JP2000321690A - Geometrical dimension specified method of radiation image reader, cassette for geometrical dimension inspection and geometrical dimension inspection apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable the easy inspection of geometrical dimensions with good accuracy by inspecting the geometrical dimensions of an image reader from the known geometrical dimensions with respect to a mark and the geometrical dimensions on the read image on the mark. SOLUTION: An image data calculation section calculates the positions of the respective parallel lines of the parallel line patterns Q on the read images corresponding to the parallel lines 28a to 28c a 28d to 28g of a cassette 29. A position information acquisition section reads the image data of the geometrical dimension information 29 on the read images, records the data on the irradiation surface of the cassette 20 and knows the positions of the respective straight lines of the parallel lines on the images formed on a phosphor sheet P and the spacings between the straight lines. An image inspection section carries out the inspection of the geometrical dimensions of the read images by comparing the positions of the respective straight lines of the parallel line patterns Q and the spacings between the straight lines on the resulted read images, and the positions of the respective straight lines on the images formed on the phosphor sheet P obtained in the position information acquisition section and the spacings between the straight lines.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention belongs to the technical field of radiation image reading used for radiation diagnosis and the like.
The present invention relates to an inspection method for inspecting geometric dimensional accuracy of image reading by a radiation image reader, and a geometric dimensional inspection cassette and a geometric dimensional inspection apparatus suitably used for the inspection.

[0002]

2. Description of the Related Art A radiation diagnostic system using a stimulable phosphor, such as FCR (Fuji Computed Radiography), has been put to practical use.

[0003] A stimulable phosphor (stimulable phosphor) means that when irradiated with radiation (X-ray, α-ray, β-ray, γ-ray, electron beam, ultraviolet ray, etc.), a part of the radiation energy is emitted. Accumulate,
Thereafter, when the phosphor is irradiated with excitation light such as visible light,
It is a phosphor that shows stimulated emission according to the stored energy. In the radiation diagnostic system using the stimulable phosphor, a radiation image of a subject such as a human body is recorded on a sheet having a stimulable phosphor layer (hereinafter, referred to as a phosphor sheet), and the phosphor sheet is excited by excitation light. Scans two-dimensionally to generate stimulated emission light, and photoelectrically reads the stimulated emission light to obtain an image signal. Based on the image signal, the radiation of the subject is displayed on a photographic photosensitive material or a display device such as a CRT. Output an image as a visible image (JP-A-55-12429, JP-A-56-1)
No. 1395).

Further, a system using a stimulable phosphor has many advantages, and is considered to be used not only in the field of medical diagnosis but also for flaw detection inspection of industrial products.
For example, if a transmitted radiation image such as a round bar or a steel pipe is reproduced in the same manner as above, the damaged portion has a lower radiation absorptivity than the other portions, and in the reproduced image, becomes darker than the surroundings. In addition, a damaged portion that cannot be observed from the outside can be detected.

[0005] In order to perform proper diagnosis and inspection using such a radiation image system, a radiation image read by an image reader must be free from deviations in image size and image position, image distortion and bending. That is, it is important that the geometrical dimensional accuracy of the read radiation image is appropriate. Therefore, various methods for inspecting the geometric dimensions of image reading in a radiation image reader have been proposed.

For example, in the specification of European Patent No. 0710013B1, a phosphor sheet on which a phantom image in which a ruler (ruler) which does not transmit X-rays is provided at equal intervals is recorded and which is read by scanning exposure is read. A method of detecting a geometric distortion of image reading from a ruler interval and an actual ruler interval is disclosed. Also,
Japanese Patent Application Laid-Open No. 8-171153 discloses that a phosphor sheet having a test pattern which cannot be erased permanently is scanned and exposed and read to test various parameters of a read image obtained by a reading device. A method is disclosed.

[0007]

However, in a method of recording a phantom image on a phosphor sheet, a plurality of rectangular metal pieces, such as aluminum, for weakening X-rays, such as aluminum, are arranged in parallel on a rectangular base that transmits X-rays. A special phantom attached must be used, and it must be accurately positioned at a predetermined position for inspection of geometric dimensions, and recorded on a phosphor sheet in consideration of the magnification of the image. However, the recording method is complicated, and there is a problem that a phantom image cannot be obtained with high accuracy.

In the method of inspecting the geometrical dimensions of a read image using a phosphor sheet having a test pattern that cannot be permanently erased, a test pattern that is not permanently erased is used separately from a phosphor sheet that is usually used. However, there has been a problem that a simple inspection cannot be performed because the inspection phosphor sheet having the above problem must be provided exclusively.

Further, when a read image is obtained by an image reader,
Since the direction of conveyance is changed while bending the phosphor sheet in the image reader, the phosphor sheet undergoes physical deformation such as bending deformation. Therefore, during repeated use, deterioration occurs due to this physical deformation, for example,
Cracks may occur on the phosphor sheet surface. In the above-mentioned phosphor sheet dedicated to inspection, patterns such as cracks are also formed as patterns on the read image, so there is a risk that accurate inspection may be hindered during repeated use. It was necessary to prepare a new storage phosphor sheet.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems of the prior art, and is not permanently erased when the geometric dimensions of an image reader are inspected by a radiation image system such as a radiation diagnostic system. Abstract: A radiation image geometric dimension inspection method, a geometric dimension inspection cassette, and a geometric dimension inspection apparatus capable of easily and accurately inspecting a geometric dimension without using a dedicated phosphor sheet having a test pattern. To provide.

[0011]

According to a first aspect of the present invention, a radiation recording medium for generating a radiation image is housed in a cassette and irradiated with radiation. Upon generating an image and performing image reading with an image reader, a mark having a known geometric dimension on the image, which is generated as an image on the radiation recording medium, is recorded in advance on a radiation irradiation surface of the cassette. The recorded mark is recorded as an image on the radiation recording medium by irradiation of radiation to obtain a read image of the mark, and the geometric dimensions and the geometrical shape on the read image of the mark are obtained with respect to the mark. A method for inspecting a geometric dimension of a radiation image reader, wherein the geometric dimension of the image reader is inspected from the dimensions.

At this time, it is preferable that a distance from a predetermined position of the mark or an interval between the marks in a case where there are a plurality of marks is known as a geometric dimension of the mark. Preferably, the geometrical dimension of the mark depending on the cassette is displayed on the cassette, or information on the geometrical dimension of the mark depending on the cassette is displayed together with the mark on the irradiation surface. Is recorded in the cassette, the information on the geometric dimensions is formed on the read image together with the mark recorded as an image on the radiation recording medium by using the cassette on which the information is recorded. The information about the geometric dimensions is automatically recognized by the information acquisition means to obtain the geometric dimensions of the mark, and the geometric dimensions are obtained from the known geometric dimensions and the corresponding geometric dimensions of the read image. It is preferred to check the dimensions. Further, it is preferable that the mark is a straight line, and a parallel line pattern is formed by a plurality of straight lines drawn in parallel. Further, it is preferable that the radiation recording medium is fixed at a predetermined position in the cassette to record an image.

[0013] In addition, the inspection of the geometrical dimension is performed on the radiation recording medium, which is recorded near an end in the main scanning direction or the sub-scanning direction of an image generated on the radiation recording medium at the time of image reading. Using two marks on the image to be scanned in which the interval in the main scanning direction or the sub scanning direction is known,
From the interval between these marks and the interval between the corresponding marks on the read image, an inspection of the overall reduction ratio for inspecting the entire length of the read image in the main scanning direction or the sub-scanning direction, and an inspection performed on the radiation recording medium is performed. Using at least two marks having a known interval in the main scanning direction or the sub-scanning direction on an image to be read, and determining the main scanning of the read image from the interval between these marks and the interval between the corresponding marks on the read image. Inspection of the partial contraction rate for inspecting the partial length in the direction or the sub-scanning direction, and the mark recorded on the radiation recording medium whose absolute position on an image generated on the radiation recording medium is known. Inspection of an image position for inspecting a geometric position of the image from the mark and a position of the mark on the read image corresponding to the mark, and the main scanning of an image generated on the radiation recording medium Using the mark lying parallel to the direction or sub-scanning direction, and a position of the point corresponding to the point of a point and read image is ideally a straight line connecting the marks,
Inspect the image for curvature, or if the mark is a straight line, examine the curvature of the straight line on the read image corresponding to this straight line, inspect the image for curvature in the read image, and inspect the radiation Using the mark positioned parallel to the main scanning direction or the sub-scanning direction of the image generated on the medium, reading the mark corresponding to the distance from the end of the image generated on the radiation recording medium and the mark The inclination of the image is inspected from the distance from the end of the image, or, when the mark is a straight line, the inclination of the straight line of the read image corresponding to this straight line is examined, and the inclination of the image in the read image is inspected. It is preferable that at least one inspection is selected from the inspection of the image inclination.

According to a second aspect of the present invention, there is provided a housing for accommodating a radiation recording medium and having an irradiation surface for receiving radiation, a radiation recording surface of the housing for recording the radiation, Another object of the present invention is to provide a cassette for geometric dimension inspection, wherein a geometric dimension on an image generated on a recording medium has a known mark.

In this case, it is preferable that the geometric dimension of the mark is a distance from a predetermined position of the mark or an interval between the marks in a case where there are a plurality of marks, and depends on the cassette. Preferably, the geometric dimensions of the mark are displayed on the cassette,
Alternatively, it is preferable that information on a geometric dimension of the mark depending on the cassette, which is recorded as an image on the radiation recording medium by irradiation of radiation, is recorded on the irradiation surface together with the mark.
Preferably, the mark is a straight line, and forms a parallel line pattern by a plurality of straight lines drawn in parallel. Further, it is preferable that the cassette is provided with positioning means for fixing the radiation recording medium at a predetermined position in the cassette when irradiating radiation to record an image.

According to a third aspect of the present invention, there is provided an image inspection apparatus for inspecting geometric dimensions of an image reader for scanning and reading an image generated by irradiating a radiation recording medium contained in a cassette with radiation. An apparatus, using a cassette in which the geometric dimensions on an image generated on the radiation recording medium are previously recorded on the irradiation surface of the cassette, to obtain an image recorded on the radiation recording medium, For a read image obtained by performing scanning reading from the obtained image, information that the geometric dimensions on the image of the mark are known,
From the corresponding geometric dimensions on the read image, an inspection of the overall reduction ratio for inspecting the entire length of the read image, an inspection of the partial reduction ratio for inspecting the partial length of the read image, and the read image Inspection of an image position for inspecting a geometric position of the image, inspection of an image curvature for inspecting image curvature in a read image, and inspection of an image inclination for inspecting image inclination are performed. A geometric dimension inspection device for a radiation image reader, comprising geometric dimension inspection means.

Here, when the information about the geometric dimension on the image of the mark recorded on the irradiation surface of the cassette together with the mark is formed in the read image, the geometric dimension is calculated from the information about the geometric dimension. It is preferable that the image reader is provided with information acquiring means for automatically reading and making the geometric dimensions of the mark known.

[0018]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of an image inspection apparatus for carrying out a method for inspecting geometrical dimensions of a radiographic image according to the present invention; This will be described in detail.

FIG. 1 shows an outline of an example of a radiation image geometric size inspection system using a phosphor sheet using a stimulable phosphor, which is suitable for implementing the radiation image geometric size inspection method of the present invention. .

A geometric inspection system 1 shown in FIG.
Reference numeral 0 denotes a geometric dimension inspection cassette 20 containing a radiation recording medium for generating a radiation image, and a geometric dimension of the radiation image obtained by scanning and reading an image generated on the radiation recording medium with excitation light to obtain a read image. An image reading device 30 to be inspected, an image processing device 50 for performing predetermined processing on image data obtained by the image reading device to obtain a digital image and performing various image processing, and an obtained image reading device And a monitor 70 that outputs a read image as an image and outputs the inspection result of the geometric dimensions.

The cassette 20 for geometrical dimension inspection (hereinafter, referred to as a cassette 20) shown in FIG. 2 captures a radiation image in a state where the phosphor sheet P is housed in the same manner as a normal cassette for photography. Thereafter, the fluorescent sheet P is loaded into the image reader 30 in a state of being stored. The phosphor sheet P on which the image has been taken is taken out of the cassette 20 in the image reader 30, and is used for reading a radiation image. Such a cassette 20 basically has an irradiation surface 22 that transmits radiation (the lower surface side in FIG. 2),
It has a housing 24 for storing the phosphor sheet P, and a lid 26 of the housing 24.

The housing 24 and the lid 26, that is, the main body of the cassette are basically the same as those of a cassette for storing a radiation recording medium such as a phosphor sheet P or an X-ray film, which is used in an ordinary radiation imaging system. Well, except for the irradiation surface 22 described below, for example, various resins, metals such as aluminum, etc., are formed from various known materials, and the lid 26 is formed by a known means such as a hinge. One side is configured to be openable and closable in the arrow direction in the figure. Both may be constituted by separate members, or may be constituted by integrally molding resin or the like so that the lid 14 can be opened and closed in the direction of arrow a.

In the cassette for geometric dimension inspection according to the present invention, the main body of the cassette is not limited to the configuration shown in the illustrated example, and various configurations corresponding to the radiation image system in which the cassette 20 is used may be used. It is possible.

As shown in FIG. 3, an excitation light is scanned in one direction by an image reader 30 described later on the irradiation surface 22 of the cassette 20 so that the phosphor sheet P accommodated in the cassette 20 is scanned. Main scanning direction for reading (direction of arrow x in the figure)
And a grid-like parallel line pattern Q composed of a plurality of parallel lines 28a to 28c and 28d to 28g drawn in parallel at equal intervals in the same direction as the sub-scanning direction (the direction of the arrow y in FIG. Are recorded on the phosphor sheet P accommodated in the cassette 20 by the irradiation of radiation.
Parallel lines 2 corresponding to 8a-28c and 28d-28g
8a 'to 28c' and 28d 'to 28g'. Note that the intervals between parallel lines in the main scanning direction (the direction of the arrow x in the drawing) and the sub-scanning direction (the direction of the arrow y in the drawing) do not necessarily need to be the same. In the cassette 20 shown in FIG. 3, the grid pattern is a parallel line pattern Q, but the pattern is not limited to the grid pattern, and may be in one direction, for example, the main scanning direction (the direction of the arrow x in FIG. 3) or the sub-scanning direction (in the figure A parallel line pattern only in the direction of the arrow y) may be used.

On the other hand, on the lower right side of the irradiation surface 22 of the cassette 20 shown in FIG.
Information on the positions of the parallel lines 28a 'to 28c' and 28d 'to 28g' on the image generated on the phosphor sheet P corresponding to d to 28g, for example, the distance from the end of the image on the phosphor sheet P, Alternatively, the parallel lines 28a 'to 28c' and 28d 'to
Geometric dimension information 29 relating to the geometric dimension of the interval between the parallel lines of 28 g 'is recorded in the form of a bar code, and the parallel line pattern Q is applied to the phosphor sheet P housed in the cassette 20 by irradiation of radiation. And recorded as an image. The positions of the parallel lines and the intervals between the parallel lines obtained based on the geometric dimension information 29 are determined by the positions of the parallel lines and the parallel lines of the parallel line pattern Q on the image actually generated on the phosphor sheet P. Equivalent to line spacing.

The geometric dimension information 29 includes a parallel line 28a '.
28c 'and 28d' to 28g 'only, or parallel lines 28a' to 28c 'and 28d' to 2
Only the information on the interval between the parallel lines of 8g 'may be used.
Note that the pattern information is not limited to the barcode format, but may be a number, a code, or the like. In the example shown in the figure, the geometric dimension information 29 is located on the lower right side of the irradiation surface 22. However, the present invention is not limited to this. There may be. Instead of the geometrical dimension information 29, the position of the parallel line of the parallel line pattern Q or the value of the interval between the parallel lines may be directly described by a number, a character, a code, or the like. And directly read the numbers, characters, codes, etc. of the geometric dimension information 29 from the image inspection apparatus 6 described later.
0 may be input using a keyboard or a mouse. In this case, the irradiation surface 22 is not necessarily
Need not be written on the surface of the cassette 20, for example, may be written on the surface or side surface of the cassette 20 opposite to the irradiation surface 22.

The positions of the parallel lines and the intervals between the parallel lines directly written on the geometrical dimension information 29 or the cassette 20 recorded on the phosphor sheet P of the lattice-shaped parallel line pattern Q are determined by the phosphor sheet. The position of each parallel line and the interval of each parallel line actually generated in P are displayed for each cassette, so that variations in geometrical dimensions at the time of image reading by the cassette can be suppressed.

The irradiation surface 22 of the cassette 20 is
Since it is formed of a carbon resin that transmits radiation, for example, X-rays, when X-rays are irradiated, the amount of X-rays transmitted is reduced and an image of the parallel line pattern Q and the geometric dimension information 29 is generated on the phosphor sheet P. A parallel line pattern Q and geometrical dimension information 29 can be recorded on the irradiation surface 22 of the cassette 20 by partially mixing a material such as a metal such as lead or aluminum into a carbon resin. Also, a material that reduces the amount of X-ray transmission,
For example, a thinned alloy of lead or aluminum may be attached or fitted. Further, a material having good radiation transmission is used for the parallel line pattern Q and the geometric dimension information 29, and the other radiation surface 22 of the cassette 20 is made of a material having low radiation transmission. The physical dimension information 29 may be recorded as an image.

Further, in the present invention, the parallel line pattern Q
There is no particular limitation on the thickness of the line in the geometrical dimension information 29, but the thinner the line, the higher the accuracy of the inspection, but the more difficult it is to detect the line, which is disadvantageous in terms of work efficiency. It may be appropriately determined according to the required inspection accuracy, the spatial resolution of the image reader, and the like. Further, instead of the parallel line pattern Q composed of a plurality of parallel straight lines, for example, the main scanning direction (the direction of the arrow x in the drawing) and the sub-scanning direction ( A mark such as a point or a cross may be recorded on the irradiation surface 22 of the cassette 20 so that an opposite point or a mark such as a cross which is parallel to the direction of the arrow y in FIG. . That is, in the present invention, the actual cassette 2
Various marks can be used as long as the position on 0 and the position on the read radiation image can be detected in association with each other.

As shown in FIG. 4, positioning means 27a for fixing the phosphor sheet P exactly along the reference planes A ₁ and A ₂ of the cassette 20 are provided on the cassette 20.
And 27b, and the phosphor sheet P is always
The parallel lines 28a to 28c and 28d to 28g recorded on the cassette 20 are always recorded at predetermined positions on the phosphor sheet P. Although the reference planes A ₁ and A ₂ in the figure are the lower bottom surface of the left side surface of the cassette 20, it is not limited to this, and may be, for example, the right side surface or the upper surface. Positioning means 27a and 27b are a phosphor sheet P well be any as long as it is fixed tightly along the reference plane A ₁ and A _2, the elastic member, for example a sponge or material such as rubber or a spring or the like You may. The number of the elastic members is two each, but is not limited to this, and may be one, three, or more. Further, in the positioning means of the present invention, it is not always necessary to position and fix the phosphor sheet P along the reference plane, and the phosphor sheet P is positioned at a predetermined position in the cassette 20 by a known means, for example, a hook (key hook) or the like. It may be fixed.

In the image reader 30, when the phosphor sheet P on which the radiation image is recorded is irradiated with the excitation light, the phosphor sheet P generates stimulated emission light in accordance with the accumulated and recorded radiation image, and the emitted light is converted into a photoelectric signal. Thus, it is possible to obtain read image data. That is, as shown in FIG. 5, the excitation light B is emitted from the light source 32, the beam diameter is expanded by the beam expander 34, and the light is deflected by a galvanometer mirror 36 or the like. Direction). The excitation light B scanned in the main scanning direction is
lens 38 forms an image at a predetermined reading position with a predetermined beam diameter.

On the other hand, the phosphor sheet P on which the radiation image has been stored is recorded by the sub-scanning conveyance means 40 composed of a roller and an endless belt, while the surface thereof is maintained at the reading position and the sub-scanning direction orthogonal to the main scanning direction. (Y in the figure
(In the direction of the arrow). As described above, since the excitation light B is scanned in the main scanning direction, the phosphor sheet P conveyed in the sub-scanning direction is consequently two-dimensionally scanned by the excitation light B. .

From the position of the phosphor sheet P scanned by the excitation light B, stimulated emission light corresponding to the radiation image stored and recorded is emitted. The stimulated emission light is propagated by the light guide 42, components other than the stimulated emission light are removed by a filter (not shown), and read photoelectrically by a photomultiplier (photomultiplier) 44. The image data read photoelectrically is sent to the image processing device 50.

In the image processing device 50, an output signal from the photomultiplier 44 is output from the image reader 30 as an image signal of a radiation image, is sampled at a predetermined pixel clock frequency, and is amplified, corrected for shading, and corrected for dark time. , Log conversion, A / D conversion (analog / digital conversion), anti-aliasing processing, and the like, are performed to obtain digital image data of the radiation image. This image data is subjected to various types of image processing such as gradation correction, sharpness processing, and contrast correction that do not change the geometric dimensions as necessary. The obtained image data is processed by the image inspection device 60. Sent to If necessary, the image data before the image processing and the image data after the image processing are sent to the monitor 70, and the read image before or after the image processing is displayed.

As shown in FIG. 6, the image inspection device 60 obtains a read image from an image in which the parallel line pattern Q and the geometric dimension information 29 are stored and recorded on the phosphor sheet P, and obtains the geometric dimension of the read image. This is an inspection device for performing an inspection, and the parallel lines 28a to 28c and 28d to 2d of the cassette 20 shown in FIG.
The image data position calculator 62 calculates the positions of the parallel lines 82a to 82c and 82d to 82g of the parallel line pattern Q on the read image 80 corresponding to 8g, and the image data of the geometric dimension information 29 on the read image. The position which is read and recorded on the irradiation surface 22 of the cassette 20 and which knows the position of each straight line of the parallel lines 28a 'to 28c' and 28d 'to 28g' and the interval between the straight lines on the image generated on the phosphor sheet P Information acquisition unit 64
And the position of each straight line of the parallel line pattern Q on the obtained read image and the interval between the straight lines, and the position of each straight line on the image generated on the phosphor sheet P obtained by the position information acquisition unit 64 And an image inspection unit 66 for inspecting the geometric dimensions of the read image by comparing the intervals between the straight lines. Further, the image inspection device 60 checks the position of each straight line that has extracted the parallel line pattern from the read image, and in some cases, the operator indicates the position of the geometric dimension information 29 on the read image, It is used to indicate a method of inspecting the geometric dimensions of an image, and is connected to a monitor 70 that displays the progress of the inspection.

The image data position calculator 62 calculates the parallel lines 82a to 82c forming the parallel line pattern Q from the gradation values of the image data of the read image 80 sent from the image processing device 50.
And 82d to 82g are automatically extracted, and the position of the image data is automatically calculated.

In the position information acquisition section 64, the area where the geometric dimension information 29 on the read image is located is known in advance.
The position of the geometric dimension information 29 is automatically searched for from the tone value of the image data of the read image in the area, and the geometric dimension information 29 displayed in a barcode format is decoded from the tone value of the image data. The position of each parallel line of the parallel line pattern Q on the image generated on the phosphor sheet P and the interval between the straight lines can be known from the decoded information. Since the position of the parallel line and the interval between the straight lines for each cassette can be known in this manner, the variation in the inspection result in the geometric dimension inspection due to the variation in the recorded parallel line pattern Q for each cassette is eliminated.

In the image inspection unit 66, the position of each parallel line of the parallel line pattern Q on the read image obtained by the image data position calculation unit 62 and the phosphor sheet P obtained by the position information acquisition unit 64 The geometric dimensions of the read image are inspected from the information on the positions and intervals of the parallel lines on the generated image. That is, the distance between the two straight lines of the read image, the position of the straight line, the bend and the inclination, and the position of each straight line on the image generated on the phosphor sheet P are checked according to the instruction of the operator on the monitor 70. The geometric dimensions of the read image are inspected by comparing with information such as intervals. The obtained inspection result is stored in a storage unit (not shown) of the image inspection device 60, displayed on the monitor 70, and printed out to a printer (not shown).

The geometric dimension inspection system 10 is configured as described above. Hereinafter, an example of a geometric dimension inspection method using this system will be described. In the example shown below, as the geometric dimension inspection, the total reduction ratio, the partial reduction ratio,
Although the inspection of the image position, the image bending, and the image inclination are exemplified, the present invention is not limited thereto.

When the geometrical dimension inspection of the image read by the image reader 30 is performed, for example, an instruction to perform the geometrical dimension inspection is issued to the apparatus by selecting a mode or the like, and the phosphor sheet P is positioned. The parallel line pattern Q and the geometric dimension information 29 recorded on the irradiation surface 22 of the cassette 20 are fixed to the predetermined position in the cassette 20 by the means 27a and 27b, and the phosphor sheet P is irradiated with X-rays. After the accumulation and recording, the image is loaded into a predetermined position of the image reader 30 while being inserted into the cassette 20. In response to an instruction to start reading, the cassette 20 moves the phosphor sheet P
Are taken out, and the phosphor sheet P is conveyed to the sub-scanning conveyance means 40, and while being conveyed in the sub-scanning direction by the sub-scanning conveyance means 40, the entire surface is two-dimensionally excited by the excitation light B deflected in the main scanning direction. Scanned.

From the position of the phosphor sheet P scanned by the excitation light B, stimulated emission light is generated in accordance with the degree to which the image of the parallel line pattern Q and the geometric dimension information 29 is stored and recorded. The stimulated emission light is propagated by the light guide 42, read by the photomultiplier 44, and sent to the image processing device 50. In the image processing device 50, the output signal output from the image reader 30 is subjected to processing such as amplification, shading correction, darkness correction, Log conversion, A / D conversion (analog / digital conversion), and anti-aliasing processing. These are used as digital image data of the radiation image. Thereafter, image processing such as gradation processing and frequency processing may be performed. Here, since an image of the parallel line pattern Q and the geometric dimension information 29 is recorded on the phosphor sheet P, the parallel line pattern Q and the geometric dimension information 29 are formed on the read image after the image processing. Is done. The obtained image data after the image processing is sent to the image inspection device 60.

The sent image data of the read image 80 is converted by the image data position calculator 62 into parallel lines 82a 'to 8a'.
2c 'and 82d' to 82g 'are automatically extracted and calculated. That is, by extracting image data in which the tone value of the image data continuously exceeds the set threshold value from the image data of the read image 80, the parallel lines 82a 'to 82c' 82d '~ 82
g ′ is automatically extracted and calculated. At this time, the operator may determine the threshold value of the gradation value according to the contrast of the read image, and may set the threshold value based on the histogram of the image data or the statistical property of the read image such as the maximum value / minimum value. It may be set automatically. Even when the mark is a point or a cross, the position is calculated in the same manner. The position of an unnecessary parallel line need not be calculated according to the geometric dimension inspection to be performed. Further, in the image data position calculation unit 62, the parallel lines 82a ′ to 82c ′ and 82d ′ to
The position of 82g 'may be specified while looking at the display screen of the read image.

The read image data is also sent to the position information acquisition section 64, and the position of the geometric dimension information 29 on the read image is automatically searched. Geometric dimension information 2 on read image
The position of the area 9 is known in advance, and the image data of the read image of the area is binarized by a certain threshold value as in the case of the parallel line pattern Q, and the geometric dimension information 29 is held. Image patterns can be extracted.

Since the found geometric dimension information 29 is displayed in a barcode format, the geometric dimension information 29 can be easily decoded from the gradation values of the image data. That is, after recognizing the geometric dimension information 29 composed of 0 or 1 bit, the information is decoded and the parallel line 28 is read.
The positions and intervals of a 'to 28c' and 28d 'to 28g' are known as numerical values. Thus, the parallel lines 28a 'to 28c' and 28d 'to 2 on the image generated on the phosphor sheet P
The position of 8g 'and the interval between parallel lines, for example, parallel line 28a'
And 28b 'and 28d' and 28e '. As described above, the position of the parallel line and the interval between the parallel lines depending on the cassette can be obtained, so that in the geometric dimension inspection described later, there is no variation in the inspection result due to the variation of the recorded parallel line pattern Q for each cassette.

Each parallel line of the parallel line pattern Q on the read image thus obtained (parallel line 82a shown in FIG. 7).
To 82c and 82d to 82g), the distance between parallel lines, and the phosphor sheet P obtained from the geometric dimension information 29.
Parallel lines 28a 'to 28c' and 2
The geometric dimensions of the read image are inspected from the positions of 8d 'to 28g' and the distance between the parallel lines. Inspection of the geometric dimensions of the read image includes enlargement / reduction of the length of the read image obtained by the image reader 30 in the main scanning direction and the sub-scanning direction, displacement of the read image with respect to the phosphor sheet P, and distortion of the read image. And inspections such as inclination and inclination, which occur when the image reader 50 reads an image. Therefore, by inspecting the geometric dimensions of the read image, the geometric dimensions of the image reader 30 are inspected. According to the inspection result, scanning conditions at the time of scanning, for example, main scanning pixels Clock frequency setting conditions and the like can be finely adjusted.

In the above-described inspection of the geometric dimensions, the position and the dimension on the read image 80 are obtained by the number of pixels (that is, the position of the pixel, the size of the pixel, etc.). The known position and dimension value on the surface of the cassette 20 are generally set in units of length such as centimeters. Therefore, a step of converting the number of pixels into a length or a step of converting the length into the number of pixels is required. This conversion is uniquely determined if the sampling density when reading the image and the enlargement ratio of the pixel density conversion applied to the read image are known. Information necessary for such conversion is input to an image inspection unit 66, which is a means for inspecting a geometric dimension as supplementary information of a read image, and the conversion is preferably performed using the information.

The inspection of such geometric dimensions is automatically performed as described below. Alternatively, the position of each parallel line may be displayed on the monitor 70, and the operator may perform the following inspection.

FIG. 7 shows a read image 80 illuminated using the cassette 20 and read by the image reader 30.
It is shown. In this read image, geometric dimension information 2
The read image for No. 9 is omitted. The inspection of the overall reduction ratio of the image reading in the main scanning direction, that is, the inspection of the entire length (size) of the image in the main scanning direction is performed on the phosphor sheet P recorded near the end of the phosphor sheet P in the main scanning direction. This can be performed by using two parallel lines having a known interval in the main scanning direction on the generated image. In the example of FIG.
Parallel line 8 in read image 80 corresponding to 8a 'and 28c'
2a and 82c, and as an example,
The number of pixels (the number of pixels) in the main scanning direction (the direction of the arrow x in the figure) at the same position in the sub-scanning direction (the direction of the arrow y in the figure) in the read image of the parallel lines 82a and 82c is obtained.
The distance (reading dimension) between the parallel lines 82a and 82c on the read image is calculated from the number of pixels and the pixel interval of image reading. Using this and the distance (reference dimension) between the parallel lines 28a 'and 28c' on the image generated on the phosphor sheet P acquired by the position information acquisition unit 64, the overall reduction ratio is calculated by the following equation. Do.

Similarly, the overall reduction ratio in the sub-scanning direction is determined by the interval in the main scanning direction on the image generated on the phosphor sheet P, which is recorded near the end of the phosphor sheet P in the main scanning direction. This can be done using two known parallel lines. In the illustrated example, this is performed using the parallel lines 82d and 82g, and similarly, the number of pixels of the parallel lines 82d and 82g at the same position in the main scanning direction (the direction of the arrow x in the figure) in the read image. , The reading dimensions of the parallel lines 82d and 82g are calculated, and the parallel lines 28d on the image generated on the phosphor sheet P acquired by the position information acquiring unit 64 are calculated.
Using d ′ and the reference size of 28 g ′, the overall reduction ratio is calculated by the following equation. Overall reduction ratio [%] = − [1− (read size / reference size)] ×
100

If the overall reduction ratio in the main scanning direction is inappropriate, the setting of the sampling frequency of the image data is changed, etc.
This can be dealt with by a method such as fine-tuning the main scan pixel clock frequency. If the overall reduction ratio in the sub-scanning direction is inappropriate, it can be dealt with by adjusting the rotational speed of the motor of the sub-scanning conveyance means 40 or the like.

The inspection of the partial reduction ratio (partial length) of the image reader may be basically performed in the same manner as the overall reduction ratio, and is performed in the main scanning direction on the image generated on the phosphor sheet P. Is performed using two parallel lines with known intervals. For example, in the main scanning direction, the parallel lines 28a 'to 28b', 28b 'to 28
Parallel lines 82a-82b, 82b-82c corresponding to c '
Are calculated, and the parallel lines 28a 'to 28-' on the image generated on the phosphor sheet P acquired by the position information acquisition unit 64 are calculated.
The partial shrinkage ratio is calculated using the reference dimensions 28b 'and 28b' to 28c '. Further, in the cassette 20 on which three or more parallel lines are recorded, the intervals between adjacent parallel lines on the read image may be obtained, and the partial reduction ratio at each position may be obtained. Note that the inspection of the partial reduction ratio is not limited to being performed between adjacent parallel lines. For example, in the sub-scanning direction, the parallel lines 82d 'to 28f' and 28e 'to 28g' correspond to the parallel lines 82d 'to 28d'. To 82f, 82e to 82g, or the like. The partial reduction ratio in the sub-scanning direction can also be obtained in the same manner as in the main scanning direction. If the partial reduction ratio in the main scanning direction is inappropriate, it can be dealt with by adjusting or exchanging the optical system, and if the partial reduction ratio in the sub-scanning direction is inappropriate, This can be dealt with by replacing the motor, replacing the sub-scanning and conveying means 40, and the like.

The inspection of the image position can be performed using an absolute position on the read image 80, for example, a straight line recorded on the phosphor sheet P whose distance from the end in the scanning direction or the sub-scanning direction is known. it can. In the illustrated example, for example, focusing on the parallel line 82a, the position of the parallel line 82a in the main scanning direction is determined based on the number of pixels from the reading start point (image starting point) in the main scanning direction in the read image to the parallel line 82a. The phosphor sheet P calculated and acquired by the position information acquiring unit 64
Inspection of the image position in the main scanning direction is performed in comparison with the position of the parallel line 28a 'on the image generated in the step (a). Also,
Inspection of the image position in the sub-scanning direction can be performed similarly. When the image position in the main scanning direction is not appropriate, it is possible to cope with the problem by adjusting the number of pixels to be seen off in the image reading, and when the image position in the sub-scanning direction is not appropriate, it is possible to adjust the number of lines to be seen off. it can. Further, when a positioning mechanism for storing the phosphor sheet P at a predetermined position is provided in the cassette 20, the positioning mechanism is finely adjusted to adjust the storage position of the phosphor sheet P stored in the cassette 20. Can be adjusted.

Inspection of image bending (distortion) can be performed using straight lines using parallel lines in the main scanning direction. For example, the curvature of the parallel line 82a of the read image is determined by taking predetermined points located at upper and lower ends on the parallel line 82a shown in FIG.
By measuring the distance at which a point located at the middle between the upper and lower ends on the line a is away from the virtual straight line, it is possible to inspect the curvature of the image in the main scanning direction. The inspection of the image bending in the sub-scanning direction can be similarly performed. If necessary, the image may be inspected for bending using a plurality of parallel lines. In the case where the mark recorded on the irradiation surface 22 is not a straight line but a point, for example, on an image generated on the phosphor sheet P, a point located in parallel with the scanning direction or the sub-scanning direction is used. A difference between a point on the ideal straight line to be connected and a position of a point corresponding to the point on the read image may be read to inspect the image for bending. The inspection of the image bending in the sub-scanning direction can be similarly performed. If the image is bent in the sub-scanning direction due to adjustment or replacement of the optical system if the image is bent in the main scanning direction, if the image is bent in the sub-scanning direction, the Each can be dealt with by exchange or the like.

The inspection of the image inclination can be performed by examining the inclination of a straight line in the main scanning direction or the sub-scanning direction using parallel lines, and examining the image inclination in the read image. For example, in the same manner as in the above-described example, the inclination in the main scanning direction can be inspected by examining the inclination of the parallel line 82a in the read image from the positions of both ends on the parallel line 82a. When the mark recorded on the irradiation surface 22 is not a straight line but a point, for example, two points parallel to the main scanning direction or the sub-scanning direction of the image generated on the phosphor sheet P are noted. By calculating the corresponding position on the read image and determining the inclination of the virtual straight line connecting these two points, the inclination in the main scanning direction can be inspected. In this case, the two points used are not limited. If the image is tilted in the main scanning direction, if the image is tilted in the sub-scanning direction due to adjustment or replacement of the optical system, etc. Each can be dealt with by exchange or the like.

The result of such a geometric inspection can be automatically performed, and the variation of the inspection result due to the position and the variation of each parallel line for each cassette is automatically corrected. The result of the inspection is displayed on the monitor 70 and output as a hard copy. Alternatively, for those that can be adjusted, such as fine adjustment of the pixel clock frequency and adjustment of the rotation speed of the motor of the sub-scanning conveyance means 20,
The image reader 30 may automatically perform the adjustment according to the result of the inappropriateness. Further, means for performing the above-described inspection of the geometric dimensions may be provided in the image reader, so that the steps from the image reading to the inspection may be performed automatically, and the steps up to the adjustment may be performed automatically. Good.

Although the method for inspecting geometric dimensions of a radiographic image, the cassette for inspecting geometric dimensions, and the apparatus for inspecting geometric dimensions according to the present invention have been described in detail above, the present invention is not limited to the above-described embodiment. Of course, various improvements and changes may be made without departing from the spirit of the invention.

[0057]

As described above in detail, according to the present invention, the entire reduction ratio, the partial reduction ratio, the image position, the image distortion, and the image inclination of the read image obtained by the radiation image reader are obtained. When performing various geometric dimension inspections such as, a mark having a known geometric dimension on an image generated on a radiation recording medium is recorded using a geometric inspection cassette which is recorded in advance on a radiation irradiation surface. After recording the mark as an image on a radiation recording medium such as a phosphor sheet by irradiating the radiation, a read image of the mark can be obtained, and thus a dedicated phosphor sheet for inspection having a test pattern that does not disappear permanently. A conventional phosphor sheet for radiography can be used without using a radiation recording medium such as the one described above. Ku, can be inspected accurately geometric dimensions more easily. Also, since the cassette does not deteriorate like the phosphor sheet, there is no need to replace it with a new cassette, and if the phosphor sheet deteriorates, it is not a phosphor sheet dedicated to inspection but is usually used. It is only necessary to prepare a phosphor sheet for radiation imaging to be performed. Furthermore, since the image reader can be fine-tuned according to the test results, accurate diagnosis using high-precision images can be performed stably, for example, by using this test method in a radiology medical system. become.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating an outline of a geometric dimension inspection system including a geometric dimension inspection apparatus that performs a geometric dimension inspection method of a radiation image reader according to the present invention.

FIG. 2 is a perspective view showing an example of a cassette for inspecting geometric dimensions of the radiation image reader according to the present invention.

FIG. 3 is a plan view showing an irradiation surface of the cassette for geometric dimension inspection shown in FIG. 2;

FIG. 4 is a cross-sectional view of the cassette for explaining the positioning means provided in the cassette for geometric dimension inspection of the present invention.

FIG. 5 is a schematic view of a preferred example of a radiation image reader used when carrying out the geometrical dimension inspection method of the radiation image reader according to the present invention.

FIG. 6 is a block diagram showing an outline of a geometric dimension inspection apparatus for a radiation image reader according to the present invention.

FIG. 7 is an explanatory diagram showing an example of a read image obtained by the geometrical dimension inspection method of the radiation image reader according to the present invention.

[Explanation of symbols]

Reference Signs List 10 geometric dimension inspection system 20 geometric dimension inspection cassette 22 irradiation surface 24 housing 26 lid 27a, 27b positioning means 28a to 28g, 28a 'to 28g', 82a to 82g
Parallel line 29 Geometric dimension information 30 Image reader 32 Light source 34 Beam expander 36 Galvanometer mirror 38 fθ lens 40 Sub-scanning conveyance means 42 Light guide 44 Photomultiplier 50 Image processing device 60 Image inspection device 62 Image data position calculation unit 64 Position information acquisition unit 66 Image inspection unit 70 Monitor

Claims (15)

[Claims] 1. A radiation recording medium for generating a radiation image is housed in a cassette, irradiated with radiation, an image is generated on the radiation recording medium, and an image is read by an image reader. A mark having a known geometric dimension on the image, which is generated as an image, is recorded in advance on a radiation irradiation surface of the cassette, and the recorded mark is formed as an image on the radiation recording medium by irradiation of radiation. Recording, obtaining a read image of the mark, and inspecting the geometric size of the image reader from the geometric size known for the mark and the geometric size on the read image of the mark. Inspection method for geometric dimensions of radiation image readers. 2. The radiographic image reading apparatus according to claim 1, wherein the mark has a known geometrical distance from a predetermined position of the mark or an interval between the marks when there are a plurality of marks. Machine geometric dimension inspection method. 3. The method according to claim 1, wherein a geometric dimension of the mark dependent on the cassette is displayed on the cassette. 4. The information relating to the geometric dimension of the mark depending on the cassette is recorded on the irradiation surface together with the mark, and the information relating to the geometric dimension is obtained by using the cassette in which the information is recorded. Forming the read image together with the mark recorded as an image on the radiation recording medium, automatically recognizing information on the geometric dimensions formed on the read image by information acquisition means, The geometrical dimension of the radiation image reader according to claim 1, wherein the geometrical dimension is obtained, and the geometrical dimension is inspected from the known geometrical dimension and the corresponding geometrical dimension of the read image. Inspection methods. 5. The mark is a straight line, and a parallel line pattern is formed by a plurality of straight lines drawn in parallel.
5. The method for inspecting geometric dimensions of a radiation image reader according to any one of claims 4 to 4. 6. The method according to claim 1, wherein the radiation recording medium is fixed at a predetermined position in the cassette and an image is recorded on the radiation recording medium. 7. The inspection of the geometric dimensions is performed on the radiation recording medium, which is recorded near an end in the main scanning direction or the sub-scanning direction of an image generated on the radiation recording medium at the time of image reading. Using two marks having a known interval in the main scanning direction or the sub-scanning direction on the image to be read, and determining the interval in the main scanning direction or the Inspection of the overall reduction ratio for inspecting the entire length of the read image in the scanning direction, and at least two marks having a known interval in the main scanning direction or the sub-scanning direction on an image generated on the radiation recording medium. Inspection of a partial shrinkage ratio for inspecting a partial length of the read image in the main scanning direction or the sub-scanning direction from the intervals of the marks and the intervals of the marks on the read image corresponding to the radiation recording. Medium Using the mark recorded on the radiation recording medium whose absolute position on the image to be generated is known, the geometrical position of the image is determined from the mark and the position of the mark on the read image corresponding to the mark. Inspection of the image position to inspect the position, using the mark located parallel to the main scanning direction or the sub-scanning direction of the image generated on the radiation recording medium,
From the point on the ideal straight line connecting this mark and the position of the point corresponding to the point on the read image, inspect the image for curvature,
Alternatively, in the case where the mark is a straight line, an inspection of a straight line on the read image corresponding to the straight line is performed, and an image bend inspection for inspecting an image bend in the read image is performed. Using the mark positioned parallel to the main scanning direction or the sub-scanning direction,
From the distance of the mark from the end of the image generated on the radiation recording medium and the distance from the end of the read image corresponding to the mark, check the inclination of the image, or if the mark is a straight line 7. The inspection according to claim 1, wherein at least one inspection is selected from an image inclination inspection for examining an inclination of a straight line of the read image corresponding to the straight line and inspecting an image inclination in the read image. 7. The method for inspecting geometric dimensions of a radiation image reader according to claim 1. 8. A housing for housing a radiation recording medium and having an irradiation surface for receiving radiation, and an image recorded on the irradiation surface of the housing and generated on the radiation recording medium by the irradiation of radiation. A cassette for inspecting geometric dimensions, wherein the cassette has a mark whose geometric dimensions are known. 9. The cassette for geometric dimension inspection according to claim 8, wherein the geometric dimension of the mark is a distance from a predetermined position of the mark or an interval between the marks when there are a plurality of the marks. . 10. The cassette for geometric dimension inspection according to claim 8, wherein a geometric dimension of the mark depending on the cassette is displayed on the cassette. 11. Information relating to a geometric dimension of the mark depending on the cassette, the information being recorded as an image on the radiation recording medium by irradiation of radiation is recorded on the irradiation surface together with the mark. Claim 8
The cassette for geometrical dimension inspection according to any one of claims 10 to 10. 12. The cassette according to claim 8, wherein said mark is a straight line and forms a parallel line pattern by a plurality of straight lines drawn in parallel. 13. The cassette according to claim 8, wherein said cassette is provided with a positioning means for fixing said radiation recording medium at a predetermined position in said cassette when irradiating radiation to record an image.
13. The cassette for geometric dimension inspection according to any one of 12). 14. An image inspection apparatus for inspecting geometric dimensions of an image reader for scanning and reading an image generated by irradiating a radiation recording medium contained in a cassette with radiation, wherein said radiation recording medium is Using a cassette in which the geometric dimensions on the image generated in advance are already known on the irradiation surface of the cassette, an image recorded on the radiation recording medium is obtained, and scanning and reading are performed from the obtained image. For the read image obtained by performing the scanning, the overall size of the entire read image is inspected from the information on the known geometric size of the mark on the image and the corresponding geometric size on the read image. Inspection of ratio, inspection of partial reduction to inspect partial length of scanned image, inspection of image position to inspect geometrical position of scanned image, and inspection of image bending in scanned image image Rising inspection, and image geometric dimensional inspection apparatus of the radiation image reading apparatus characterized by having a geometric dimension inspecting means for performing at least one test of the test image slope for inspecting the slope of the. 15. When information about a geometric dimension on an image of the mark recorded on the irradiation surface of the cassette together with the mark is formed in the read image, the information about the geometric dimension is automatically read. 15. The geometric dimension inspection apparatus for a radiation image reader according to claim 14, wherein information acquisition means for making known the geometric dimension of the mark is provided in the image reader.