JP2969313B2 - Radiation image reading processing condition determination method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation image reading process for obtaining a reading condition for obtaining an image signal and an image processing condition for performing image processing on the image signal based on a histogram of the image signal representing the radiation image. It relates to a condition determination method.

[0002]

2. Description of the Related Art A recorded radiographic image is read to obtain an image signal, and the image signal is subjected to appropriate image processing.
Reproduction and recording of images are performed in various fields.
For example, recording an X-ray image using a low gamma X-ray film designed to be compatible with subsequent image processing,
The X-ray image is read from the film on which the X-ray image is recorded, converted into an electric signal, the electric signal (image signal) is subjected to image processing, and then reproduced as a visible image in a copy photograph or the like, thereby obtaining a contrast. A reproduced image having good image quality performance such as image quality, sharpness, and graininess has been obtained (see Japanese Patent Publication No. 61-5193).

[0003] Further, the applicant of the present invention has proposed that radiation (X-ray, α
Radiation, β-rays, γ-rays, electron beams, ultraviolet rays, etc.), a part of this radiation energy is accumulated, and then irradiation with excitation light, such as visible light, causes a photostimulated emission according to the accumulated energy. Using stimulable phosphor (stimulable phosphor)
The radiation image information of a subject such as a human body is temporarily recorded on a sheet-shaped stimulable phosphor, and the stimulable phosphor sheet is scanned with an excitation light such as a laser beam to generate stimulated emission light. A radiation image recording / reproducing system has already been proposed in which the emitted light is photoelectrically read to obtain an image signal, and a radiation image of the subject is output as a visible image to a recording material such as a photographic material or a CRT based on the image data. (JP-A-55-12429, JP-A-56-11395, JP-A-55-163472, and JP-A-56-1)
04645, 55-116340, etc.).

[0004] This system has the practical advantage of being able to record images over a very wide radiation exposure area compared to conventional radiographic systems using silver halide photography. That is, in the case of the stimulable phosphor, it has been recognized that the amount of emitted light that is stimulated by excitation after accumulation is proportional to the radiation exposure amount over an extremely wide range. Even if fluctuates considerably, the amount of the stimulating light emitted from the stimulable phosphor sheet is read by the photoelectric conversion means with the reading gain set to an appropriate value and converted into an electric signal. Recording materials such as photographic photosensitive materials using
By outputting a radiation image as a visible image on a display device such as a CRT, it is possible to obtain a radiation image that is not affected by a change in radiation exposure.

[0005] In the above system, before the image signal is obtained by reading under the optimum reading conditions in accordance with the dose of the radiation applied to the stimulable phosphor sheet or the like, the stimulable phosphor sheet is previously irradiated with a low-level light beam. Scan ahead to read the outline of the radiation image recorded on this sheet,
The pre-read image signal obtained by this pre-read is analyzed, and then the sheet is irradiated with a high-level light beam and scanned,
There is also a system configured to perform a main reading in which an image signal is obtained by reading the radiation image under the optimum reading conditions.

Here, the reading condition is a general term for various conditions that affect the relationship between the amount of stimulated emission light in reading and the output of the reading device. It means the scale factor or the power of the excitation light in reading.

[0007] The high level / low level of the light beam means the magnitude of the energy of the light beam applied per unit area of the sheet or the energy of the photostimulated light emitted from the sheet, respectively. When it depends on the wavelength of the light beam (has a wavelength sensitivity distribution), the weight of the energy of the light beam irradiated per unit area of the sheet is weighted by the wavelength sensitivity. In other words, the method of changing the level of the light beam includes a method of using light beams of different wavelengths, a method of changing the intensity of a light beam emitted from a laser light source or the like, and inserting and removing an ND filter or the like on an optical path of the light beam. Known methods such as a method of changing the intensity of the light beam, a method of changing the scanning density by changing the beam diameter of the light beam, and a method of changing the scanning speed The method of people can be used.

[0008] Regardless of whether the system performs the pre-reading or the system which does not perform the pre-reading, the obtained image signal (including the pre-reading image signal) is analyzed, and the optimum image when the image signal is subjected to the image processing is analyzed. In some systems, processing conditions are determined. Here, the image processing condition is a general term for various conditions when a process that affects the gradation and sensitivity of a reproduced image based on an image signal is performed on the image signal. The method for determining the optimum image processing conditions based on this image signal is not limited to a system using a stimulable phosphor sheet,
For example, it is also applied to a conventional system for obtaining an image signal from a radiation image recorded on a recording sheet such as an X-ray film.

In the above-described calculation for obtaining reading conditions and / or image processing conditions (hereinafter, referred to as reading conditions, etc.) based on the image signals (including the pre-read image signals), a large number of radiation images are statistically processed in advance. The algorithm is determined based on the results (see, for example, JP-A-60-185944 and JP-A-61-280163).

As one of the conventionally employed algorithms, there is known a method of obtaining a histogram of an image signal and obtaining reading conditions and the like based on the histogram. A method of obtaining reading conditions and the like based on the histogram is subdivided into a method for obtaining both a maximum value and a minimum value of a range required as image information from a histogram of an image signal, and sandwiching the maximum value and the minimum value. (See Japanese Patent Application Laid-Open No. 60-156055), for example, obtains only the maximum value from the above-mentioned histogram, and determines a predetermined value from the maximum value. A method in which the subtracted value is set to a minimum value, and a range sandwiched between the maximum value and the minimum value is set to a range of necessary image information (see Japanese Patent Application Laid-Open No. 60-185944). A method in which a value obtained by adding a predetermined value to the minimum value is set as a maximum value, and a range sandwiched between the minimum value and the maximum value is set as a necessary image information range (see Japanese Patent Application Laid-Open No. 61-280163). Difference histogram (See JP-A-63-233658), a method using a cumulative histogram (see JP-A-61-170730), and a method of dividing a histogram into a plurality of small areas based on a discrimination criterion (see JP-A-63-233658). Two
A method is known in which a necessary range of image information is obtained by using a number of methods, and the reading conditions and the like are determined based on the obtained range.

When reading conditions and the like are determined from the histogram, it is necessary to set the maximum value and the minimum value of the histogram as described above. For example, when the minimum value is set in the above-described method, a certain threshold value is set, and the image signal value at the point where the frequency of the histogram exceeds the threshold value for the first time is determined from the lowest image signal value side of the histogram. Value, the method of maximizing the image signal at the point where the frequency of the histogram exceeds the threshold value from the viewpoint of the highest image signal value of the histogram, and the method of calculating the cumulative histogram of the image signal. The maximum and minimum values are set by the method of setting the image signal level at the point where the frequency exceeds a certain threshold value or at the point where the ratio of the cumulative frequency to the whole exceeds a certain threshold value to the maximum value or the minimum value. ing.

[0012]

However, for example, the image information carried in the image signal for determining the reading conditions and the like includes not only the required image information but also various unnecessary image information. Therefore, there may be a case where the maximum value and the minimum value of the desired image information range cannot be properly obtained due to the presence of the unnecessary image information. If the maximum value and the minimum value obtained in such a case are not appropriate values, the reading conditions and image processing conditions determined based on these values are also inappropriate, and eventually the observation readability is excellent. It is difficult to reproduce the visible image.

As an example of such a case, there is a case of a margen image. That is, when a radiographic image for examination of a magen (stomach) is obtained, imaging is performed by imaging the magen part using a contrast agent such as barium. The concentration is much lower than the untreated part. Fig. 3 (a) shows an example of the histogram of this magen image.
Shown in Although two peaks appear in the histogram 1 shown in FIG. 3A, the peak A is a low-density region corresponding to the contrast agent portion, and the peak B is a region corresponding to a portion other than the contrast agent. When the maximum value and the minimum value are obtained from this histogram, and the reading conditions and the like are determined from the histogram by the method described above,
Originally the image signal values S ₁ in the histogram 1 is the minimum value is desirable.

However, since the above-described method for obtaining the minimum value of the histogram is unique, if the height and the area of the peak A change due to the change in the area of the contrast agent portion, a level lower than the image signal value S ₁ is obtained. There is a case where the image signal value corresponding to the inside of the mountain A is obtained as the minimum value. If such a value is set as the minimum value of the histogram, the desired image information range becomes extremely wide, the density of the image in a portion necessary for diagnosis increases, and as a result, the contrast is reduced, and satisfactory diagnosis is performed. It will be difficult. This is not limited to the case of a magen image, and the same applies to an image having a low-density region such as an image including artificial bone or metal, and an image obtained by imaging with an irradiation field aperture.

In the case of an image having a so-called pierced portion irradiated directly with radiation other than the subject, the histogram has a ridge C and a ridge D corresponding to the pierced portion as shown in FIG. 3 (b). , that the image signal value S ₂ in the histogram 2 in FIG. 3 (b) is a maximum value described above desirable. However, since how to determine the maximum value of the histogram as described above it is uniquely, by the area of the to missing portion varies, mountain C height, area varies higher than the image signal values S ₂ levels There is a case where the image signal value corresponding to the inside of the mountain D is obtained as the maximum value. Also in this case, the contrast of the image decreases, and satisfactory diagnosis becomes difficult.

That is, if the range required for the image information in the histogram is wide, it is difficult to determine the optimum reading conditions and the like, and as a result, it is difficult to obtain a visible image excellent in observation and interpretation. Become.

Therefore, when the reading conditions and the image processing conditions are determined based on the image signal by the above method, the maximum value and the minimum value of the required range of the appropriate image information are always obtained, and the maximum value is determined. It is desirable to determine those conditions based on the value and the minimum value.

The above problem can occur regardless of the type of recording medium on which the radiation image information is recorded, that is, regardless of whether the recording medium is a stimulable phosphor sheet.

SUMMARY OF THE INVENTION In view of the above circumstances, it is an object of the present invention to set an appropriate maximum range of desired image information without being affected even if an image signal includes a low-density area or a high-density area unnecessary as image information. It is an object of the present invention to provide a method for determining radiation image information reading processing conditions, which can determine values and minimum values and determine appropriate reading conditions and image processing conditions based on the maximum and minimum values.

[0020]

According to a first radiographic image reading processing condition determining method of the present invention, a histogram of an image signal carrying a radiographic image is obtained, and the histogram is used as image information of the radiographic image of the image signal. In a method for determining a maximum value and a minimum value in a required range and determining a reading processing condition of the radiation image based on the maximum value and the minimum value, the minimum image signal Smi in the histogram is determined.
n, and any image signal value greater than the minimum image signal value Smin in the histogram and smaller than the image signal value Sh corresponding to the maximum frequency of the range required as image information of the radiation image is represented by S, When the frequency of the histogram in S is H (s), H (s) /
The image signal value S at which (S−Smin) is minimum is obtained as the minimum value.

According to a second radiographic image reading processing condition determining method of the present invention, a histogram of an image signal carrying a radiographic image is obtained, and a histogram of the image signal within a range required as image information of the radiographic image is obtained from the histogram. In a method of determining a maximum value and a minimum value, and determining a reading processing condition of the radiation image based on the maximum value and the minimum value, determining a maximum image signal Smax in the histogram, and determining the maximum image signal value in the histogram Sma
Any image signal value smaller than x and larger than the image signal value Sh corresponding to the maximum frequency of the range required as image information of the radiation image is represented by S, and the frequency of the histogram in the image signal value S is represented by H (s). H (s) / (Sma
x−S) is determined as the maximum value.

Here, the minimum image signal value Smin refers to not only the lowest image signal value of the histogram but also the value of the image signal whose frequency exceeds a predetermined threshold for the first time in view of the lowest image signal value. Is also included. The maximum image signal value Smax includes not only the highest image signal value in the histogram but also the image signal value whose frequency exceeds a predetermined threshold for the first time in view of the highest image signal value.

[0023]

According to the radiation image reading processing condition determining method of the present invention, a minimum image signal value Smin of a histogram of an image signal carrying a radiation image is obtained, and an image signal corresponding to a maximum frequency of a range required as image information of the radiation image is obtained. Assuming that an arbitrary image signal value smaller than the value Sh is S and the frequency of the histogram in the image signal value S is H (s), H (s) /
The image signal value S at which (S-Smin) is minimum is set to the minimum value described above. This minimum value corresponds to the least frequent image signal value between the peak of the low density region and the peak of the high density region in the histogram, that is, the minimum value of the image signal value carrying the desired image information. Therefore, if the reading conditions and the like are determined based on the minimum value and the maximum value of the image signal value carrying the desired image information, it is possible to determine the optimal reading conditions and the like for the image corresponding to the histogram.

In another radiographic image reading condition determining method according to the present invention, a maximum image signal value Smax of a histogram of an image signal carrying a radiographic image is obtained, and an arbitrary image signal value larger than the aforementioned image signal value Sh is determined. S, when the frequency of the histogram in this image signal value is H (s), the image signal value S at which H (s) / (Smax-S) is the minimum.
Is the maximum value described above. This maximum value corresponds to the least frequent image signal value between the peak of the low density region and the peak of the high density region in the histogram, that is, the maximum value of the image signal value carrying the desired image information. . Therefore, if the reading conditions and the like are obtained based on the maximum value, it is possible to obtain the optimum reading conditions and the like for the image corresponding to the histogram.

[0025]

Embodiments of the present invention will be described below in detail with reference to the drawings.

In the embodiments described below, the present invention is applied to a radiation image information recording / reproducing system using the above-mentioned stimulable phosphor sheet.

First, a description will be given of an embodiment in which a reading condition for main reading is determined based on a pre-read image signal which is an image signal for condition determination.

First, a pre-read image signal is read from the stimulable phosphor sheet on which the radiation image information of the magen of the human body as the subject is recorded by the pre-reading described above.

Next, the read pre-read image signal is input to a computer system, and a histogram of the image signal is created in the computer system. An example of this histogram is shown in FIG. The histogram 1 has two peaks. A peak A corresponds to a low-density region corresponding to a contrast agent such as barium for contrasting a magen, and a peak B corresponds to other portions.

First, as shown in FIG. 1 (a), a predetermined threshold value Th is determined, and an image signal value Smin1 exceeding the threshold value Th is first determined from the lowest image signal value Smin0 of the histogram 1. Further, a range required as image information of the radiation image in the histogram 1, that is, an image signal value Sh corresponding to the maximum frequency of the main histogram is also determined.

Next, as shown in FIG. 1B, the histogram 1 is searched for the image signal value Sh starting from the image signal value Smin1. Then around the intersection T ₁ of the S-axis of the image signal value Smin1 and histograms 1, vector V ₁ toward the X point representing the frequency H (s) in the image signal value S is on the histogram 1 is determined, the vector V ₁
Angle theta ₁ formed by the S-axis of the histogram 1 is determined with. The vector V ₁ and the angle θ ₁ are obtained up to the image signal value Sh of the histogram 1, and the image signal value S in which the angle θ ₁ is the minimum is obtained. The image signal value S at which the angle θ ₁ is minimum is the histogram 1
Is regarded as an image signal value between the valley A corresponding to the low-density region and the valley between the peak B corresponding to the other region, and this image signal value S is an image signal value in a range necessary as image information of the radiation image. It is obtained as the minimum value Smin of the value.

In this embodiment, the image signal value S at which the angle θ ₁ is minimum is obtained as the minimum value Smin. This is because the frequency of the histogram 1 at an arbitrary image signal value S is represented by H (s). Then, only the image signal value that minimizes H (s) / (S−Smin1) (1) is obtained. That is, the relationship between the angle theta ₁ with formula (1), since the _{tan θ 1 = H (s)} / (S-Smin) ... (2), Equation (1) is tan theta ₁ of if the minimum The value is also minimum, and therefore the value of the angle θ ₁ is also minimum.

When the minimum value Smin is obtained in this manner, the maximum value Smax of the image signal value in a range required as image information is obtained. In the embodiment according to the present invention, as a method for obtaining the maximum value Smax, the minimum image signal level in the difference histogram is directly used as Smax as shown in FIG. 1B, but other methods such as FIG. A predetermined threshold value Th is set as shown in
A method of setting the image signal level at a point where the frequency exceeds the threshold value to the maximum value Smax, or a cumulative histogram for the difference histogram is created, and the cumulative frequency in the cumulative histogram exceeds a threshold value Th. A method of setting the image signal level at a point where the ratio of the points or the cumulative frequency to the total frequency exceeds a certain threshold value Th to the maximum value Smax, a method of setting the highest image signal value in the histogram to the maximum value Smax, or the like. Is also good.

In the above embodiment, the minimum value Smin of the image signal value which does not include the low density area of the histogram is set. The maximum value Smax of the range required as image information of the image histogram may be obtained. Hereinafter, a method of obtaining the maximum value Smax will be described.

First, as shown in FIG. 2A, a predetermined threshold value Th is determined, and an image signal value Smax1 exceeding the threshold value Th is first determined from the highest image signal value Smax0 of the histogram 2. Further, a range required as image information of the radiation image in the histogram 2, that is, an image signal value Sh corresponding to the maximum frequency of the main histogram is also determined.

Next, as shown in FIG. 2 (b), the histogram 2 is searched for the image signal value Sh starting from the image signal value Smax1. Then around the intersection T ₂ of the S-axis of the image signal value Smax1 histogram 2, vector V ₂ toward the X point representing the frequency H (s) in the image signal value S is on the histogram 2 is determined, the vector V _Two
And the angle θ ₂ between the histogram and the S-axis of the histogram 2 are obtained. The vector V ₂ and the angle θ ₂ are obtained up to the image signal value Sh of the histogram 2, and the image signal value S at which the angle θ ₂ is the minimum is obtained. The image signal value S at which the angle θ ₂ is minimum is represented by histogram 2
Is regarded as an image signal value between the valley D corresponding to the high-density region and the valley between the peak C corresponding to the other region, and this image signal value S is an image signal value in a range necessary as image information of the radiation image. It is obtained as the maximum value Smax of the value.

In this embodiment, the image signal value S at which the angle θ ₂ is minimum is obtained as the maximum value Smax. This is because the frequency of the histogram 2 at any image signal value S of the histogram 2 is represented by H ( s), the image signal value that minimizes H (s) / (Smax1-S) (3) is merely obtained. In other words, the relationship between the equation (3) and the angle theta _2, since the _{tan θ 2 = H (s)} / (Smax1-S) ... (4), Equation (3) tan theta ₂ of if the minimum The value is also minimum, and therefore the value of the angle θ ₂ is also minimum.

When the maximum value Smax is obtained in this way, the minimum value Smin of the image signal value in a range required as image information is obtained. As a method of obtaining the minimum value Smin, as described above, the image signal level at the point where the frequency of the histogram exceeds a predetermined threshold value is set to the minimum value Smi.
n, the method using a cumulative histogram, or the lowest image signal value in the histogram as the minimum value Smi.
The method of n can be adopted.

When the maximum value Smax and the minimum value Smin of the desired image information range are obtained as described above, the maximum value Smax
The reading conditions for the main reading are determined based on the max and the minimum value Smin. Various specific methods for determining the reading conditions based on the maximum value Smax and the minimum value Smin can be used, and an example thereof will be described below with reference to FIG.

That is, in the radiation image information recording / reproducing system, an electric image signal is obtained from the stimulated emission light by the photoelectric reading means according to the reading conditions as described above, and the signal is determined by the image processing means. This signal is subjected to gradation processing in accordance with the gradation processing conditions, and this signal is reproduced and recorded as a visible output image on a photographic material by an image reproducing means. In this output image, there is a density range suitable for observation and interpretation, and in general, this appropriate density range (Dmax to Dmax)
min) is determined in advance, and the reproduction conditions (conditions for determining the relationship between the input to the reproduction means and the output from the reproduction means) in the image reproduction means are determined in advance by what kind of image reproduction means is used. , The optimal concentration range (Dmax ~
Dmin), the input signal level (Rmax to Rmin) to the image reproducing means is uniquely determined by the image reproducing conditions. Further, since the gradation processing conditions in the image processing means are also determined in advance by the photographing conditions and the like, the input signal levels (Qmax to Qmin) to the image processing means corresponding to the input signal levels (Rmax to Rmin) to the image reproducing means are determined. It is uniquely determined by the gradation processing conditions. Therefore,
The input signal level range (Qmax-Qmin) to the image processing means corresponding to the appropriate density range (Dmax-Dmin) is uniquely determined according to predetermined gradation processing conditions and image reproduction conditions. Therefore, the maximum value S obtained as described above
The reading condition is set so that max and the minimum value Smin correspond to Qmax and Qmin determined as described above.

Note that the maximum value Smax and the minimum value Smin are Qma
To set the reading conditions to correspond to x and Qmin,
The range of the image signal level (Smax-Smin) in the pre-reading is equal to the image signal level (Qmax-Qmin) in the main reading.
) Means that the reading conditions used for pre-reading are shifted as shown in FIG. 4 in consideration of the difference in excitation light energy between pre-reading and main reading. And the maximum value Smax and the minimum value Smin are Qma
What is necessary is just to set the reading conditions of the main reading so as to correspond to x and Qmin. As shown in the drawing, shifting the reading condition means changing the reading gain, and rotating means changing the recording scale factor. Further, the reading condition is not limited to a linear condition as shown in the figure, but may be a curved condition.

Next, the maximum value S determined as described above
An embodiment in which a gradation processing condition, which is one of the image processing conditions, is determined based on max and a minimum value Smin will be described with reference to FIG. In the embodiment described below, the conditions for performing the gradation processing on the main-read image signal in the case where the main reading is performed according to the reading conditions appropriately determined without being based on the maximum value Smax and the minimum value Smin are determined.

In this case, since the reading conditions for the main reading are appropriately determined, the image signal (the maximum value Smax to the minimum value Smin) in the pre-reading determined as described above.
) In the actual reading (maximum value Smax 'to minimum value Smin)
'), Which is not necessarily the above (Qmax
ＱQmin), the range where the image information is required is left in the proper density range (Dmax〜Dmin).
Can no longer be displayed.

Therefore, the maximum value Smax and the minimum value Smin of the required range of the image information in the pre-read image signal obtained as described above are the maximum signal level Rmax and the minimum value Smin of the desired input signal range in the image reproducing means. Signal level R
min, that is, considering the reading conditions for pre-reading and main reading, etc., the above-mentioned main reading image signals Smax 'and Smin' corresponding to the pre-read image signals Smax and Smin are obtained.
x'-Smin ') is determined so that the gradation processing conditions are output as (Rmax-Rmin) after image processing.

The gradation processing is performed by an image processing means (gradation processing means).
Is a process of converting the level of each image signal input to the device according to a certain condition and outputting the converted signal. The certain condition is called a gradation processing condition and is usually represented by a non-linear gradation curve.

This gradation processing is intended to obtain a preferable visible output image suitable for the purpose of diagnosis in accordance with imaging conditions such as an imaging part such as a head and a chest and an imaging method such as simplicity and contrast. Therefore, in general, the basic form of the non-linear gradation processing condition having the most preferable pattern for each photographing condition is determined in advance, and when performing gradation processing of each image, the basic form of the non-linear gradation processing condition is determined. It is preferable to select a basic form of an appropriate gradation processing condition in accordance therewith and perform gradation processing using the basic form.

Also in the present embodiment, an appropriate one is selected from the basic forms of the predetermined gradation processing conditions in accordance with the photographing conditions of the image in this way, and is corrected, that is, the basic form is selected. Are shifted vertically as shown in FIG. 4 or rotated about a predetermined center point K so that Smax 'and Smin' are output as Rmax and Rmin. To be used is determined.

The gradation processing conditions are not limited to the above-described non-linear ones, but may be linear ones. In this case, one predetermined straight line is used in the same manner as in the above case. Rotate or shift to Smax ',
The gradation processing conditions to be used are determined by positioning so that Smin 'is output as Rmax and Rmin. The determination of the gradation processing condition by this method is performed based on only the maximum value Smax and the minimum value Smin of the required range of the image information without being based on the imaging part or the imaging method.

Further, in one embodiment of the radiation image information recording / reproducing system, there is a system which immediately performs the main reading without performing the pre-reading. In this case, the main reading is performed according to the preset reading conditions, and the gradation processing condition is determined based on the main reading image signal. In this case, the present invention can be applied. For example, in the same manner as the above-described specific method of determining the gradation processing condition based on the pre-read image signal, a histogram of the main read image signal is created, and the maximum value Smax or the minimum value Smin is obtained. The gradation processing condition may be determined so that the value Smax and the minimum value Smin correspond to Rmax and Rmin.

In the above embodiment, when it is not desired to include an image signal in a low-density area of a histogram like a magen image, the minimum value Smin of the image signal value in the required range of the image information is set as follows. The maximum value Smax is obtained when it is not desired to include the image signal of the high-density area of the histogram as in the case of an image having many missing parts. However, in the case of the image including the low-density area and the high-density area, According to the present invention, both the maximum value Smax and the minimum value Smin may be obtained.

Further, in the above embodiment, the minimum image signal value and the maximum image signal value of the histogram are the image signal values whose frequency exceeds the predetermined threshold value for the first time when viewed from the lowest image signal value of the histogram. Although the image signal value whose frequency of the histogram exceeds a predetermined threshold value for the first time in view of the highest image signal value of the histogram is used, the lowest image signal value of the histogram and the lowest image signal value of the histogram are used as the minimum and maximum image signal values. The highest image signal value may be used.

[0052]

As described above in detail, the method for determining the conditions for reading radiographic image information according to the present invention is for obtaining the maximum value or the minimum value of the range required as image information. It is possible to obtain a more appropriate maximum or minimum value of the desired image information range than when determining based on the image signal histogram, thereby making it possible to determine more appropriate reading conditions and image processing conditions. A visible image having the suitability for observation and interpretation can be obtained.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining a method for obtaining a minimum value of a range required as image information according to an embodiment of the present invention.

FIG. 2 is a diagram for explaining a method of obtaining a maximum value of a range required as image information according to an embodiment of the present invention.

FIG. 3 is a diagram showing a histogram.

FIG. 4 is a diagram showing a relationship between a visible output image serving as an image signal and density.

[Explanation of symbols]

 1,2 Histogram Smax Maximum value Smin Minimum value

──────────────────────────────────────────────────続 き Continued on the front page (58) Fields surveyed (Int. Cl. ⁶ , DB name) G03B 42/02 G06T 5/00 H04N 1/04 A61B 6/00

Claims (2)

(57) [Claims] 1. A histogram of an image signal carrying a radiation image is obtained, and a maximum value and a minimum value of the image signal in a range required as image information of the radiation image are obtained from the histogram, and the maximum value and the minimum value are obtained. In the method of determining the read processing condition of the radiation image based on the above, a minimum image signal Smin in the histogram is obtained, and the minimum image signal value Smin in the histogram is larger than the minimum image signal value Smin in the range required as image information of the radiation image. Assuming that an arbitrary image signal value smaller than the image signal value Sh corresponding to the maximum frequency is S and the frequency of the histogram in the image signal value S is H (s), H (s) / (S−Smi
n) determining the image signal value S that minimizes the image signal value S as the minimum value. 2. A histogram of an image signal carrying a radiation image is obtained, and a maximum value and a minimum value of the image signal in a range required as image information of the radiation image are obtained from the histogram, and the maximum value and the minimum value are obtained. Determining the reading processing conditions of the radiation image based on the maximum image signal value Smax in the histogram, and the maximum image signal value Smax in the histogram is smaller than the maximum image signal value Smax in the histogram, and the range required as image information of the radiation image When an arbitrary image signal value larger than the image signal value Sh corresponding to the maximum frequency is S and the frequency of the histogram in the image signal value S is H (s), H (s) / (Smax−
A method for determining a condition of a radiation image reading process, wherein the image signal value S that minimizes S) is obtained as the maximum value.