JP2020099827A - Radiographic apparatus, radiographic system and dose index management method - Google Patents

Abstract

To provide a radiographic apparatus, a radiographic system and a dose index management method for selecting a target dose index suitable for a photographing mode of radiography, and properly evaluating the dose index.SOLUTION: A radiographic apparatus comprises: a selection part 113 for selecting a target dose index in radiography based on a photographing mode of radiography; a dose index acquisition part 115 for acquiring a dose index from image data based on radiation ray which passed a subject; and a calculation part 116 for calculating a deviation index of the dose index with respect to the target dose index. In other embodiment, the radiographic apparatus comprises a display control part 118 for displaying the target dose index and the dose index on a display part 40 with information of the photographing mode of radiography.SELECTED DRAWING: Figure 1

Description

The present invention relates to software for controlling radiation imaging, or a radiation imaging apparatus for imaging radiation, a radiation imaging system, and a dose index management method.

In recent years, a radiation imaging system in which radiation is irradiated from a radiation generation device to the radiation imaging device, the radiation imaging device generates a radiation image, and the radiation image can be displayed has become popular.

Further, the radiation imaging apparatus can calculate a dose index corresponding to the dose based on the representative pixel value acquired from the radiation image. In the radiation imaging apparatus described in Patent Document 1, a target dose index to be targeted is set for each imaging site, and whether the dose at the time of imaging was appropriate was determined from the actually calculated dose index and the target dose index. It allows the operator to evaluate.

JP, 2009-268801, A

When a grid is attached to a radiation imaging apparatus to perform radiation imaging, the grid absorbs scattered rays based on the radiation and part of the radiation. Therefore, even if the dose of radiation generated from the radiation generator is the same, the dose index calculated from the radiation image becomes smaller than in the case where the grid is not attached. That is, the dose index calculated from the radiographic image changes depending on the radiographic imaging mode (for example, the presence or absence of a grid). In the above-mentioned patent document, there is no mention of selecting the target dose index in consideration of the radiographic imaging mode.

Therefore, an object of the present invention is to provide a radiation imaging apparatus, a radiation imaging system, and a dose index management method capable of selecting a target dose index suitable for an imaging mode of radiography and appropriately evaluating the dose index. ..

In order to achieve the object of the present invention, a radiographic apparatus of the present invention is configured such that a selection unit for selecting a target dose index in radiographic imaging based on a radiographic imaging mode and an image based on radiation transmitted through a subject. A dose index acquisition unit that acquires a dose index from the data and a calculation unit that calculates a deviation index of the dose index from the target dose index are provided. Alternatively, the radiation imaging apparatus of the present invention includes a display control unit that causes the display unit to display the target dose index and the dose index together with the information on the imaging mode of the radiation imaging.

According to the present invention, it is possible to select a target dose index suitable for an imaging mode of radiography and appropriately evaluate the dose index.

The block diagram which shows an example of a structure of the radiography system of this invention. The block diagram which shows an example of a structure of the radiography apparatus of this invention. The figure which shows an example of the screen of the display part which sets the target dose index of this invention. The figure which shows an example of the screen of the display part which displays the radiation image etc. of this invention. 3 is a flowchart showing an operation in the first embodiment of the present invention. The block diagram which shows an example of a structure of the radiography apparatus of this invention. The figure which shows an example of the screen display which sets the allowable range of the dose warning function of this invention. The figure which shows an example of the screen of the display part which displays the warning information of this invention. The block diagram which shows an example of a structure of the radiography apparatus of this invention. 9 is a flowchart showing the operation of the third embodiment of the present invention.

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

FIG. 1 shows an example of the configuration of a radiation imaging system of the present invention. The radiation imaging system includes a radiation generation device 20 that generates radiation, a radiation imaging device 10 that images radiation, a display unit 40 that displays a radiation image based on the radiation imaged by the radiation imaging device 10, and an operator performs various operations. And an input unit 60 for inputting information. The input unit 60 is a keyboard, buttons, touch panel, etc., and the operator inputs various information.

The radiation generator 20 has a function of generating radiation. The radiation generator 20 can irradiate a predetermined irradiation range with radiation. The radiation generator 20 is installed via a support (not shown) installed on the floor or ceiling. A diaphragm (not shown) that blocks radiation is installed on the irradiation surface of the radiation generator 20. The operator can set the irradiation range of the radiation emitted from the radiation generation device 20 by controlling the diaphragm that blocks the radiation.

The radiation imaging apparatus 10 includes an imaging unit 101 that images the radiation that has passed through the subject 30 and generates image data, and a control unit 102 that processes the image data and outputs a radiation image to the display unit 40. There is.

The imaging unit 101 detects the radiation that has passed through the subject 30 and converts it into an electrical signal to generate image data. The imaging unit 101 detects the radiation that has passed through the subject 30 as electric charges corresponding to the amount of transmitted radiation. For example, in the imaging unit 101, a direct conversion sensor such as a-Se that converts radiation into electric charges, or a direct conversion sensor that directly converts radiation into electric charges, a scintillator such as CsI, and a photoelectric conversion element such as a-Si are used. An indirect sensor is used. The imaging unit 101 generates image data by A/D converting the detected charges. Then, the photographing unit 101 outputs the image data to the control unit 102.

The control unit 102 has components necessary for control such as a CPU and a memory. The CPU is a microprocessor and controls the devices of the control unit 102 by performing arithmetic operations for image pickup processing, image processing, display control processing, and the like, and logical judgment. The memory is a readable/writable random access memory, and is used as a main memory for temporary storage of various data from the device. The control unit 102 is assumed to have a configuration in which software is installed in a personal computer or the like, but a dedicated hardware unit may be used. Further, although the imaging unit 101 and the control unit 102 of the radiation imaging apparatus 10 are configured as separate bodies, it is not limited to being a separate body, and some of the functions of the control unit 102 are built into the imaging unit 101. It is also possible.

The control unit 102 can control the imaging unit 101 to perform radiation imaging. The control unit 102 performs various processes such as image processing of image data, and outputs the processed image data to the display unit 40 as a radiation image. The control unit 102 can also control the display unit 40 to set the display form of the radiation image or the like.

The display unit 40 is a liquid crystal display, a CRT, or the like, and displays the radiation image output from the radiation imaging apparatus 10 and various information input from the input unit 60.

The grid 50 is attached to the radiation imaging apparatus 10. The grid 50 has a function of blocking scattered radiation based on radiation. The grid 50 includes a plurality of metal foils, and absorbs scattered rays scattered by the subject 30 and part of the radiation generated from the radiation generator 10 and transmitted through the subject 30.

The grid 50 is attached so as to cover the imaging unit 101 of the radiation imaging apparatus 10 according to the imaging site of the subject 30. For example, if the imaged region of the subject 30 is the abdomen, the grid 50 is attached to the radiation imaging apparatus 10. If the imaged region of the subject 30 is a limb, scattered radiation is weak, so that the grid 50 need not be attached to the radiation imaging apparatus 10.

The radiation imaging system includes a grid attachment detection unit 103 that detects the attachment state of the grid 50. The grid attachment detection unit 103 may be installed in a holding unit that holds the radiation imaging apparatus 10 or may be installed in the radiation imaging apparatus 10. The grid attachment detection unit 103 detects whether or not the grid 50 is attached to the radiation imaging apparatus 10. For detecting the mounting of the grid 50, the grid 50 is physically detected by a contact sensor, a magnetic sensor, a pressure sensor, or the like.

FIG. 2 is a diagram showing the configuration of the radiation imaging apparatus 10 in the radiation imaging system of the present invention. The radiation imaging apparatus 10 includes a setting unit 111 that sets a target dose index, and a storage unit 112 that stores a plurality of target dose indices set by the setting unit 111.

The radiation imaging apparatus 10 includes a selection unit 113 that selects a target dose index from a plurality of target dose indices stored in the storage unit 112, and a holding unit 114 that holds the selected target dose index. The radiation imaging apparatus 10 also includes a dose index acquisition unit 115 that acquires a dose index from image data based on the radiation that has passed through the subject 30, and a calculation unit 116 that calculates a deviation index of the dose index from the target dose index. I have it.

The radiation imaging apparatus 10 causes the display unit 40 to display the image processing unit 117 that processes the image data output from the imaging unit 101 to generate a radiation image, and the radiation image and the deviation index of the dose index with respect to the target dose index. And a display control unit 118.

The dose index acquisition unit 115 acquires a dose index from the image data output from the imaging unit 101. The dose index is, for example, Exposure Index (EI). The dose index is a value for evaluating the dose used for radiography. EI is an index standardized as IEC62494-1 by the International Electrotechnical Commission (International_Electric_Conference: IEC).

Specifically, first, the dose index acquisition unit 115 sets a predetermined region of interest in the image data output from the imaging unit 101, and calculates a representative pixel value in the region of interest. The representative pixel value is a pixel value such as an average value, a median value and a mode value. The dose index acquisition unit 115 converts the representative pixel value into a dose based on the known relationship between the incident dose and the pixel value. Then, the dose index acquisition unit 115 calculates the dose index (EI) by multiplying the converted dose by a constant. Although the dose index acquisition unit 115 has calculated EI as a dose index, any dose index other than EI can be used as long as the dose index can determine whether the dose reaching the imaging unit 101 is relatively high or low. Dose indicators may be used. The dose index acquired by the dose index acquisition unit 115 is output to the calculation unit 116.

Here, the setting unit 111 that sets the target dose index will be described with reference to FIG. FIG. 3 shows an example of a screen of the display unit 40 for setting a plurality of different target dose indexes in the setting unit 111. A setting screen for setting the target dose index is displayed on the display unit 40. Here, a target dose index name 401, a target dose index input field 402, and a dose index reference value 403 are displayed. The target dose index (setting value) in the target dose index input field 402 is input by the input unit 60. Here, Exposure Index Target (EIt) is set as the target dose index. EIt is an index standardized as IEC62494-1.

As the target dose index name 401, at least one target dose index name associated with the examination order of the subject 30 is displayed. The target dose index name may be associated with the imaging site (abdomen, extremities, etc.) of the subject 30. For example, if the imaging region of the subject 30 is the abdomen, the target dose index name and the like may be set assuming that the grid 50 is attached to the radiation imaging apparatus 10. If the imaged region of the subject 30 is a limb, the target dose index name and the like may be set assuming that the grid 50 is not attached to the radiation imaging apparatus 10.

Here, as the target dose index name 401, the name of the target dose index EIt(glid) assuming that the grid 50 is attached to the radiation imaging apparatus 10 is displayed. Further, as the target dose index name 401, the name of the target dose index EIt (glidless) assuming that the grid 50 is not attached to the radiation imaging apparatus 10 is displayed.

The target dose index input field 402 can input at least one target dose index. The operator can input the target dose index EIt via the input unit 60. Specifically, the operator can input, via the input unit 60, a target dose index EIt(glid) assuming that the grid 50 is attached to the radiation imaging apparatus 10. Further, the operator can input a target dose index EIt (glidless), which is assumed when the grid 50 is not attached to the radiation imaging apparatus 10, via the input unit 60.

The dose index reference value 403 is a dose index EI calculated from radiation images captured in the past. The dose index reference value 403 is a reference value when the operator sets the target dose index in the target dose index input field 402. For example, the dose index reference value 403 is a statistical value (for example, in a plurality of dose indices EI calculated from a plurality of radiation images captured in the past with and without the grid 50 attached to the radiation imaging apparatus 10). , Average value).

The dose index reference value 403 corresponding to the target dose index EIt(glid) is a dose index EI calculated from radiation images taken in the past with the grid 50 attached to the radiation imaging apparatus 10. The dose index reference value 403 corresponding to the target dose index EIt (glidless) is the dose index EI calculated from the radiation images captured in the past with the grid 50 not attached to the radiation imaging apparatus 10.

Note that it is not necessary to display all the information on the screen for setting the target dose index shown in FIG. 3, as long as at least the target dose index name 401 and the target dose index input field 402 are displayed.

The storage unit 112 stores a plurality of target dose indexes set on the setting screen for setting the target dose indexes shown in FIG. The storage unit 112 stores a target dose index EIt(glid) assuming that the grid 50 is attached to the radiation imaging apparatus 10, and a target dose index EIt(glidless) assuming that the grid 50 is not attached to the radiation imaging apparatus 10. Identify and store. The storage unit 112 can store the target dose index EIt(glid) as a first target dose index and the target dose index EIt(glidless) as a second target dose index.

The selection unit 113 selects a target dose index for radiography based on the radiography mode. The imaging mode of radiation imaging is, for example, the mounting state of the grid 50. When the grid 50 is attached to the radiation imaging apparatus 10, the selection unit 113 selects the target dose index EIt(glid). When the grid 50 is not attached to the radiation imaging apparatus 10, the selection unit 113 selects the target dose index EIt(glidless).

The holding unit 114 holds the target dose index selected by the selection unit 113. The target dose index held in the holding unit 114 corresponds to the dose index acquired from the image data output from the imaging unit 101. That is, the image capturing mode (grid mounting state) of the image data, which is the source of the target dose index held by the holding unit 114 and the dose index acquired by the dose index acquiring unit 115, is the same.

The calculation unit 116 calculates the deviation index of the dose index EI from the target dose index EIt based on the dose index EI output from the dose index acquisition unit 115 and the target dose index EIt output from the holding unit 114 (selection unit 113). calculate.

The deviation index Deviation Index (DI) is an index standardized as IEC 62494-1. Specifically, the deviation index DI is calculated by the following formula.
DI=10 log ₁₀ (EI/EIt)

Generally, it is considered that the dose is higher than usual when the deviation index DI is larger than 0, and the dose is lower than normal when the deviation index DI is smaller than 0. The deviation index DI calculated by the calculation unit 116 is output to the display control unit 118.

The image processing unit 117 has a function of performing image processing such as noise removal and gradation processing on the image data output from the image capturing unit 101. The image processing unit 117 can also perform image processing such as trimming and rotation on the image data output from the imaging unit 101. The image data image-processed by the image processing unit 117 is output to the display control unit 118 as a radiation image.

The display control unit 118 causes the display unit 40 to display the radiation image. The display control unit 118 may display the deviation index of the dose index with respect to the target dose index together with the information on the imaging mode of radiography. Further, the display control unit 118 may cause the display unit 40 to display the target dose index and the dose index together with the information on the imaging mode of radiation imaging.

A specific display form of the display unit 40 will be described with reference to FIG. As shown in FIG. 4, the display unit 40 displays the radiation image 410 image-processed by the image processing unit 117. The dose index 411 acquired by the dose index acquisition unit 115 is displayed on the display unit 40 in an area adjacent to the radiation image 410. Then, the deviation index 412 of the dose index with respect to the target dose index calculated by the calculation unit 116 and the target dose index 413 selected by the selection unit 113 are displayed on the display unit 40.

The target dose index 413 displayed on the display unit 40 includes information indicating the mounting state of the grid 50. If it is EIt (glid), it indicates that the grid 50 is attached to the radiation imaging apparatus 10. If it is EIt (glidless), it means that the grid 50 is not attached to the radiation imaging apparatus 10. The operator can recognize whether it is the target dose index EIt when the grid 50 is mounted or the target dose index EIt when the grid 50 is not mounted, based on the information indicating the mounting state of the grid 50. .. Note that the display unit 40 may display all the target dose indexes stored in the storage unit 112 or display the target dose indexes held by the holding unit 114, regardless of the mounting state of the grid 50. Good. It is not necessary for all of this information to be displayed, and the items to be displayed may be individually set according to the settings of the operator.

As shown in FIG. 4, when the dose index 411 acquired by the dose index acquisition unit 115 is “126” and the target dose index 413 selected by the selection unit 113 is “100”, the above formula 1 is obtained. The deviation index 412 of the dose index with respect to the target dose index calculated based on this is “+1”. Since the deviation index DI is larger than 0, the operator can recognize that the dose is higher than usual. At that time, the operator can also recognize that the deviation index 412 is calculated in a state where the grid 50 is attached to the radiation imaging apparatus 10.

In the present invention, the display unit 40 displays at least the radiation image 410, the dose index 411, the deviation index 412 or the target dose index 413 on the same screen. The deviation index 412 allows the operator to recognize whether the dose reaching the imaging unit 101 is relatively high or low. Further, the operator can recognize how high or low the dose index 412 is with respect to the target dose index 413.

Here, the operation of the radiation imaging system of the present invention will be described with reference to the flowchart shown in FIG.

In step S501, the operator selects the examination order in which the imaged region of the subject 30 is set.

In step S502, the operator selects the radiation imaging apparatus 10 (sensor) used for imaging. A case in which the radiation imaging apparatus 10 does not have a grid detection function for detecting the grid 50 or a case in which the use of the grid 50 cannot be physically determined will be described in another embodiment.

In step S503, the grid attachment detection unit 103 determines whether the grid 503 is attached. The grid attachment detection unit 103 may physically detect attachment of the grid 50 by an external means such as a change in weight due to attachment of the radiation imaging apparatus 10 or information on a camera provided in the radiation imaging system. The grid attachment detection unit 103 is not always necessary, and the operator can manually input whether the grid 50 is attached via the input unit 60. The mounting information of the grid 50 input by the input unit 60 is output to the control unit 102.

When the grid 50 is attached to the radiation imaging apparatus 10, the process proceeds to step S504, and when the grid 50 is not attached to the radiation imaging device 10, the process proceeds to step S505.

In step S504, the selection unit 113 selects a target dose index when the grid 50 is attached to the radiation imaging apparatus 10, from at least one target dose index stored in the storage unit 112. The target dose index selected by the selection unit 113 is held in the holding unit 114.

In step S505, the selection unit 113 selects a target dose index when the grid 50 is not attached to the radiation imaging apparatus 10, from at least one or more target dose indices stored in the storage unit 112. The target dose index selected by the selection unit 113 is held in the holding unit 114.

In step S506, the operator performs radiography. The imaging unit 101 detects the radiation that has passed through the subject 30, converts it into an electrical signal, and outputs image data.

In step S507, the dose index acquisition unit 115 acquires the dose index from the image data.

In step S508, the dose index is displayed on the display unit 40. In addition, the display unit 40 displays the dose index and the deviation index or the target dose index on the same screen together with the information on the radiographic imaging mode. The operator can confirm whether or not the dose index for this imaging is within the allowable range.

As described above, according to the radiation imaging system (radiation imaging apparatus) of the present embodiment, the selection unit 113 that selects the target dose index in the radiation imaging based on the imaging mode of the radiation imaging (presence or absence of grid) and the subject are selected. A dose index acquisition unit 115 that acquires a dose index from image data based on the transmitted radiation and a calculation unit 116 that calculates a deviation index of the dose index with respect to the target dose index selected by the selection unit 113 are provided. Alternatively, the radiation imaging system (radiation imaging apparatus) includes a display control unit 118 that displays the target dose index and the dose index selected by the selection unit 113 together with the information on the imaging mode of radiation imaging. Therefore, the operator can select the target dose index suitable for the imaging mode, and the operator can appropriately evaluate the dose index.

Example 2 will be described with reference to FIGS. 6 to 8. The difference from the first embodiment is that it includes a determination unit 120 that determines whether or not the dose index is within a preset allowable range.

FIG. 6 is a diagram showing the configuration of the radiation imaging apparatus 10 of the present invention. The configuration other than the determination unit 120 and the information generation unit 121 is the same as that of FIG. 2, and thus the description other than the determination unit 120 and the information generation unit 121 will be omitted.

The determining unit 120 uses the dose index acquired by the dose index acquiring unit 115 and the target dose index held by the holding unit 114 to determine whether or not the dose index is within a predetermined allowable range. To do.

When the determination unit 120 determines that the dose index is not within the allowable range (outside the allowable range), the information generation unit 121 generates warning information. The information generation unit 118 generates warning information when the determination unit 120 determines that the dose index is not within the allowable range.

The display control unit 120 generates a screen to be presented to the operator from the radiation image output from the image processing unit 119 and the warning information generated by the information generation unit 121, and displays the display state of the screen displayed on the display unit 40. Control.

FIG. 7 shows an example of a screen display for setting the upper limit value and the lower limit value which are the allowable range of the dose warning function. The dose warning function is a function to warn the operator when the determination unit 120 determines that the dose index of the image data captured this time is outside the appropriate dose range. Specifically, a check box 501 of the dose warning function to be checked when enabling the dose warning function is displayed. In FIG. 7, since the check box 501 is checked, it indicates that the dose warning function is enabled.

When the dose warning function is enabled, an index selection button 502 for selecting which index is used to use the dose warning function is displayed. In this embodiment, the sensitivity index REX, the dose index EI, and the deviation index DI can be selected.

Also, check boxes 503 to 506 of the dose determination reference value to be checked when enabling the setting of the upper limit value or the lower limit value for determining that the dose index is within the allowable range, and that the dose index is within the allowable range. The dose determination reference value input fields 507 to 510 for inputting the upper limit value or the lower limit value for determination are components of the setting screen. Note that it is not necessary to display all of this information, and at least one or more of the dose determination reference value checks 503 to 506 and the dose determination reference value input fields 507 to 510 may be performed.

The set target dose index and the upper limit value and the lower limit value that are the allowable range of the dose warning function are stored in the determination unit 120. The determination unit 120 uses the target dose index to determine whether the dose index for the current imaging is within the allowable range. Specifically, the determination unit 120 compares the upper limit value of the permissible range of the target dose index with the dose index for this imaging, and determines whether or not the current dose index is large. Furthermore, the determination unit 120 compares the lower limit value of the allowable range of the target dose index with the dose index of the current imaging, and determines whether or not the dose index of this time is small. When it is determined that the dose index is outside the allowable range, the information generation unit 121 generates warning information.

FIG. 8 shows an example of a warning information display screen generated by the information generation unit 121. Specifically, the warning information 601, the imaging mode 602 of the target dose index corresponding to the selected examination order, and the dose index 603 acquired by the dose index acquisition unit 115 in the current imaging are displayed. Further, the target dose index 604 held in the holding unit 114 and the allowable range information 605 set in the dose determination reference value input fields 507 to 510 are displayed. As the warning information 601, for example, "a dose index exceeds the allowable range upper limit value of the target dose index for grid imaging. Please check the settings of the radiation generator or the imaging conditions." The display control unit 120 displays on the display unit 40 a screen displaying the radiation image image-processed by the image processing unit 117, the warning information generated by the information generation unit 118, or the dose index and the target dose index. Control the display state of.

Note that it is not necessary to display all of these pieces of information, and at least one of the warning information 601 and the shooting mode 602 may be displayed. The information generation unit 121 does not generate warning information when the dose index acquired by the dose index acquisition unit 115 in the current imaging is within the allowable range.

Further, the determination unit 120 may determine whether or not the deviation index of the dose index is within a predetermined allowable range. When the determination unit 120 determines that the deviation index of the dose index is not within the allowable range (outside the allowable range), the information generation unit 121 generates warning information.

As described above, according to the radiation imaging system (radiation imaging apparatus) of the present embodiment, it is determined whether or not the dose index (deviation index) is within a preset allowable range, and the alarm information is notified to the operator. be able to. Therefore, the operator can set a dose suitable for radiography in the radiation generator 20.

Example 3 will be described with reference to FIGS. The difference from the first and second embodiments is that a grid mounting determination unit 130 that analyzes the image data output from the image capturing unit 101 and determines the mounting state of the grid 50 is provided, and the selection unit 113 corresponds to the mounting state of the grid. The point is to select the target dose index.

FIG. 9 is a diagram showing the configuration of the radiation imaging apparatus 10 of the present invention. The configuration other than the grid attachment determination unit 130 is similar to that of FIG.

The image processing unit 117 performs image processing on the image data output from the image capturing unit 101 and outputs the image data to the grid attachment determination unit 130. The grid attachment determination unit 130 determines from the image data whether or not the grid 50 is attached during the shooting. Specifically, the grid attachment determination unit 130 detects the presence or absence of grid stripes, which are stripe patterns generated by the grid 50 in the image data. Specifically, the grid attachment determination unit 130 determines whether or not there is a peak in a certain frequency component in the frequency spectrum obtained by frequency-analyzing the image data. The grid attachment determination unit 130 determines that the grid 50 is attached when the peak exists in the frequency spectrum, and determines that the grid 50 is not attached when the peak does not exist.

The grid attachment determination unit 130 outputs the attachment state of the grid 50 acquired by analyzing the image data to the selection unit 113. The selection unit 113 selects a target dose index for radiography based on the mounting state of the grid 50. Thus, when the grid 50 is attached to the radiation imaging apparatus 10, the selection unit 113 selects the target dose index EIt(glid). When the grid 50 is not attached to the radiation imaging apparatus 10, the selection unit 113 selects the target dose index EIt(glidless).

Here, the operation of the radiation imaging system of the present invention will be described using the flowchart shown in FIG.

Since each processing of step S501 to step S508 is the same as each processing of FIG. 5, detailed description will be omitted.

In step S1000, the grid mounting determination unit 130 determines from the image data captured by the capturing unit 101 whether or not the grid is mounted during the capturing. When the grid 50 is attached to the radiation imaging apparatus 10, the process proceeds to step S504, and when the grid 50 is not attached to the radiation imaging device 10, the process proceeds to step S505.

As described above, according to the radiation imaging system (radiation imaging apparatus) of this embodiment, it is possible to determine the mounting state of the grid 50 from the image data and select the target dose index. Therefore, the target dose index suitable for the imaging mode is selected without using the grid attachment detection unit 103, so that the operator can appropriately evaluate the dose index.

Example 4 will be described with reference to FIGS. 2 and 9. The difference from the first to third embodiments is that the selection unit 113 selects the target dose index according to the type of the grid 50.

The grid attachment detection unit 103 shown in FIG. 1 detects the type of the grid 50. The grid 50 is provided with a marker for identifying the type of grid. The type of the grid 50 can be detected by the grid attachment detection unit 103 reading the marker. Further, the grid attachment determination unit 130 illustrated in FIG. 9 can analyze the image data output from the imaging unit 101 and detect the type of the grid 50 based on the grid stripe that is the stripe pattern generated by the grid 50. ..

The grid 50 is attached so as to cover the imaging unit 101 of the radiation imaging apparatus 10. The grid 50 includes a plurality of metal foils and absorbs scattered rays scattered by the subject 30 among the radiation generated from the radiation generator 10 and transmitted through the subject 30.

The type of grid 50 is defined by the grid ratio and the grid density. The grid ratio is the ratio of the height of a metal foil to the distance between adjacent metal foils. The grid ratio is, for example, 6:1, 8:1, 10:1 or the like. The grid density is the number of metal foils per 1 cm in width. The grid density is, for example, 40 lines/cm, 60 lines/cm, 80 lines/cm, or the like.

The grid attachment detection unit 103 or the grid attachment determination unit 130 can detect that the grid 50 attached to the radiation imaging apparatus 10 has a grid ratio of 6:1 and a grid density of 60 lines/cm, for example.

The selection unit 113 selects a target dose index according to the type of grid 50. For example, if the grid density (80 lines/cm) of the grid 50 is high, the radiation is blocked by the grid 50, so a relatively low target dose index is selected. If the grid density (40 lines/cm) of the grid 50 is low, a relatively high target dose index is selected.

As described above, according to the radiation imaging system (radiation imaging apparatus) of the present exemplary embodiment, the target dose index suitable for the type of the grid 50 is selected, so that the operator can appropriately evaluate the dose index.

Example 5 will be described with reference to FIG. The difference from the first to fourth embodiments is that the selection unit 113 selects the target dose index according to the image processing in the image processing unit 117.

Although it has been described that the grid 50 is attached to the radiation imaging apparatus 10 according to the imaged region of the subject 30, the grid 50 is not attached if the image processing (scattered ray reduction processing) of the image processing unit 117 is performed. Sometimes it becomes. For example, the grid 50 may not be attached to the radiation imaging apparatus 10 even if the imaging region of the subject 30 is the abdomen. When the scattered radiation reduction processing is performed in the image processing unit 117, it can be recognized that the grid 50 is not attached to the radiation imaging apparatus 10. That is, when the scattered radiation reduction processing is performed in the image processing unit 117, the target dose index EIt(glidless) is selected by the selection unit 113 as in the case where the grid 50 is not attached to the radiation imaging apparatus 10.

As described above, according to the radiation imaging system (radiation imaging apparatus) of the present embodiment, the mounting state of the grid 50 is determined according to the image processing (scattered radiation reduction processing) of the image processing unit 117, and the target dose index is selected. You can Therefore, the target dose index suitable for the imaging mode is selected without using the grid attachment detection unit 103, so that the operator can appropriately evaluate the dose index.

As described above, the present invention supplies a program for realizing one or more functions (particularly the dose index management method) of the above-described embodiment to a radiation imaging system or a radiation imaging apparatus via a network or a storage medium, and the radiation imaging system or It can also be realized by a process in which one or more processors in the computer of the radiation imaging apparatus read and execute the program. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

10 Radiography apparatus 20 Radiation generator 30 Subject 40 Display section 50 Grid 60 Input section 101 Imaging section 102 Control section 111 Setting section 112 Storage section 113 Selection section 114 Holding section 115 Dose index acquisition section 116 Calculation section 117 Image processing section 118 display control unit

Claims (17)

Selection means for selecting a target dose index in radiography based on the radiography imaging mode;
A dose index acquisition means for acquiring a dose index from image data based on the radiation transmitted through the subject;
A radiation imaging apparatus comprising: a calculation unit that calculates a deviation index of the dose index with respect to the target dose index. The radiographic imaging apparatus according to claim 1, wherein the radiographic imaging mode is a mounted state of a grid that blocks scattered rays based on radiation. When the grid is attached to the radiation imaging apparatus, the selection unit selects the first target dose index, and when the grid is not attached to the radiation imaging apparatus, the selection unit selects the second target dose index. The radiation imaging apparatus according to claim 2, wherein: The storage means for storing a plurality of target dose indexes is provided, and the selection means selects one target dose index from the plurality of target dose indexes based on an imaging mode of radiography. The radiographic apparatus described. The storage unit identifies a target dose index assuming a case where a grid for shielding scattered rays based on radiation is attached to the radiation imaging apparatus and a target dose index assuming a case where the grid is not attached to the radiation imaging apparatus. The radiation imaging apparatus according to claim 4, wherein the radiation imaging apparatus is stored. The radiation imaging apparatus according to claim 1, further comprising: a determination unit that determines whether or not the deviation index of the dose index is within a preset allowable range. 7. The radiation imaging apparatus according to claim 6, further comprising an information generating unit that generates warning information when the determination unit determines that the deviation index of the dose index is not within the allowable range. The radiation imaging apparatus according to claim 1, further comprising a grid mounting determination unit that analyzes the image data and determines a mounting state of a grid. The radiation imaging apparatus according to claim 1, wherein the selection unit selects the target dose index according to a type of a grid that blocks scattered radiation based on radiation. The radiation imaging apparatus according to claim 1, wherein the selection unit selects the target dose index according to image processing of the image data by an image processing unit. The radiation imaging apparatus according to claim 1, further comprising: display control means for displaying a deviation index of the dose index with respect to the target dose index on a display unit together with the information on the imaging mode of the radiation imaging. Selection means for selecting a target dose index for radiography, based on the radiography imaging mode;
A dose index acquisition means for acquiring a dose index from image data based on the radiation transmitted through the subject;
A radiation imaging apparatus comprising: the target dose index and display control means for displaying the dose index on a display unit together with the information on the imaging mode of the radiation imaging. The radiation imaging apparatus according to claim 12, further comprising a determination unit that determines whether or not the dose index is within a preset allowable range. 14. The radiation imaging apparatus according to claim 13, further comprising information generating means for generating warning information when the determining means determines that the dose index is not within the allowable range. A radiation imaging system comprising: the radiation imaging apparatus according to claim 1; and a radiation generation apparatus that generates radiation. Selecting a target dose index for radiography based on the radiography imaging mode;
Acquiring a dose index from image data based on the radiation transmitted through the subject, and
Calculating a deviation index of the dose index with respect to the target dose index. Selecting a target dose index for radiography based on the radiography imaging mode;
Acquiring a dose index from image data based on the radiation transmitted through the subject, and
A dose index management method, comprising: displaying the target dose index and the dose index on a display unit together with the information on the radiographic imaging mode.

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