JP6843544B2 - Radiation imaging equipment, radiography systems, radiography methods, and programs - Google Patents

Description

The present invention relates to a radiographic apparatus for photographing radiological images, a radiological imaging system, a radiological imaging method, and a program.

In the medical field in recent years, photography in a wide observation area (hereinafter referred to as long photography) such as photographing the entire spinal cord and lower limbs of the subject or the whole body of the subject has been performed. Patent Document 1 discloses a radiographic imaging system capable of performing long-length imaging by arranging a plurality of radiological detectors (radiographing apparatus) for imaging. The plurality of radiation detectors output radiation data based on the radiation incident on each of them, convert it into a plurality of image data, and then combine them to generate a long image.

On the other hand, in radiography, in order to prevent irradiation of the part of the subject who is not related to diagnosis, a radiation shielding substance such as a lead plate is installed as an irradiation field diaphragm in the radiation generating part. This irradiation field aperture sets the irradiation field area of radiation at the time of radiography, and in the generated radiation image, the area irradiated with radiation (irradiation field) and the area shielded by radiation (shielded field) are displayed. Give rise. Further, Patent Document 2 describes that the irradiation field recognition is performed based on the input information regarding the shape of the irradiation field candidate region.

Japanese Unexamined Patent Publication No. 2012-040140 Japanese Unexamined Patent Publication No. 2005-218581

However, even in long-length photography, the irradiation field area is set by the irradiation field diaphragm, but since a long image is generated by synthesizing a plurality of image data, it takes a processing time to align the image data. Therefore, it is difficult to quickly recognize the irradiation field of a long image.

The radiography apparatus according to the present invention comprises a first image generation means for generating a plurality of partial images obtained by irradiating radiation detection units arranged at spatially different positions with radiation, and the plurality of partial images. Based on the extraction means for extracting contour candidates of the irradiation field, the calculation means for calculating the relative positional relationship of the plurality of partial images, and the relative positional relationship, the partial images are combined to generate a long image. A second image generation means and a specific means for identifying the irradiation field of the long image from the contour candidate based on the relative positional relationship are provided.

According to the present invention, irradiation field recognition in a long image can be performed quickly.

It is a figure which shows the schematic structure of the radiography system to which the embodiment which concerns on this invention is applied. It is a figure which shows that a long image is generated from a plurality of partial images. It is a figure which shows the example of the relative positional relationship with a plurality of partial images. It is a figure which shows the example of the relationship between a plurality of partial images and a long image. It is a flowchart which shows an example of the operation of a long irradiation field recognition part. It is a figure which shows an example of the contour candidate of the irradiation field in a partial image and a long image. It is a figure which shows that a long image is separated into a plurality of partial images. It is a flowchart which shows an example of the operation of an image processing unit. It is a figure which shows an example of the processing of the radiography system to which the embodiment which concerns on this invention is applied.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

(Rough configuration of radiography system 100)
FIG. 1 is a diagram showing a schematic configuration of a radiographic imaging system 100 capable of long imaging to which the present invention is applied. The radiation imaging system 100 includes a radiation generation unit 101, a radiation detection unit 102, a data collection unit 103, a preprocessing unit 104, a CPU 105, a main memory 106, an operation unit 107, a display unit 108, and an image processing unit 109. Further, they are connected so that data can be exchanged with each other via the CPU bus 110.

The radiation detection unit 102, for example, has two or more radiation detectors arranged in the longitudinal direction of the subject, and takes a long image of a large subject 140 that cannot fit in one radiation detector. It can be performed. Further, a diaphragm 111 for shielding radiation is installed on the irradiation surface of the radiation generation unit 101. The operator can adjust the size of the irradiation range 112 with the aperture 111.

(Operation during radiography)
In the radiography system 100 described above, the main memory 106 stores various data necessary for processing by the CPU 105 and functions as a working memory of the CPU 105. The CPU 105 uses the main memory 106 to control the operation of the entire device according to the operation from the operation unit 107. As a result, the radiography system 100 including the radiography apparatus operates as follows.

First, when a shooting instruction is input from the user via the operation unit 107, the shooting instruction is transmitted to the data collecting unit 103 by the CPU 105. Upon receiving the imaging instruction, the CPU 105 controls the radiation generating unit 101 and the radiation detecting unit 102 to execute the radiation imaging.

In radiography, the radiation generating unit 101 irradiates the radiation beam, and the radiation beam is irradiated within the irradiation range 112 limited by the diaphragm 111. The radiation beam transmits the subject 140 within the irradiation range 112 while attenuating, and reaches the radiation detection unit 102.

(Radiation detector)
As described above, in the present embodiment, it is assumed that the subject 140 has a size (wide observation area) that cannot be accommodated in one radiation detector. This is, for example, the entire spinal region of the human body. In order to photograph the entire spinal region, as shown in FIG. 1, the radiation detection unit 102 has a plurality of radiation detectors (radiation detection units) 102-1, which are arranged side by side so as to partially overlap spatially. Includes 102-2 and 102-3.

The plurality of radiation detectors 102-1, 102-2, and 102-3 receive the radiation beam transmitted through the subject 140 and individually output signals according to the radiation intensity. That is, when looking at the radiation detection unit 102 as a whole, a plurality of radiation intensity signals are output from the plurality of radiation detectors 102-1, 102-2, 102-3 in one irradiation. The number of the plurality of radiation intensity signals is the number of radiation detectors constituting the radiation detection unit 102.

The data collection unit (first image generation unit) 103 collects a plurality of partial images obtained by irradiating radiation detectors 102-1, 102-2, and 102-3 arranged at different positions in space. Generate. The first image generation unit acquires a plurality of partial images by irradiating a plurality of radiation detectors 102-1, 102-2, 102-3 arranged at spatially different positions with radiation.

In addition, the first image generation unit may acquire a plurality of partial images by moving and arranging the radiation detectors at spatially different positions for each irradiation of radiation. For example, the radiation detector 102 is a single radiation detector whose spatial arrangement can be changed, and is irradiated multiple times while changing the spatial arrangement of the radiation detector in order to photograph the entire spinal region of the human body. May be done.

The radiation detector outputs a signal corresponding to the radiation intensity for each irradiation. Even when radiography is performed while changing the arrangement, a part of the radiation detector has a spatially overlapping portion. In this case, the number of multiple radiation intensity signals is the number of times the radiation detector has been irradiated. That is, the radiation detection unit 102 outputs a plurality of radiation intensity signals having different times of irradiation.

As described above, the radiation detection unit 102 outputs a plurality of radiation intensity signals to the data collection unit 103. The data collection unit 103 converts a plurality of signals into digital signals and supplies the plurality of image data to the preprocessing unit 104. The preprocessing unit 104 performs preprocessing such as offset correction and gain correction on a plurality of image data supplied from the data collection unit 103. The plurality of image data preprocessed by the preprocessing unit 104 are sequentially transferred to the main memory 106 and the image processing unit 109 via the CPU 105.

(Long image and partial image)
The image processing unit 109 includes a relative position calculation unit 113 and a long image composition unit 114.

The relative position calculation unit (calculation unit) 113 calculates the relative positional relationship of the plurality of partial images. The relative position calculation unit 113 calculates the relative positional relationship between the image data sets generated from the outputs of the radiation detectors arranged so that the parts are spatially overlapped. Further, the long image synthesizing unit (second image generating unit) 114 synthesizes partial images based on the relative positional relationship to generate a long image.

The long image synthesizing unit 114 synthesizes an image data set to generate a long image based on the relative positional relationship obtained by the relative position calculation unit 113. In the following description, the image data generated from the radiation intensity signal output by one radiation detector in one radiography is referred to as a "partial image", and an image data set of a plurality of partial images is combined. An image in which the entire area of the subject 130 is depicted is referred to as a "long image".

It will be described with reference to FIG. 2 that a long image IL is generated by the relative position calculation unit 113 and the long image synthesis unit 114 based on the relative positional relationship of the image data sets (partial images I1 and I2). ..

(Relative position calculation unit)
The method of calculating the relative positional relationship of the image data set performed by the relative position calculation unit 113 may be a conventional method and is not particularly limited. For example, while changing the relative positional relationship of the image data set, the degree of difference (or similarity) of the overlapping area of the image data set is obtained, and the degree of difference is the minimum (or the maximum degree of similarity). The calculation method is used.

When synthesizing image data sets (partial images I1 and I2) by this method, as shown in FIG. 3, one point (upper left end in FIG. 3) of one of the image data sets (partial image I1) is set as the origin O. Consider the coordinate system (x ₁ , y _1). Further, the coordinate system (x ₂ , y ₂ ) of the other (partial image I2) is represented by the coordinate system (x ₁ , y _1). In this case, the origin position of the other coordinate system (partial image _{I2) (x 2, y 2} ) _{is, (x 1, y 1)} = (sx, sy) is represented by, from the overlap area of the partial image I1, I2 The calculated difference S is defined by the equation (1).

In the above equation, oh is the height of the overlapping region and ow is the width of the overlapping region. The degree of difference S becomes smaller as the difference between the image signals in the overlapping region of the partial images I1 and I2 becomes smaller. The image signal is a signal obtained by converting the radiation transmitted through the subject and incident on the radiation detection unit, and the fact that the difference between the image signals is small is the converted image signal of the radiation transmitted through the same subject. Conceivable. Therefore, in this case, the degree of difference S is calculated while changing the position (sx, sy) within a predetermined range. Then, the relative position calculation unit 113 may calculate the relative positional relationship between the partial images I1 and I2 based on the position (sx, sy) at which the degree of difference S is minimized.

Further, as the relative positional relationship between the partial images I1 and I2, for example, the relative rotation angle r and the relative enlargement / reduction ratio s of the partial image I2 with respect to the partial image I1 due to the inclination of the radiation detector and the distance from the radiation generating portion are also adjusted. It is desirable to be done. In this case, the partial image I2 is rotated at the rotation angle r, the image enlarged / reduced at the scaling factor s is defined as I2rs, and the origin position of the image I2rs with respect to the partial image I1 is (x ₁ , y ₁ ) = (sx, sy). The degree of difference S is defined by the equation (2).

According to the above equation, the degree of difference S is calculated while changing the rotation angle r, the enlargement / reduction ratio s, and the origin position (sx, sy) within a predetermined range, and the parameters r, s, sx that minimize the degree of difference S are calculated. , Sy, the relative position calculation unit 113 may calculate the relative positions of the partial images I1 and I2.

In this way, while changing the relative positional relationship, the relative positional relationship is determined based on the degree of similarity or difference of the overlapping regions in the plurality of partial images. The relative position calculation unit 113 calculates at least one of the relative position, the relative rotation angle, and the relative enlargement / reduction ratio of the plurality of partial images as the relative positional relationship.

(Long image compositing section)
The long image synthesizing unit 114 synthesizes an image data set based on the relative positional relationship of the partial images I1 and I2 output by the relative position calculation unit 113, and generates a long image IL. The method for generating the long image IL may be a conventional method and is not particularly limited.

Here, a method of synthesizing an image data set when the relative positional relationship between the partial images I1 and I2 is expressed based on the origin position (sx, sy) of the partial image I2 with respect to the partial image I1 will be described.

The image size of the partial image I1 is defined as a height H1 and a width W1. Further, the image size of the partial image I2 is defined as a height H2 and a width W2. At this time, assuming that the size of the long image IL obtained by synthesizing the partial images I1 and I2 in consideration of the relative positional relationship (sx, sy) is the height HL and the width WL, the height HL and the width WL Is represented by the equation (3) as shown in FIG.

As shown in FIG. 4, the long image IL is an image in which partial images I1 and I2 are attached to a region of this size while maintaining a relative positional relationship (sx, sy). The region IB in which neither of the partial images I1 and I2 exists is filled with, for example, a pixel value of zero. Further, the pixel value of the overlapping area ID is the average value of the corresponding pixel values of the partial images I1 and I2.

(Partial irradiation field recognition)
The image processing unit 109 includes a contour candidate extraction unit 115, a partial irradiation field recognition unit 116, a long irradiation field recognition unit 117, and a long irradiation field decomposition unit 118.

The contour candidate extraction unit (extraction unit) 115 extracts contour candidates of the irradiation field in a plurality of partial images. The contour candidate extraction unit 115 extracts contour candidates (irradiation field contour candidates) of the irradiation field corresponding to the irradiation range 112 included in the partial image from each partial image. The method for extracting the irradiation field contour candidate may be a conventional method and is not particularly limited. For example, the contour candidate extraction unit (extraction unit) 115 may extract a straight line obtained by Hough transforming the partial image as an irradiation field contour candidate.

The partial irradiation field recognition unit (selection unit) 116 sets at least one criterion of the length, angle, position, and length ratio of the contour candidate based on the image size of the partial image, and the contour that matches this criterion. Select. The partial irradiation field recognition unit 116 selects an appropriate contour of the partial irradiation field from the irradiation field contour candidates extracted by the contour candidate extraction unit 115, and recognizes the area surrounded by the contour as the partial irradiation field.

The method for selecting an appropriate contour may be a conventional method and is not particularly limited. Here, we explain a method of defining an evaluation value that expresses the contour-likeness of a partial irradiation field, selecting appropriate contours on the top, bottom, left, and right based on the evaluation value, and recognizing the area surrounded by the selected contour as a partial irradiation field. To do.

The nth contour candidate Ln among the N contour candidates extracted from the partial image I is represented by the equation (4).

The contour candidate Ln, which is a straight line, is a vertical straight line whose inclination with respect to the y-axis direction is within ± 45 degrees if | an | is larger than | bn |, and if | an | is smaller than | bn |. , The inclination with respect to the x-axis direction is a straight line in the lateral direction within a range of ± 45 degrees. Using this equation, the evaluation value Sn considering that the contour of the irradiation field is a steep edge is defined by the equation (5). The evaluation value Sn representing the contour-likeness of the nth contour candidate Ln is defined as follows, for example.

This equation is the sum of the squares of the differences between the left and right pixels of the pixels on the contour candidate Ln, which is a straight line, and takes a large value at the left and right ends of the contour. Further, if the evaluation formula is defined by using the sum of squares of the differences between the upper and lower pixels of the pixels on the contour candidate Ln which is a straight line, a large value is taken at the upper and lower ends of the contour. Therefore, for the top, bottom, left, and right of the partial image, if the contour candidate Ln that maximizes these evaluation values is obtained on four sides and the area surrounded by the four sides is set as the partial irradiation field, the contour is surrounded by the contour that seems to be the most contour of the partial irradiation field. The area can be recognized as a partial irradiation field.

(Long irradiation field recognition)
The long irradiation field recognition unit (specific unit) 117 identifies the irradiation field of a long image from contour candidates based on the relative positional relationship. The long irradiation field recognition unit 117 synthesizes the contour candidates of the partial irradiation field extracted by the contour candidate extraction unit 115 based on the relative positional relationship output by the relative position calculation unit 113, and is appropriate as the contour of the long irradiation field. The area surrounded by the contour selected in is recognized (specified) as a long irradiation field.

In this case, the long irradiation field recognition unit 117 functions as a selection unit and sets at least one reference of the length, angle, position, and length ratio of the contour candidate based on the image size of the long image. , Contours that meet this criterion may be selected.

The method of recognizing the long irradiation field may be a conventional method and is not particularly limited. Here, as an example, a method of recognizing a long irradiation field in the steps shown in FIG. 5 will be described.

In step S501, the contour candidates extracted for each partial image are deformed based on the relative positional relationship of the partial images I1 and I2. This is to convert the contour candidates represented by the coordinate system (x ₁ , y ₁ ), (x ₂ , y ₂ ) for each partial image into the coordinate system (x _L , y _{L) of the long image.} Means. Here, the contour candidate L1 on the partial image I1 represented by the equation (6) and the contour candidate L2 on the partial image I2 will be described.

As shown in FIGS. 6 (a) and 6 (b), the equations of these contour candidates L1 and L2 have a coordinate system (x _{1) in which the upper left end coordinates of the respective partial images I1 and I2 are the origins O1 and O2.} , Y ₁ ), (x ₂ , y ₂ ). In order to simplify the explanation, the relative positional relationship between the partial images I1 and I2 is calculated based on the origin position (sx, sy) of the partial image I2 with respect to the partial image I1 as in the explanation used above. Will be done. It is assumed that both sx and sy are non-negative values.

At this time, as shown in FIG. 6C, the origin O1 of the partial image I1 coincides with the coordinates of the upper left end of the long image IL obtained by synthesizing the partial images I1 and I2, and the long image IL The coordinate system (x _L , y _{L ) is represented by the coordinate system (x 1} , y ₁ ) having the coordinate O1 as the origin, as in the partial image I1. Therefore, the formula representing the contour candidate L1 is the same in the coordinate system of the long image IL. On the other hand, the equation expressing the contour candidate L2 is _{converted into the coordinate system (x L} , y _L ) of the long image IL, and expressed in the coordinate system (x ₁ , y ₁ ), it becomes the equation (7).

In equation (7), the origin O2 (x ₂ , y ₂ ) = (0, 0) in the coordinate system of the partial image I2 is (x ₁ + sx _{) in the coordinate system (x L} , y _{L) of the long image IL.} , Y ₁ + sy). Here, a simple relative positional relationship (sx, sy) has been described as an example. For example, when the partial image I2 is rotated at a relative rotation angle r with respect to the partial image I1 and is enlarged / reduced at a relative enlargement / reduction ratio s. Applies coordinate transformations that match these to contour candidates.

In step S502, among the contour candidates of each partial image converted in the coordinate system of the long image IL based on the relative positional relationship in step S501, those presumed to be the same contour are integrated. For example, when the partial images I1 and I2 are combined into a long image as in the contour candidates L1 and L2 shown in FIG. 6C, it is estimated that the contours forming substantially the same straight line have the same contour. , Treat as a contour candidate as a whole.

Specifically, taking the contour candidates L1 and L2 represented by the coordinate system of the long image IL described above as an example, the slope of the straight line and the intercept are substantially equal according to the equation (8) (the difference is within a predetermined range). ), The contour candidates L1 and L2 are integrated as having the same contour.

In step S503, from the contour candidates of the long image IL integrated in step S502, an appropriate contour of the long irradiation field is selected, and the area surrounded by the contour is recognized as the long irradiation field. Here, as in the partial irradiation field recognition method, an evaluation value representing the contour-likeness of the long irradiation field is defined, contour candidates on the top, bottom, left, and right are selected based on the evaluation value, and the area surrounded by the contour candidates is long. It shall be recognized as an irradiation field.

The method for selecting an appropriate contour may be a conventional method and is not particularly limited. For example, by utilizing the steep edge of the irradiation field as well as the evaluation value of the partial irradiation field, an appropriate contour on the top, bottom, left, and right is selected based on the evaluation value, and the area surrounded by the selected contour is selected. May be recognized as a long irradiation field.

Further, more precise recognition processing is possible by using the characteristic information of the long image. The long irradiation field recognition unit (selection unit) 117 transforms the contour candidates in the partial image based on the relative positional relationship, and based on the ratio of the long side length to the short side length of the contour candidates, the long image. Select the contour of.

For example, a long irradiation field can be located on the long side (for example, | a1 | <1 or |) by utilizing the fact that the ratio of the length of the long side to the length of the short side is larger than that of the partial image. a2 | <1), contour candidates shorter than a predetermined threshold value are excluded from contour candidates because they are incorrect as vertical contours. In other words, the contour candidates integrated in step S502 are likely to be the correct long field contours.

Further, the long irradiation field recognition unit (selection unit) 117 transforms the contour candidates in the partial image based on the relative positional relationship, and excludes the contours included in the overlapping region of the plurality of partial images from the contour candidates. In the image data set for which the relative positional relationship has been calculated, the contour candidate located between the image data sets (for example, the overlapping region of the partial images I1 and I2) is a contour that divides the long irradiation field in the middle. It is presumed that the image is excluded from the contour candidates.

In this way, in the long irradiation field recognition, the long irradiation field contour is obtained by re-evaluating the contour candidates using the evaluation value indicating the long irradiation field contour likeness different from the evaluation value of the partial irradiation field contour. It may be confirmed.

(Long irradiation field decomposition)
The long irradiation field decomposition unit (separation unit) 118 radiates a plurality of partial images of the irradiation field of the long image specified by the long irradiation field recognition unit (specific unit) 117 based on the relative positional relationship. It is separated into irradiation fields, and the separated radiation irradiation fields are output as renewal irradiation fields. The long irradiation field decomposition unit 118 decomposes the long irradiation field recognized by the long irradiation field recognition unit 117 based on the relative positional relationship output by the relative position calculation unit 113, and outputs it as an updated partial irradiation field.

In this process, the long _{irradiation field represented by the coordinate system (x L} , y _{L ) of the long image IL has the coordinate systems (x 1} , y ₁ ), (x ₂ , y 1) of the partial images I1 and I2, respectively. or y ₂₎ becomes the in any position, and requests by the inverse transform of step 501 described above. Here, as a simple example, the relative positional relationship between the partial images I1 and I2 is that the origin position of the partial image I2 with respect to the partial image I1 is (sx, sy) and sx and sx and The case where both sy are non-negative values will be described with reference to FIG.

FIG. 7 schematically shows a long image IL and a long irradiation field RL obtained by synthesizing partial images I1 and I2 based on a relative positional relationship (sx, sy). The long irradiation field RL can be expressed as follows, for example, by using a binary image IB in which the inside of the long irradiation field having the same size as the long image IL is 1 and the outside of the long irradiation field is 0.

At this time, the updated partial irradiation field R1 of the partial image I1 is a region of the long irradiation field RL that is cut out in a range corresponding to the partial image I1. In this example, the coordinate system of the partial image I1 and the long image IL And since the coordinate systems of the binary image IB match, it can be expressed as follows.

On the other hand, the updated partial irradiation field R2 of the partial image I2 is a region of the long irradiation field RL that is cut out in a range corresponding to the partial image I2. In this example, considering that the coordinate system of the partial image I2 is different from the coordinate system of the long image IL and the binary image IB, it is expressed as follows.

That is, the long irradiation field decomposition unit 118 redefines the partial irradiation field for each of the partial images I1 and I2 by converting the coordinate system in consideration of the relative positional relationship as shown in the above equation, and the updated partial irradiation field. Obtain R1 and R2. Here, a simple relative positional relationship (sx, sy) has been described as an example. For example, when the partial image I2 is rotated at a relative rotation angle r with respect to the partial image I1 and is enlarged / reduced at a relative enlargement / reduction ratio s. Is applied with coordinate transformations that match these.

(Difference between partial irradiation field and renewal partial irradiation field)
Here, the partial irradiation field, the long irradiation field, and the renewal partial irradiation field will be described in detail. The partial irradiation field recognition unit 116 recognizes the partial irradiation field corresponding to the partial image by using the information of each of the partial images from the contour candidates of the irradiation field. In addition, the long irradiation field recognition unit 117 recognizes the long irradiation field from the contour candidates of the irradiation field by using the information of the entire long image. Further, the long irradiation field decomposition unit 118 decomposes the long irradiation field into an irradiation field for each partial image to obtain an updated partial irradiation field including information on the entire long image.

That is, the partial irradiation field is generated from the information of one corresponding partial image, while the updated partial irradiation field is generated by using the information of the entire long image. As will be described later, it is desirable that the partial irradiation field recognition performed by the partial irradiation field recognition unit 116 is a robust method that can be processed at high speed and does not cause a large failure so that it can be used for the preview display. On the other hand, the recognition of the long irradiation field performed by the long irradiation field recognition unit 117 is preferably a method that can recognize a precise irradiation field even if it cannot be processed at high speed so that it can be used for diagnostic image generation. ..

As described above, the long irradiation field recognition preferably uses the relative position information which is not used in the partial image irradiation field recognition, and performs the irradiation field recognition with high accuracy. Therefore, the long irradiation field recognition result can output the irradiation field with higher accuracy than the partial irradiation field recognition, and the updated partial irradiation field generated by this can be used for diagnosis. This is a highly accurate irradiation field recognition result.

(Preview image processing unit and diagnostic image processing unit)
The image processing unit 109 includes a preview image processing unit 119 and a diagnostic image processing unit 120.

The preview image processing unit (first image processing unit) 119 processes a plurality of partial images generated by the data collection unit (first image generation unit) 103 as preview images. The preview image processing unit 119 displays a preview partial image necessary for the user to quickly confirm, for example, whether the irradiated radiation is appropriate and whether the subject is within the shooting range in an appropriate posture. Generate. Here, the specific method is not limited, but preferably, a gradation conversion based on the pixel value distribution in the partial irradiation field output by the partial irradiation field recognition unit 116 is applied to the partial image for previewing. Output a partial image.

On the other hand, the diagnostic image processing unit (second image processing unit) 120 processes the long image generated by the long image synthesizing unit (second image generation unit) 114 as a diagnostic image. The diagnostic image processing unit 120 performs advanced noise reduction and edge enhancement processing generally required for diagnostic radiographic images, dynamic range compression optimized for each imaging site, enlargement / reduction processing, rotation, trimming, and the like. Then, the diagnostic image is output.

The diagnostic image processing is applied to both the partial image and the long image, and the diagnostic partial image and the diagnostic long image for the purpose of final display on the display unit or transfer to an external storage device, a printer, or the like. To generate. Appropriate images can be generated by performing diagnostic image processing on the long irradiation field output by the long irradiation field recognition unit 117 and the updated partial irradiation field output by the long irradiation field decomposition unit 118. become.

(Operation flow of image processing unit)
In the radiation imaging system 100 having the above configuration, the operation of the image processing unit 109 at the time of photographing a long image, which is a feature of the present embodiment, will be specifically described with reference to the flowchart shown in FIG.

In step S801, the plurality of partial images output by the preprocessing unit 104 are transferred to the image processing unit 109 via the CPU bus 110. The image processing unit 109 inputs a plurality of partial images one by one to the contour candidate extraction unit 115, and extracts contour candidates presumed to be the contour of the irradiation field region of each partial image.

In step S802, the image processing unit 109 inputs a plurality of contour candidates extracted by the contour candidate extraction unit 115 into the partial irradiation field recognition unit 116, and generates one irradiation field region for each partial image as a partial irradiation field. To do.

In step S803, the image processing unit 109 previews the plurality of partial images output by the preprocessing unit 104 one by one and the partial irradiation field of each partial image recognized by the partial irradiation field recognition unit 116. Input to the image processing unit 119 to generate a partial image for preview. As soon as the preview partial image is generated, it is transferred to the display unit 108 via the CPU bus 110 and preview-displayed one by one. Here, the preview display can be performed before the processing that requires the processing time after the step S804 that follows, and high-speed display can be realized.

In step S804, the image processing unit 109 inputs to the relative position calculation unit 113 an image data set in which the radiation detector at the time of photographing is spatially adjacent to each other among the plurality of partial images output by the preprocessing unit 104. Then, the relative position information between images is output. When the number of partial images is three or more, the images are input to the relative position calculation unit 113 while changing the image data set, and the relative position information regarding the adjacent image data sets is obtained respectively. That is, the relative position information between the partial images is obtained as many as the number of joint positions (overlapping), such as 2 in the case of 3 images and 3 in the case of 4 images.

In step S805, the image processing unit 109 inputs a plurality of partial images output by the preprocessing unit 104 and relative position information output by the relative position calculation unit 113 into the long image composition unit 114, and inputs the long image. Is output.

In step S806, the image processing unit 109 converts the partial irradiation field of each of the plurality of partial images output by the partial irradiation field recognition unit 116 and the relative position information output by the relative position calculation unit 113 into the long irradiation field recognition unit. Input to 117 and output the long irradiation field.

In step S807, the image processing unit 109 inputs the long image output by the long image synthesis unit 114 and the long irradiation field output by the long irradiation field recognition unit 117 into the diagnostic image processing unit 120. , Outputs a long image for diagnosis.

In step S808, the image processing unit 109 inputs the long irradiation field output by the long irradiation field recognition unit 117 and the relative position information output by the correlation position calculation unit 113 into the long irradiation field decomposition unit 118. , Output the updated partial irradiation field.

In step S809, the image processing unit 109 inputs a plurality of partial images output by the preprocessing unit 104 and an updated partial irradiation field output by the long irradiation field decomposition unit 118 into the diagnostic image processing unit 120. Output a partial image for diagnosis. A plurality of portions of a long image generated by a diagnostic image processing unit (second image processing unit) 120 and a long image synthesizing unit (second image generation unit) 114 separated based on a relative positional relationship. Process the image as a diagnostic partial image. Here, the diagnostic partial image is a partial image regenerated based on the updated partial irradiation field, and high-precision diagnostic image generation that could not be performed at the time of preview display can be realized.

(About thinned images)
In the radiography system 100 described above, the data collection unit 103 may collect image data from the radiation detection unit 102 in a plurality of units. The data collection unit (first image generation unit) 103 generates a partial image with a predetermined amount of data or less. The preview image processing unit (first image processing unit) 119 processes a partial image having a predetermined amount of data or less as a preview image.

For example, the first time, the amount corresponding to 1/4 of the image data is thinned out and collected, and the second time, the amount corresponding to the remaining 3/4 is collected. Then, if thinned-out image data is generated from the data corresponding to the first 1/4 and the steps up to step S803 are executed using the thinned-out image data, a higher-speed preview display can be performed. Further, by configuring the relative position information calculation in step S804 to be performed using the entire image data combined with the data collected a second time, it is possible to prevent a decrease in the accuracy of the relative position information calculation.

FIG. 9 is a diagram showing an example of processing of a radiography system to which this embodiment is applied. The relative position calculation unit (calculation unit) 113 calculates the relative positional relationship of the plurality of partial images 1 to 3 and outputs the relative position information. The long image synthesizing unit (second image generating unit) 114 synthesizes the partial images 1 to 3 based on the relative positional relationship to generate a long image.

The contour candidate extraction unit (extraction unit) 115 extracts contour candidates of the irradiation field in the plurality of partial images 1 to 3. The partial irradiation field recognition unit (selection unit) 116 selects an appropriate contour of the partial irradiation field from the irradiation field contour candidates extracted by the contour candidate extraction unit 115, and recognizes the area surrounded by the contour as the partial irradiation field. ..

The long irradiation field decomposition unit (separation unit) 118 describes the radiation irradiation field of the long image specified by the long irradiation field recognition unit (specific unit) 117 with a plurality of partial images 1 to 2 based on the relative positional relationship. It is separated into the irradiation fields of No. 3, and the separated irradiation fields are output as the renewal irradiation fields.

According to the present embodiment, in a radiography apparatus that synthesizes a plurality of radiographic images acquired by a radiological detection unit to generate a composite image (long image), a relative position calculation unit 113 and a partial irradiation field recognition unit 116 A long irradiation field recognition unit 117 is provided. The partial irradiation field recognition unit 116 can generate a partial irradiation field that can be used for preview image processing at high speed by recognizing the irradiation field individually from the partial image.

The long irradiation field recognition unit 117 can generate a long irradiation field that can be used for diagnostic image processing with high accuracy based on the alignment information generated by the relative position calculation unit 113. As a result, it is possible to realize both high speed of the preview image and improvement of the accuracy of the diagnostic image in the irradiation field recognition of the radiographic imaging apparatus that performs long-length imaging.

As described above, according to the present embodiment, it is possible to improve the recognition accuracy of the irradiation field of a long image. In addition, the diagnostic image can be displayed with the accuracy required for diagnosis, and the preview image can be displayed quickly.

Although the preferred embodiments of the present invention have been described above, it goes without saying that the present invention is not limited to these embodiments, and various modifications and modifications can be made within the scope of the gist thereof.

The present invention is also achieved by supplying a software program for executing the above processing directly or remotely to a system or device, and the computer of the system or device reading and executing the supplied program code. Including the case.

Therefore, in order to realize the functional processing of the present invention on a computer, the program code itself installed on the computer also realizes the present invention. That is, the present invention also includes a computer program itself for realizing the functional processing of the present invention.

Computer-readable storage media that store programs for supplying programs include the following. For example, hard disks, optical disks, optical magnetic disks, MOs, CD-ROMs, CD-Rs, CD-RWs, magnetic tapes, non-volatile memory cards, ROMs, DVDs (DVD-ROMs, DVD-Rs) and the like.

In addition, as a method of supplying the program, it can also be supplied by connecting to the homepage of the Internet using the browser of the client computer and downloading from the homepage to the computer of the present invention itself. The program can also be supplied by downloading a compressed file including an automatic installation function to a recording medium such as a hard disk.

It can also be realized by dividing the program code constituting the program of the present invention into a plurality of files and downloading each file from different homepages. That is, the present invention also includes a WWW server that allows a plurality of users to download a program file for realizing the functional processing of the present invention on a computer.

By encrypting the program of the present invention, storing it in a storage medium, and distributing it to users, a user who clears a predetermined condition is made to download the key information for decrypting the encryption via the Internet, and the key information is used. It is also possible to run an encrypted program.

The function of the embodiment is realized by the computer executing the read program, and the OS or the like running on the computer performs a part or all of the actual processing based on the instruction of the program. This can also realize the function of the embodiment.

100 Radiation imaging system 101 Radiation generation unit 102 Radiation detection unit 103 Data collection unit 104 Preprocessing unit 105 CPU
106 Main memory 107 Operation unit 108 Display unit 109 Image processing unit 110 CPU bus 111 Aperture 112 Irradiation range 113 Relative position calculation unit 114 Long image synthesis unit 115 Contour candidate extraction unit 116 Partial irradiation field recognition unit 117 Long irradiation field recognition unit 118 Long irradiation field decomposition unit 119 Preview image processing unit 120 Diagnostic image processing unit 130, 140 Subject

Claims (17)

A first image generating means for generating a plurality of partial images from one degree of radiation against the radiation detecting section arranged in spatially different positions,
An extraction means for extracting contour candidates of the irradiation field in the plurality of partial images, and
A calculation means for calculating the relative positional relationship of the plurality of partial images, and
A second image generation means that synthesizes the partial images to generate a long image based on the relative positional relationship, and
Based on the relative positional relationship, a long irradiation field recognition means for recognizing the irradiation field of the long image from the outline candidate,
The irradiation field of the long image recognized by the long irradiation field recognition means is separated into the irradiation fields of the plurality of partial images based on the relative positional relationship, and the separated irradiation fields are separated. Is recognized as a partial irradiation field in the plurality of partial images, and a partial irradiation field recognition means.
A radiographing apparatus characterized in that it is provided with. A first image generation means for generating a plurality of partial images by moving and arranging a radiation detection unit at a spatially different position without changing the setting of the irradiation field region for each irradiation of radiation.
An extraction means for extracting contour candidates of the irradiation field in the plurality of partial images, and
A calculation means for calculating the relative positional relationship of the plurality of partial images, and
A second image generation means that synthesizes the partial images to generate a long image based on the relative positional relationship, and
A long irradiation field recognition means for recognizing the irradiation field of the long image from the contour candidate based on the relative positional relationship, and
The irradiation field of the long image recognized by the long irradiation field recognition means is separated into the irradiation fields of the plurality of partial images based on the relative positional relationship, and the separated irradiation fields are separated. Is recognized as a partial irradiation field in the plurality of partial images, and a partial irradiation field recognition means.
A radiographing apparatus characterized in that it is provided with. The radiography apparatus according to claim 1 or 2 , further comprising a first image processing means for performing gradation conversion processing on the plurality of partial images generated by the first image generating means. .. At least one of noise reduction processing, edge enhancement processing, dynamic range change, enlargement / reduction processing, rotation processing, and trimming processing is performed on the long image generated by the second image generation means. The radiography apparatus according to any one of claims 1 to 3, further comprising a second image processing means to be applied. To said second image generating means multiple partial image from the generated said elongate image is separated based on the relative positional relationship, the noise reduction processing, edge enhancement processing, changes of dynamic range, scaling The radiography apparatus according to any one of claims 1 to 4, further comprising a second image processing means for performing at least one image processing of processing, rotation processing, and trimming processing. The first image generation means generates the partial image with less than the amount of image data output from the radiation detection unit .
The radiography according to claim 3 , wherein the first image processing means performs a gradation conversion process on the partial image having a data amount smaller than the amount of image data output from the radiation detection unit. apparatus. The radiography apparatus according to any one of claims 1 to 6 , wherein the extraction means extracts the contour candidate by Hough transform. A selection means for setting at least one criterion of the length, angle, position, and length ratio of the contour candidate based on the image size of the partial image or the long image, and selecting a contour that matches the criterion. equipped with a,
The long irradiation field recognition means, a radiation imaging apparatus according to any one of claims 1 to 7, characterized that you recognize a region surrounded by the selected contour as the radiation field. Based on the overlapping region of the plurality of partial images or the relative positional relationship, at least one criterion of the length, angle, position, and length ratio of the contour candidate is set, and the long image that matches the criterion. a selection means for selecting the contour,
The long irradiation field recognition means, a radiation imaging apparatus according to any one of claims 1 to 7, characterized that you recognize a region surrounded by the selected contour as the radiation field. A selection means for selecting a contour by performing coordinate transformation of the contour candidate in the partial image based on the relative positional relationship and excluding the contour including the entire contour in one overlapping region of the plurality of partial images from the contour candidate. equipped with a,
The long irradiation field recognition means, a radiation imaging apparatus according to any one of claims 1 to 7, characterized that you recognize a region surrounded by the selected contour as the radiation field. The calculating means, as the relative positional relationship, the relative positions of the plurality of partial images, one of a relative rotation angle, and claims 1 to 1 0, characterized in that to calculate at least one of the relative scaling factor The radiography apparatus according to item 1. Said calculation means, while changing the relative positional relationship, based on the similarity or dissimilarity of the overlap region in the plurality of partial images, according to claim 1 to 1 1, characterized in that determining the relative positional relationship The radiography apparatus according to any one of the above items. Radiation generating means to generate radiation and
A radiation detection unit that detects the radiation and
A first image generating means for generating a plurality of partial images from one degree of radiation against the radiation detecting portion arranged in spatially different positions,
An extraction means for extracting contour candidates of the irradiation field in the plurality of partial images, and
A calculation means for calculating the relative positional relationship of the plurality of partial images, and
A second image generation means that synthesizes the partial images to generate a long image based on the relative positional relationship, and
Based on the relative positional relationship, a recognition means for recognizing the irradiation field of the long image from the outline candidate,
The irradiation field of the long image recognized by the long irradiation field recognition means is separated into the irradiation fields of the plurality of partial images based on the relative positional relationship, and the separated irradiation fields are separated. Is recognized as a partial irradiation field in the plurality of partial images, and a partial irradiation field recognition means.
A radiography system characterized by being equipped with. A first image generation means for generating the plurality of partial images by moving and arranging the radiation detection unit at the spatially different positions without changing the setting of the irradiation field region for each irradiation of the radiation.
An extraction means for extracting contour candidates of the irradiation field in the plurality of partial images, and
A calculation means for calculating the relative positional relationship of the plurality of partial images, and
A second image generation means that synthesizes the partial images to generate a long image based on the relative positional relationship, and
A long irradiation field recognition means for recognizing the irradiation field of the long image from the contour candidate based on the relative positional relationship, and
The irradiation field of the long image recognized by the long irradiation field recognition means is separated into the irradiation fields of the plurality of partial images based on the relative positional relationship, and the separated irradiation fields are separated. Is recognized as a partial irradiation field in the plurality of partial images, and a partial irradiation field recognition means.
A radiography system characterized by being equipped with. Generating a plurality of partial images from the radiation SenTeru morphism of 1 degree against the radiation detecting section arranged in spatially different positions,
A step of extracting contour candidates of the irradiation field in the plurality of partial images, and
The step of calculating the relative positional relationship of the plurality of partial images and
A step of synthesizing the partial images to generate a long image based on the relative positional relationship, and
Based on the relative positional relationship, a step of recognizing the irradiation field of the long image from the outline candidate,
The irradiation field of the long image is separated into the irradiation field of the plurality of partial images based on the relative positional relationship, and the separated radiation field is used as the partial irradiation field of the plurality of partial images. The process of recognition and
A radiological imaging method characterized by comprising. A step of generating the plurality of partial images by moving and arranging the radiation detection unit at the spatially different positions without changing the setting of the irradiation field region for each irradiation of the radiation.
A step of extracting contour candidates of the irradiation field in the plurality of partial images, and
The step of calculating the relative positional relationship of the plurality of partial images and
A step of synthesizing the partial images to generate a long image based on the relative positional relationship, and
A step of recognizing the irradiation field of the long image from the contour candidate based on the relative positional relationship, and
The irradiation field of the long image recognized by the long irradiation field recognition means is separated into the irradiation fields of the plurality of partial images based on the relative positional relationship, and the separated irradiation fields are separated. Is recognized as a partial irradiation field in the plurality of partial images, and
A radiological imaging method characterized by comprising. Program for causing to function as each means of the radiation imaging apparatus according to the computer in any one of claims 1 to 1 2.