JPH0777749A - Radiation image information reader - Google Patents

Abstract

PURPOSE:To decrease the operation errors in photographing and reading process and the troubles of the radiation image information reader having a means for discriminating whether the result of photographing is okay or not by processing the image information read from a recording medium recorded with the radiation image. CONSTITUTION:This image information reader is composed of a reading section 1, an analysis processing section 3 and a control section 4. The analysis processing section 3 outputs a discrimination result signal to the control section 4 according to the result of the comparison obtd. by executing prescribed arithmetic processing with the pixel values on prescribed scanning lines or the frequency values of the prescribed pixel values, for example, determining a mean, max., min., and difference and comparing the results thereof with a reference value for comparison. The control section 4 immediately discriminates whether a series of routine photographing are adequately ended or not according to the discrimination result signal. The control section immediately executes starting of rephotographing when the result of the photographing is judged to be defective.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation image information reading apparatus provided with a means for processing image information read from a recording body on which a radiation image is recorded and determining whether or not a photographing result is good or bad.

[0002] Conventionally, a mass examination has been performed using a radiation image device, but the imaged image cannot be used for diagnosis due to an operation error in the process of taking an image, a process of reading the imaged image, a temporary failure of the device, or the like. However, in the related art, separately, only a specific individual whose shooting result is poor is dealt with by re-shooting or the like, and there is a problem that operability is extremely poor.

Therefore, the image information read from the recording body on which the radiation image is recorded is processed, and the quality of the photographed result is judged in real time. If it is possible to reduce imaging defects due to various malfunctions or the like, it is possible to improve operability and reliability in the above-mentioned group medical examination.

For this reason, there is a need for a radiation image information reading device that can effectively determine the quality of a captured image.

[0005]

2. Description of the Related Art FIG. 9 is a diagram for explaining a conventional radiation image information reading apparatus, and FIG. 9 (a) shows an example of the configuration.
(b) shows the processing flow.

A conventional radiation image information reading apparatus is shown in FIG.
With the configuration shown in (a), the image information read from the recording body on which the radiation image is recorded is transferred to the image processing circuit 6
Then, after performing the emphasis processing, for example, display unit 8, printing unit
Displayed or printed at 7 or recorded on a film (not shown) is visually read by a doctor (see processing step 103 in FIG. 9) and read from the recording medium of the radiation image information reading device. The quality of the image was judged. {Refer to processing steps 100 to 105 in Fig. 9 (b)}

[0007]

Therefore, in the conventional radiographic image information reading device, the image recorded or displayed on the film or the display is actually visually judged to judge whether or not the photographing result is good or bad. If it is difficult to identify, the individual in the image data is recognized, and another image is taken again for the reason that there is a predetermined finding in a specific part, so that There is a problem that a heavy burden is given, or if the diagnosis is originally performed based on an image with poor imaging accuracy, the accuracy of the diagnosis becomes poor.

In view of the above-mentioned drawbacks of the prior art, the present invention processes the image information read from the recording body on which the radiation image is recorded, determines the quality of the photographing result in real time, and performs the photographing and reading process of the photographed image. It reduces shooting defects caused by operation mistakes, temporary device failure, etc.
Another object of the present invention is to provide a radiation image information reading device that can improve the accuracy of diagnosis.

[0009]

FIG. 1 and FIG. 2 are principle block diagrams of a radiation image information reading apparatus of the present invention. FIG.
FIG. 2 shows an example of the configuration, FIG.
5A to 5C are diagrams showing an example of arithmetic operation in the analysis processing unit of the present invention. The above problems can be solved by the radiation image information reading apparatus configured as follows.

(1) A radiation image information reading device for reading image data from a recording body on which a radiation image is recorded by being irradiated with radiation and processing the image data on the recording medium, the image data reading section 1 And an amplification processing unit 2, an analysis processing unit 3, and a control unit 4
An analysis unit 3 includes means 300 for extracting a pixel on a predetermined scanning line of the image data, means 301 for analyzing an image from a pixel value of the pixel, and a frequency value of a specific pixel value. The processing circuit 30 and the comparison reference data generation circuit 31 that generates a reference value to determine that the shooting has completed normally
And the processing data created by the analysis processing circuit 30,
The control unit 4 includes a data comparison circuit 32 that compares a reference value generated by the comparison reference data generation circuit 31, and the control unit 4 performs a series of routine photographing in accordance with a determination result signal output from the data comparison circuit 32. It is configured to determine whether or not the process has been properly finished, and output a start signal for re-imaging based on the determination result.

(2) The analysis processing unit 3 is a processing unit 301, 302, 303 for the pixel value of each pixel on a predetermined scanning line.
And arithmetic processing means 304, 30 relating to the frequency value of a specific pixel.
It is configured to have either one or both of 5,306.

(3) The analysis processing unit 3 has a result of integration processing on pixel values of each pixel on a predetermined scanning line, and
Alternatively, regarding the pixel value of each pixel on the predetermined scan line A,
Regarding the difference value Δ of two or more pixel values or the pixel value of each pixel on a predetermined scanning line A, the maximum value (MAX) and the minimum value (M
IN), or the integration result of frequency values regarding a specific pixel on a predetermined scan line A, or between two or more frequency values regarding pixels having a specific gradation value on a predetermined scan line A. Difference value Δ or a specific gradation value on a predetermined scanning line A
The maximum value (MAX) and the minimum value (MIN) of frequency values between pixels having (A, B) are compared with the reference value generated from the comparison reference data generating circuit 31.

[0013]

According to the present invention, the photographing result discrimination processing means is an analysis processing section, which performs arithmetic processing on pixel values of pixels on a predetermined scanning line or frequency values, for example, average value, maximum / minimum, difference value Δ. Obtained, for each, compared with the comparison reference value, and outputs a determination result signal to the control unit according to the comparison result, the control unit immediately determines whether or not a series of routine imaging is appropriately ended according to the determination result. The determination is made, and if it is inappropriate, an instruction for re-imaging is given.
{Refer to the processing steps 106, 107, and 108 in FIG. 2} Hereinafter, a specific example of the photographing result discrimination processing means will be described with reference to FIGS.

1) Processing when a calculated value (integrated value) on a specific main scanning line (main scanning, sub-scanning direction) A is used as a comparison target value: FIG. 3A shows a radiation image of this case. The entire image is schematically shown, a specific main scanning line A is shown by a dotted line, and FIG. 3B shows an example of distribution of pixel values on the specific scanning line.

In this example, the pixel value of each pixel of a specific main scanning line A is integrated, the calculation processing result (S) is compared with the comparison reference value (ε), and if (ε _LOW <S <Ε _HIGH ): Normal shooting, else abnormal shooting:
Reshooting For example, if constant: K pixel value integrated value: H _i pixel value: D _i pixel number: i (0 ≦ i <M) integrated processing value: S, then H _i = ΣD _i (i = 0 to M− 1) It is a process for obtaining an integration process value S obtained by S = K × H _i / (M−1).

When the radiation image device is a radiation image conversion device using a stimulable (stimulated) phosphor, in the imaging plate (IP) coated with a stimulable luminescent material, partial peeling of the phosphor, Although dust may be attached to the imaging plate (IP) and the captured image may be defective, the integrated processing value S as described above is obtained and compared with a comparison reference value to As described above, it is possible to detect partial peeling of the phosphor, adhesion of dust, and the like on the imaging plate (IP), and it is possible to detect imaging abnormalities.

The comparison reference value table (MEM) 300 for each patient information shown in FIG. 3C is a designated region of the radiation image of the subject,
5 is a diagram schematically showing a table of comparison reference values ε _LOW and ε _HIGH to be compared with the integrated processing value S, which is determined by sex, medical history, operation history and the like. A detailed example will be described later.

2) Specific scanning line (main scanning, sub-scanning direction) A
Processing when the above calculated values (difference value, maximum / minimum value) are used as comparison target values: Fig. 4 (a) schematically shows the whole image of the radiation image in this case. A is indicated by a dotted line, and FIG. 3B shows an example of distribution of pixel values on the specific scanning line A.

As is clear from FIG. 4B, the processing shown in this example is the difference value Δ on the specific scanning line A, or the maximum value.
(MAX) In the process of finding the minimum (MIN), when the pixel value: D _i pixel number: i (0 ≦ i <M) and k, l∈i, the difference value: S = D _k −D _l maximum The following comparison processing is performed on the difference value Δ, the maximum value (MAX) and the minimum value (MIN) obtained as the minimum value: S = D _max −D _min . (a) if (comparison reference value _LOW <difference value on specific scanning line A <comparison reference value _HIGH ) → normal imaging, else → abnormal imaging → re-imaging (b) if (comparison reference value _LOW <specific scanning line A Maximum / minimum value <comparison reference value _HIGH ) → normal imaging, else → abnormal imaging → re-imaging The process of obtaining the difference value and the maximum / minimum value of this pixel value is performed, for example, on the stomach wall, transverse membrane, liver, etc. When diagnosing a lesion, if the above-mentioned difference value Δ is large, for example, there is a suspicion of cirrhosis, and in order to improve the resolution of the site, the total amount of X-rays is changed (in this example, increased), or Re-imaging is performed by increasing the amplification degree of photoelectrons that can be read from the IP.

3) From the frequency distribution of each pixel value of the photographed image,
Processing for determining the quality of shooting: As shown in FIG. 5 (a), the calculated value of the frequency value {maximum (MAX) minimum value (MIN),
Difference value Δ, average value) or any gradation, for example, in FIG.
The calculated value within the range of gradation (A, B) of (b) is
In the process of comparing with the specified comparison reference value, the difference value Δ between the calculated value and the frequency value, or the maximum (MAX) minimum (MIN) value is calculated, and (a) if (comparison reference value _LOW <frequency value Difference value (maximum / minimum value) <comparison reference value _HIGH ) → normal photography, else → abnormal photography → re-imaging (b) if (comparison reference value _LOW <frequency average value within predetermined gradation range <comparison reference value _HIGH ) Normal shooting, else → Abnormal shooting →
Re-imaging: The process of determining the quality of imaging from the frequency distribution of each pixel value of this captured image is performed by, for example, a pacemaker at the heart region.
If it is (made of metal), the frequency of a specific pixel value becomes abnormally high.
(Maximum / minimum value) is compared with the reference value for recognition, and in order to sharpen the image in the vicinity, the total amount of X-rays is increased as described above to obtain an image with good contrast. Processing.

Further, by comparing the integration result of the frequency value of the specific pixel value and the comparison reference value, for example, the above I
The peeling of the image data on P can be recognized.
Further, by extracting the pixels of the scanning line from a continuous region or one or both of the intermittent regions, the range of the scanning line can be arbitrarily designated, and a specific region of the subject can be specified. It is convenient for reading the radiation image information. For example, when looking at the radiation image of the foot of the subject,
By observing the radiation images at both ends, it becomes easy to set the joint part of the foot as the region of interest.

As described above, according to the radiation image information reading apparatus of the present invention, a predetermined calculation is performed on the image information read from the recording body on which the radiation image is recorded without visually observing the radiation image. A calculated value, for example, an integrated value of pixel values of each pixel on a predetermined scanning line A, a difference value Δ of pixel values of each pixel, a maximum (MAX) minimum (MIN) value, or a predetermined gradation ( (A, B) The difference value Δ of the frequency values in the range, the average value, etc. are obtained and compared with the comparison reference value set in advance to obtain an abnormal image area, and the imaging conditions are changed. By instructing re-imaging, it is possible to determine whether the imaging result is good or bad, and it is possible to reduce operation mistakes in the imaging process and the reading process and failures of the reading device, and to improve the diagnostic accuracy.

[0023]

Embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 and FIG. 2 described above are principle configuration diagrams of the radiographic image information reading device of the present invention, and FIGS. 3 to 5 are diagrams for explaining the arithmetic operation in the analysis processing unit of the present invention, and FIG. ~ Figure 8
6 is a diagram showing an embodiment of the present invention, FIG. 6 shows a configuration example of an analysis processing unit, FIG. 7 shows an operation diagram in the analysis processing unit, and FIG. 8 compares it with a calculation result. The structural example of a comparison reference value table is shown.

In the present invention, when radiation is applied,
A radiation image information reading device for reading image data from a recording body on which a radiation image is recorded and processing the image data on the recording medium, the image data reading unit 1, an amplification unit 2, and an analysis processing unit 3. The analysis processing unit 3 includes means 300 for extracting a pixel on a predetermined scanning line A of the image data, a pixel value of the pixel, and a frequency value of a specific pixel value. Means for analyzing images from 30
1 to 306, a comparison reference data generation circuit 31 that generates a comparison reference value that determines that imaging has been completed normally, and the processing data created by the analysis processing circuit 30. , The comparison reference data generation circuit 3
Data comparison circuit that compares the comparison reference value generated in 1
The control unit 4 determines whether or not a series of routine photographing is properly completed according to the determination result signal output from the data comparison circuit 32, and based on the determination result, the control unit 4 The means for outputting the shooting start signal is a means necessary for carrying out the present invention. The same reference numerals indicate the same objects throughout the drawings.

Hereinafter, referring to FIGS. 1 to 5, FIGS.
The configuration and operation of the radiation image information reading apparatus according to the present invention will be described with reference to FIG. 8, particularly focusing on the configuration and operation of the analysis processing unit.

First, as shown in FIG. 1, the radiation image information reading apparatus of the present invention has an image data reading unit 1
And an amplification unit 2, an analysis processing unit 3, and a control unit 4, and the analysis processing unit 3 extracts a pixel 300 on a predetermined scanning line A of the image data and a unit for extracting the pixel. An analysis processing circuit 30 including a pixel value and means 301, 306 for analyzing an image from a frequency value of a specific pixel value, and comparison reference data for generating a reference value for discriminating that imaging has been normally completed. The generation circuit 31, the processing data created by the analysis processing circuit 30, and the comparison reference data generation circuit 3
Data comparison circuit to compare with the reference value generated in 1 32
And the control unit 4 includes the data comparison circuit.
According to the determination result signal output from 32, it is determined whether or not a series of routine photographing is properly ended, and a re-photographing start signal is output based on the determination result.

As described in detail in the action column, the process of discriminating the photographing result according to the present invention is performed by the analysis processing circuit 30 of the analysis processing unit 3 so that the pixel value of each pixel on the scanning line A selected. , Or, based on the frequency value of a predetermined pixel value, a predetermined calculation process, for example, the result data of the process of obtaining the average, maximum / minimum, difference value Δ, and a comparison reference data generation circuit
The data comparison circuit 32 compares the predetermined reference value from 31 with the data comparison circuit 32, and the control unit 4 determines whether or not the series of routine photographing is properly ended according to the comparison result signal. When re-imaging is required by the discrimination result signal, the re-imaging and re-reading are instructed to the re-imaging / reading unit (not shown) by the re-imaging result signal, and the re-imaging is performed. Automate.
{Refer to the operation flow of FIG. 2} FIG. 6 shows a concrete example of the analysis processing unit 3. First, the information of signals for extracting pixels on a predetermined scanning line such as the histogram analysis presence / absence flag, scanning line number, patient information (sex, presence / absence of surgery, etc.) from the control unit 4 of FIG. The comparison reference value table (MEM) 300 for each patient information shown in is searched, and the comparison reference value corresponding to the instructed scanning line number and the sample hold start flag are output at a predetermined timing.

Comparison reference value table for each patient information (MEM)
300 indicates whether or not the sample hold start flag is present for each scan line number (1 to N) corresponding to the assumed site of each patient. The pixel value of each pixel on the scan line A is integrated.

That is, the integrating circuit 302 composed of the resistor (R1), the operational amplifier (OP1), and the capacitor (C1) is energized, the pixel values of the respective pixels on the scanning line A are integrated, and Integrated value
Input (C1) to the comparator (CMP1) 303.

On the other hand, the comparison reference value table for each patient information
The comparison reference value (digital value) read from the (MEM) 300 is converted into an analog signal (H ₁ ) by the digital / analog converter (D / A) 301 and input to the above comparator (CMP1) 303. , The integrated value of the pixel values on the predetermined scanning line A is
It is compared with the predetermined comparison reference value (H ₁ ) and the integrated result (O ₁ ) satisfying the predetermined condition is output.

Similarly, in the comparator (CMP2) 304,
Pixels exceeding the pixel value indicated by H ₂ in the figure are extracted, and the number of pixels having the extracted pixel value is counted (CNT
(R) 306 counts (C ₂ ) and compares with the comparison reference value (H ₃ ) read from the patient information-specific comparison reference value table (MEM) 300, and integrates the frequency values that satisfy the predetermined conditions. I am trying to get the result (O ₃ ).

Similarly, by combining known circuits (not shown), the difference value of predetermined pixel values, or the maximum / minimum, can be calculated by the above-mentioned patient information comparison reference value table.
Compared with the comparison reference value read from (MEM) 300,
It is clear that the given conditions can be obtained.

The main purpose of the present invention is not the above-mentioned method of constructing the comparison circuit, but a predetermined calculation based on the pixel value of each pixel on a predetermined scanning line A from the read radiation image data. Then, it is determined whether or not the radiation image data is normal, and when it is detected that the radiation image data is not normal, the re-imaging is instructed.

FIG. 7 is an operation diagram showing the operation of determining whether or not the radiation image data is normal, for each signal of FIG. First, according to the timing indicated by the clock (T0, T1, T2, ~ TN), each pixel on the predetermined scanning line A
Read the value of (D _i ) and integrate the pixel value of each pixel (C ₁ )
Is, for example, the last pixel (pixel corresponding to clock TN)
Is determined at the time of reading, and the output signal (O ₁ ) of the determination result is obtained.

Similarly, a frequency value integration result output signal (O ₃ )
Is shown. (Detailed description omitted)
FIG. 8 shows the comparison reference value table (MEM) 30 for each patient information described above.
It shows a specific configuration example of 0. A comparison reference value table (MEM) 300 for each patient information is provided with a histogram analysis flag presence / absence signal, patient information 1 to N, and scanning line numbers 1 to 1.
By searching with N as an address, the comparison reference value can be read.

At this time, the S / H start flags "1" and "0" are determined by the scanning line number.
When the start flag is “1”, as is clear from the detailed example of the analysis processing unit 3 shown in FIG. 6, the integrating circuit 302 is enabled and the pixel value of the pixel on the specific scan line A is changed. The integrated value can be obtained. That is, the patient information comparison reference value table (MEM) 300 defines how to process each pixel value of the image data for each patient and each scanning line A.

In FIG. 1, in the image processing circuit 6,
As described above, the photographed image read by the reading unit 1 and recognized as having a good photographing result is converted into a digital signal by the analog / digital conversion circuit (A / D) 9, and then temporarily stored in the storage circuit 5. After being accumulated and subjected to image processing such as partial emphasis processing by the image processing circuit 6, the image is printed by the printing unit 7 or displayed on the display screen of the display unit 8 and used for diagnosis by a doctor. As described above, the radiation image information reading apparatus according to the present invention is a radiation image information reading apparatus including means for processing the image information read from the recording body on which the radiation image is recorded and determining the quality of the imaging result. , A reading unit, an amplifying unit, an analysis processing unit, and a control unit. In the analysis processing unit, a predetermined calculation process is performed on a pixel value on a predetermined scan line A or a frequency value of the predetermined pixel value, for example, , Average, maximum / minimum, and difference are calculated, and the determination result signal is output to the control unit according to the comparison result compared with the comparison reference value, and the control unit appropriately ends the series of routine photographing according to the above determination result signal. It is characterized in that whether or not it is done is immediately discriminated, and if it is determined that the photographing result is poor, the re-imaging is immediately started.

[0038]

As described above in detail, according to the radiation image information reading apparatus of the present invention, the image information read from the recording body on which the radiation image is recorded without visually observing the radiation image. A calculated value obtained by performing a predetermined calculation, for example, an integrated value of pixel values of each pixel on a predetermined scan line A, a difference value of pixel values of each pixel, a maximum / minimum value, or a predetermined gradation Obtaining the difference value, the average value, etc. of the frequency values in the range, comparing with a predetermined comparison reference value to find an abnormal image area, changing the shooting conditions, and instructing re-shooting. Thus, it is possible to determine whether the imaging result is good or bad, and it is possible to reduce operation mistakes in the imaging process and the reading process and failures of the reading device, and to improve the diagnostic accuracy.

[Brief description of drawings]

FIG. 1 is a principle configuration diagram (1) of a radiation image information reading apparatus of the present invention.

FIG. 2 is a principle configuration diagram of a radiation image information reading apparatus of the present invention (No. 2)

FIG. 3 is a diagram showing an example of arithmetic operation in the analysis processing unit of the present invention (No. 1)

FIG. 4 is a diagram showing an example of arithmetic operation in the analysis processing unit of the present invention (No. 2)

FIG. 5 is a diagram showing an example of arithmetic operation in the analysis processing unit of the present invention (No. 3)

FIG. 6 is a diagram showing an embodiment of the present invention (No. 1).

FIG. 7 is a diagram showing an embodiment of the present invention (No. 2).

FIG. 8 is a diagram showing an embodiment of the present invention (part 3).

FIG. 9 illustrates a conventional radiation image information reading device.

[Explanation of symbols]

1 Reading unit 2 Amplifier 3 Analysis processing unit 30 Analysis processing circuit 31 Comparison reference data generation circuit 32 Data comparison circuit 300 Comparison reference value table by patient information (MEM) 301 Digital / analog converter (D / A) 302 Integration circuit 303, 304, 305 Comparison Controller (CMP1, CMP2, CMP3) 306 Counter 4 Control unit 5 Memory circuit 6 Image processing circuit 7 Printing unit 8 Display unit 9 Analog / digital converter (A / D) Reference value, comparison reference value Data comparison circuit that satisfies the conditions Output signal Photographing result signal Signal for extracting pixels on a predetermined scanning line Δ Difference value MAX maximum value MIN minimum value A Scan line

Claims (10)

[Claims] 1. A radiation image information reading apparatus which reads image data from a recording body on which a radiation image is recorded by being irradiated with radiation and processes the image data on the recording medium, the image data reading section (1). ), An analysis processing unit (3), and a control unit (4), the analysis processing unit (3) is a unit (300) for extracting pixels on a predetermined scanning line of the image data, and Pixel value of pixel,
And means for analyzing the image from the frequency value of a specific pixel value (3
01, ... 306), a comparison reference data generation circuit (31) for generating a reference value () for discriminating that the imaging has been normally completed, and the analysis processing circuit (30). ) And the comparison reference data generation circuit (3
Data comparison circuit that compares with the reference value () generated in 1)
(32), the control unit (4), according to the determination result signal () output from the data comparison circuit (32), determines whether or not a series of routine imaging is appropriately finished, A radiographic image information reading apparatus, which operates so as to output a re-imaging start signal () based on the determination result. 2. The radiation image information reading apparatus according to claim 1, wherein the analysis processing unit (3) is a processing unit (301, 302, 303) for the pixel value of each pixel on a predetermined scanning line (A).
And a calculation processing means (304, 305,
306) A radiographic image information reading device characterized by comprising either one or both of them. 3. The radiation image information reading apparatus according to claim 1, wherein the analysis processing unit (3) performs integration processing on pixel values of each pixel on a predetermined scanning line (A), A radiation image information reading device characterized by comparing with a reference value () generated from the comparison reference data generating circuit (31). 4. The radiation image information reading apparatus according to claim 1, wherein the analysis processing unit (3) has two or more pixels with respect to a pixel value of each pixel on a predetermined scanning line (A). Difference value
A radiation image information reading device characterized in that (Δ) is compared with a reference value () generated from the comparison reference data generating circuit (31). 5. The radiation image information reading apparatus according to claim 1, wherein the analysis processing unit (3) has a maximum value (MAX) with respect to a pixel value of each pixel on a predetermined scanning line (A). ， Minimum value (MI
A radiation image information reading device, characterized in that N) is compared with a reference value () generated from the comparison reference data generating circuit (31). 6. The radiation image information reading apparatus according to claim 1, wherein the analysis processing unit (3) includes a result of integration of frequency values regarding specific pixels on a predetermined scanning line (A), A radiation image information reading device characterized by comparing with a reference value () generated from a comparison reference data generating circuit (31). 7. The radiographic image information reading apparatus according to claim 1, wherein the analysis processing unit (3) has two pixels relating to pixels having a specific gradation value on a predetermined scanning line (A). A radiation image information reading device characterized by comparing the difference value (Δ) of the above frequency values with the reference value () generated from the comparison reference data generating circuit (31). 8. The radiation image information reading apparatus according to claim 1, wherein the analysis processing unit (3) is a frequency value regarding pixels having a specific gradation value on a predetermined scanning line (A). Maximum value of (M
AX), minimum value (MIN), and the comparison reference data generation circuit (31)
A radiation image information reading device characterized by comparing with a reference value () generated from the radiation image information reading device. 9. The above-mentioned claims 1, 2, 3, 4, 5, 6, 7,
Alternatively, in the radiographic image information reading apparatus described in 8, the pixels on a predetermined scanning line (A) are extracted from one or both of a continuous region or an intermittent region. Radiation image information reading device. 10. The above-mentioned claims 1, 2, 3, 4, 5, 6,
7. The radiographic image information reading device described in 7, 8, or 9, wherein the target scanning line (A) is selected from one or both of a main scanning line and a sub-scanning line. Radiation image information reading device.