiment of the present invention. X-ray source 1
X-rays emitted from the object to be examined, for example, the human body 11
is irradiated. The X-rays that have passed through the human body 11
incident on . This phosphor plate 12 is coated with a stimulable phosphor such as {ZnS (0.8), CdS (0.2)}:
Ag, {BaO:SiO ₂ }, BaFBr:Eu, BaFCl:Eu, etc. are layered together with a binder. Since the storage phosphor stores a part of the energy of the incident X-rays, an X-ray transmission image of the human body is recorded on the phosphor plate 12. At the same time, photodetectors 13a, 13b, ......13 arranged behind the phosphor plate 12
The instantaneous light emitted by the stimulable phosphor is detected by n. As the photodetector 13, a photomultiplier tube, a silicon detector, a solar cell, etc. can be used in a two-dimensional arrangement.

The outputs of the photodetectors 13a, 13b...13n are amplified by an amplifier 14 and then sent to a maximum/minimum value discriminator 15, where the maximum,
The minimum brightness is discriminated. As mentioned above, the amount of instantaneous light emitted is exactly proportional to the amount of energy stored in the stimulable phosphor, so the maximum and minimum values of the instantaneous light emitted above are determined by predetermined conditions (type of phosphor, It is possible to automatically convert the energy storage amount into the maximum value and minimum value according to the structure of the reading device, etc.). This conversion operation is performed by conversion means 16 and the result is stored by storage means 17.

Recorded information is read out from the phosphor plate 12 on which images are stored and recorded using a laser beam.
This process is shown as a block diagram in FIG. As for the laser light, in order to prevent a decrease in recorded information due to a rise in the temperature of the phosphor plate 12, avoid light in a wavelength range that has a large thermal effect, and use light in a wavelength range that can be distinguished from the light emitted by the phosphor. It is desirable to use it.
In this embodiment, He-Ne laser light (wavelength
633nm) is used.

The image-bearing fluorescing emitted from the phosphor excited by scanning with laser light is detected by a photodetector 21.
This signal is converted into an electrical signal by a control circuit, which will be described later, and then controls the amount of light from a light source 23 for recording an image on a photographic film 22, which is the final image recording material. Control circuit 24
has the function of receiving a signal obtained by amplifying the electric signal from the photodetector 21 by the amplifier 25 and converting it into a predetermined value. Here, the predetermined value means, for example, in order to finish an image having various brightness ranges into "an image with an optimal density range on photographic film," the brightness range of the image is changed to a brightness range corresponding to the density range. It refers to the value after conversion when converting to .

The above-mentioned conversion converts the maximum and minimum values of the energy storage amount obtained from the instantaneous emitted light stored in the storage means 17 into the maximum and minimum values of the above-mentioned "optimum density range on the photographic film". The values are made to correspond to the luminances, and this is done on the assumption that there is a direct relationship between them.

This relationship is shown in FIG. In FIG. 3, the horizontal axis shows the energy storage amount of the two images A and B, the vertical axis shows the effective density of the image recorded on the photographic film by the light source 23, and the straight line A-A' shows the energy storage amount of the two images A and B. Quantities a to a'), the straight line B-B' is the image B
(energy storage amounts b to b'), respectively. The points of each energy storage amount are recorded on the photographic film 22 as points within the "optimal density range on the photographic film" by the above-mentioned relational straight line, and the image as a whole is recorded within the optimum density range.
In other words, an image with a relatively wide distribution of energy storage amount, such as image A in FIG.
It is also possible to record images having a relatively narrow energy storage amount distribution such as 1.

Further, in some cases, points corresponding to the maximum and minimum values of the energy storage amount may be singular points on the image. Considering such a case, for example, 10 times each of the upper and lower values between the detected maximum and minimum values.
It is also effective to cut out the range corresponding to the energy storage amount of % and finish the remaining range so that it corresponds to the maximum and minimum values of the above-mentioned "optimal density range on photographic film".

The above has mainly focused on the processing at the time of reading out stored images, focusing on the maximum and minimum values of the image, but various other aspects are possible for image processing based on the detection of instantaneous emitted light. It is. An example of using a brightness histogram on an image will be described next.

If you create a histogram (see Figure 4) with the outputs of the photodetectors 13a, 13b...13n on the horizontal axis and the frequency of their appearance on the vertical axis, you can determine the characteristics of the image, that is, the high key (curve C). Is it low key (Curve D) or high contrast (Curve E)?
It is possible to understand whether the current level is low (curve F), etc. Here, for things whose frequency exceeds a certain value,
By determining the density of the maximum and minimum outputs on the final image, a better quality image can be obtained than when the frequency is not considered.

Furthermore, it is also effective to determine from the shape of the histogram a portion corresponding to an unnecessary portion, such as a peripheral portion of the image, and delete it to increase the weight of the main portion of the object.

Moreover, it is also possible to more actively convert the shape of the histogram into a more preferable shape. In this case, it is convenient to use a cumulative histogram (see FIG. 5) in which the horizontal axis is the output of the photodetector and the vertical axis is the cumulative value of the frequency of appearance. The cumulative histogram has the characteristic that image characteristics such as high key (curve G), normal (curve H), low key (curve J), or high contrast (curve K) and low contrast (curve L) are easier to judge than in a simple histogram. (Reference: “A Statistical Method for
Image Classification and Tone Reproduction
Determination.”Journal of Applied
Photograplic Engineering, Volume 3, No. 2,
1977). By converting the shape of this cumulative histogram, the image recorded on the photographic film can be made to have desirable characteristics.

In addition to the above-mentioned photodetection element, a stimulable image pickup tube such as a silicon image pickup tube can be used to detect the instantaneous emitted light. In this case, the image on the phosphor plate is projected onto an image pickup tube via an imaging optical system and is temporarily recorded in the form of an electric charge or the like. This record is sequentially scanned with an electron beam from an image pickup tube and converted into an electrical signal for use.
Since the image pickup tube used here is not for recording the final image, a small one with low resolution may be sufficient.

If the instantaneous light emitted from the phosphor plate is particularly weak, it may be amplified by an image intensifier or the like and then received by a photodetector as described above.

The application of the stored information to image processing in the above-mentioned embodiment is, for example, when the stored information is used as a characteristic value on a CRT.
The above display or a printed version may be used either by a man-machine system that manually sets the printing conditions for the photosensitive material, or by pure electrical processing regardless of whether analog or digital processing is used. It may also depend on the operation. In this case, it is also possible to use a minicomputer if necessary.

As described above, according to the present invention, by detecting the instantaneous light emitted by the stimulable phosphor during radiation irradiation, a radiation image is accumulated and recorded on the stimulable phosphor during radiation irradiation, and at the same time, the characteristics of this image can be determined. Information is obtained from image analysis using the instantaneous emitted light, and this information is applied in the subsequent stage of reading out the accumulated image from the stimulable phosphor, and at the same time as the readout, this signal is converted to quickly produce the desired image. This method not only makes it possible to obtain a large amount of data, but also allows for a significant cost reduction of the device because it does not require a large-capacity storage device unlike the conventional method. In addition, not only the device but also the operation is simplified, which has a great practical effect.

[Brief explanation of the drawing]

FIGS. 1 and 2 are block diagrams showing embodiments of the present invention, and FIGS. 3 to 5 are graphs showing examples of image characteristic conversion. 12...Storage phosphor plate, 13...Photodetector,
15... Maximum/minimum value discrimination means, 16... Conversion means, 17... Storage means, 21... Photodetector, 22
. . . Photographic film, 23 . . . Light source, 24 . . . Control circuit.

Claims (1)

[Claims] 1. In a radiation image recording method using a stimulable phosphor, by detecting the instantaneous light emitted by the stimulable phosphor during radiation irradiation, it is possible to record a radiation image on the stimulable phosphor during radiation irradiation. ,
Information regarding the characteristics of this image is obtained from the aforementioned instantaneous emitted light, and this information is applied in the subsequent step of reading out the accumulated image from the stimulable phosphor to transform the read out signal. Characteristic radiographic image recording method.