阅读说明：本技术 放射线摄像装置及其控制方法、系统和存储介质 (Radiation imaging apparatus, control method, system, and storage medium thereof ) 是由 小林重夫 于 2021-05-19 设计创作，主要内容包括：本发明公开了放射线摄像装置及其控制方法、系统和存储介质。放射线摄像装置包括：预先存储分别对应于多个摄像模式的多个第一增益校正数据的第一存储器；具有更高读取速度的第二存储器；控制单元在放射线摄像装置启动后,基于存储的多个第一增益校正数据,在第二存储器中存储分别与多个第一增益校正数据对应的多个第二增益校正数据。在从放射线摄像装置启动到将所有第二增益校正数据存储到第二存储器期间,当用户发出摄像请求且对应于摄像模式的请求的增益校正数据已存储在第二存储器中时,在请求的摄像模式下执行放射线图像数据和偏移校正数据的获取以及通过使用偏移校正数据和所请求的增益校正数据对放射线图像数据执行校正处理。(The invention discloses a radiation imaging apparatus, a control method, a system and a storage medium thereof. The radiation imaging apparatus includes: a first memory that stores in advance a plurality of first gain correction data respectively corresponding to a plurality of image capturing modes; a second memory having a higher read speed; the control unit stores, in the second memory, a plurality of second gain correction data corresponding to the plurality of first gain correction data, respectively, based on the plurality of first gain correction data stored after the radiation imaging apparatus is activated. During startup from the radiation imaging apparatus to storage of all the second gain correction data in the second memory, when an imaging request is made by a user and gain correction data corresponding to the request of the imaging mode has been stored in the second memory, acquisition of radiation image data and offset correction data and correction processing on the radiation image data by using the offset correction data and the requested gain correction data are performed in the requested imaging mode.)

1. A radiation imaging apparatus, comprising:

a first memory that stores in advance a plurality of first gain correction data corresponding to a plurality of image capturing modes, respectively;

a second memory having a higher reading speed than the first memory; and

a control unit capable of performing image capturing in a plurality of image capturing modes,

wherein the control unit stores, after the activation of the radiation imaging apparatus, a plurality of second gain correction data respectively corresponding to the plurality of first gain correction data in the second memory based on the plurality of first gain correction data stored in the first memory, and

during a period from start-up of the radiation imaging apparatus to storage of all the second gain correction data in the second memory, when an imaging request is issued by a user and gain correction data corresponding to a request of an imaging mode associated with the imaging request among the plurality of second gain correction data has been stored in the second memory, acquisition of radiation image data and offset correction data is performed in the requested imaging mode and correction processing is performed on the radiation image data by using the offset correction data and the requested gain correction data stored in the second memory.

2. The apparatus of claim 1, wherein the plurality of first gain correction data forms a first group and a second group, each of the first group and the second group including no less than one gain correction data, and

a control unit that stores first group corresponding data of a plurality of second gain correction data corresponding to the first group data in the second memory based on first group data included in the first group in the plurality of first gain correction data, and then stores second group corresponding data of a plurality of second gain correction data corresponding to the second group data in the second memory based on second group data included in the second group in the plurality of first correction data, and

during a period during storage after the first group of data is stored in the second memory, when an imaging request is made by a user and the requested gain correction data is included in the first group of corresponding data, acquisition of radiation image data and offset correction data in the requested imaging mode is started.

3. The apparatus according to claim 2, wherein the control unit does not accept a photographing request from the user until all of the first set of corresponding data is stored in the second memory.

4. The apparatus of claim 2, further comprising a notification unit configured to notify storage of all of the first set of corresponding data in the second memory.

5. The apparatus according to claim 2, further comprising a notifying unit configured to notify second gain correction data stored in a second memory in the storage period among the plurality of second gain correction data.

6. The apparatus according to claim 4, wherein said notifying unit notifies storage of all of said plurality of second gain correction data in the second memory.

7. The apparatus according to claim 1, wherein the apparatus acquires offset correction data in the requested imaging mode before acquiring radiation image data in the requested imaging mode.

8. The apparatus according to claim 1, wherein said control unit reads out the plurality of first gain correction data stored in said first memory in a predetermined order and stores the plurality of second gain correction data corresponding to the plurality of first gain correction data in said second memory in a predetermined order, and

the predetermined sequence can be set by the user.

9. The apparatus of claim 1, wherein the second memory comprises a volatile memory.

10. The apparatus according to claim 1, further comprising a third memory configured to store offset correction data acquired in the requested image capture mode.

11. The apparatus of claim 10, wherein the third memory has a higher read speed than the first memory.

12. The apparatus of claim 10, wherein the third memory comprises a volatile memory.

13. A radiation imaging system comprising:

the radiation imaging apparatus according to any one of claims 1 to 12; and

a radiation generator configured to irradiate the radiation imaging apparatus with radiation.

14. A control method for a radiation imaging apparatus that includes a first memory that stores in advance a plurality of first gain correction data respectively corresponding to a plurality of imaging modes and a second memory having a higher reading speed than the first memory and that is capable of performing imaging in the plurality of imaging modes, the method comprising:

after the radiation imaging apparatus is started up, all of the second gain correction data respectively corresponding to the plurality of first gain correction data are stored in the second memory based on the plurality of first gain correction data stored in the first memory, and

when the user issues an image capturing request in the storage, and gain correction data corresponding to a request of an image capturing mode associated with the image capturing request among the plurality of second gain correction data has been stored in the second memory, acquisition of radiation image data and offset correction data in the requested image capturing mode and correction processing on the radiation image data by using the offset correction data and the requested gain correction data stored in the second memory are performed.

15. A non-volatile computer-readable storage medium storing a program for causing a computer to execute a method of controlling a radiation imaging apparatus that includes a first memory in which a plurality of first gain correction data respectively corresponding to a plurality of imaging modes are stored in advance and a second memory having a higher reading speed than the first memory and is capable of performing imaging in the plurality of imaging modes, the method comprising:

after the radiation imaging apparatus is started up, all of the second gain correction data respectively corresponding to the plurality of first gain correction data are stored in the second memory based on the plurality of first gain correction data stored in the first memory, and

when the user issues an image capturing request in the storage, and gain correction data corresponding to a request of an image capturing mode associated with the image capturing request among the plurality of second gain correction data has been stored in the second memory, acquisition of radiation image data and offset correction data in the requested image capturing mode and correction processing on the radiation image data by using the offset correction data and the requested gain correction data stored in the second memory are performed.

Technical Field

The invention relates to a radiation imaging apparatus, a radiation imaging system, a control method for the radiation imaging apparatus, and a nonvolatile computer storage medium.

Background

Radiographic apparatuses are widely used for medical image diagnosis and nondestructive inspection. Japanese patent laid-open No. 2016-. Offset correction and gain correction are performed in imaging in a plurality of imaging modes to obtain radiographic images suitable for the respective imaging modes. Since characteristics such as the amount of offset tend to change depending on the environment such as temperature, data for offset correction is acquired without irradiation of radiation after the power of the radiation imaging apparatus is turned on. Since the data for gain correction is robust against the influence of temperature and the like, it is possible to record the data in a nonvolatile memory or the like in advance and use the data by reading out into a fast memory for arithmetic processing after the power of the radiation imaging apparatus is turned on. As the number of imaging modes increases, more time is required to acquire data for offset correction and read data for gain correction, resulting in a longer time to prepare for imaging from when the power of the radiation imaging apparatus is turned on. Japanese patent laid-open No. 2016-198209 discloses a technique of making an imaging preparation including acquiring data for offset correction in descending order of priority according to an imaging mode and reading out the data for gain correction into a flash memory. Even when the image capturing preparation is performed, image capturing in the image capturing mode in which the image capturing preparation has been completed is permitted.

Disclosure of Invention

According to japanese patent laid-open No. 2016-198209, data for offset correction in all image capturing modes is acquired after the power is turned on, and therefore it takes a lot of time until image capturing preparations in all image capturing modes are completed. Further, the characteristics of offset correction tend to change depending on the environment such as temperature. Therefore, after acquiring data for offset correction, characteristics such as an offset amount may change with time when actual image capturing is performed.

Some embodiments of the present invention provide a technique advantageous to shorten the time until imaging can be performed by a radiographic imaging apparatus and improve the quality of an acquired radiographic image.

According to various embodiments, there is provided a radiation imaging apparatus including: a first memory that stores in advance a plurality of first gain correction data corresponding to a plurality of image capturing modes, respectively; a second memory having a higher reading speed than the first memory; and a control unit capable of performing imaging in a plurality of imaging modes, wherein the control unit, after the activation of the radiation imaging apparatus, based on the plurality of first gain correction data stored in the first memory, a plurality of second gain correcting data respectively corresponding to the plurality of first gain correcting data are stored in a second memory, and during the period from the startup of the radiation imaging apparatus to the storage of all the second gain correction data in the second memory, when the user issues an image capture request and the gain correction data corresponding to the request of the requested image capture mode associated with the image capture request among the plurality of second gain correction data has been stored in the second memory, acquisition of radiation image data and offset correction data is performed in the requested image capturing mode and correction processing is performed on the radiation image data by using the offset correction data and the requested gain correction data stored in the second memory.

According to another embodiment, there is provided a control method for a radiation imaging apparatus that includes a first memory that stores in advance a plurality of first gain correction data respectively corresponding to a plurality of imaging modes and a second memory having a higher reading speed than the first memory and is capable of performing imaging in the plurality of imaging modes, the method including: after the radiation imaging apparatus is started up, all of the second gain correction data respectively corresponding to the plurality of first gain correction data are stored in the second memory based on the plurality of first gain correction data stored in the first memory, and when an imaging request is made by a user in the storage and the gain correction data corresponding to a request of an imaging mode associated with the imaging request among the plurality of second gain correction data has been stored in the second memory, the acquisition of radiation image data and offset correction data is performed in the requested imaging mode and correction processing is performed on the radiation image data by using the offset correction data and the requested gain correction data stored in the second memory.

According to another embodiment, there is provided a nonvolatile computer-readable storage medium storing a program for causing a computer to execute a method of controlling a radiation imaging apparatus including a first memory that stores a plurality of first gain correction data respectively corresponding to a plurality of imaging modes in advance and a second memory having a higher reading speed than the first memory and capable of performing imaging in the plurality of imaging modes, the method including: after the radiation imaging apparatus is started up, all of the second gain correction data respectively corresponding to the plurality of first gain correction data are stored in the second memory based on the plurality of first gain correction data stored in the first memory, and when an imaging request is issued by a user in the storage and the gain correction data corresponding to a request of an imaging mode associated with the imaging request among the plurality of second gain correction data has been stored in the second memory, the acquisition of radiation image data and offset correction data is performed in the requested imaging mode and correction processing is performed on the radiation image data by using the offset correction data and the requested gain correction data stored in the second memory.

Further features of the invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).

Drawings

Fig. 1 is a diagram illustrating an example of the arrangement of a radiation imaging system including a radiation imaging apparatus according to an embodiment;

fig. 2 is a block diagram for explaining an image data correction operation of the radiation imaging apparatus in fig. 1;

fig. 3 is a diagram illustrating an imaging mode of the radiation imaging apparatus in fig. 1;

fig. 4 is a view showing the degree of priority of the imaging mode of the radiation imaging apparatus in fig. 1;

fig. 5 is a flowchart illustrating an outline of gain correction data expansion processing of the radiation imaging apparatus in fig. 1;

fig. 6 is a flowchart illustrating an outline of gain correction data expansion processing of the radiation imaging apparatus in fig. 1;

fig. 7 is a flowchart illustrating an imaging process of the radiation imaging apparatus in fig. 1;

fig. 8 is a diagram showing an expansion sequence of an imaging mode of the radiation imaging apparatus in fig. 1; and

fig. 9 is a flowchart illustrating gain correction data expansion processing performed by the radiation imaging apparatus in fig. 1.

Detailed Description

Embodiments of the present invention will be described below with reference to the accompanying drawings. It is noted that the following examples are not intended to limit the scope of the claimed invention. A plurality of features are described in the embodiments, but the invention which requires all of these features is not limited, and a plurality of such features may be combined as appropriate. Further, in the drawings, the same or similar configurations are given the same reference numerals, and redundant description thereof is omitted.

The radiation according to the present invention may include not only alpha rays, beta rays, and gamma rays, which are light beams generated by particles (including photons) emitted by radioactive decay, but also light beams having the same or more energy, such as X-rays, particle rays, and cosmic rays.

The arrangement and operation of the radiation imaging apparatus according to the present embodiment will be described with reference to fig. 1 to 7. Fig. 1 is a system block diagram illustrating an example of the overall arrangement of a radiation imaging system SYS including a radiation imaging apparatus 100 according to the first embodiment. The radiation imaging system SYS includes a radiation imaging apparatus 100, a computer 104, a radiation generator 105, a radiation controller 106, a display device 107, and a console 108, and is configured to image an object 109.

The radiation imaging apparatus 100 includes a scintillator 101, an imaging panel 102, a control unit 103, and memories 203, 204, and 205. The scintillator 101 is a conversion unit that converts radiation into light in a wavelength band that can be detected by detection elements arranged on the imaging panel 102. The control unit 103 has a function of controlling the entire radiation imaging apparatus 100. More specifically, the control unit 103 has a regulator function of receiving power supply from an external power supply or a built-in battery (not shown) and supplying power to the entire radiation imaging apparatus 100. The control unit 103 also has a function of driving the imaging panel 102, a function of reading radiation image data acquired by the imaging panel 102, and a function of performing correction processing on the radiation image data read from the imaging panel 102. The correction processing performed by the control unit 103 includes offset correction and gain correction. As the offset correction, a method of correcting radiation image data by using image data obtained without radiation irradiation as offset correction data is known. As the gain correction, a method of correcting radiation image data by using image data obtained by irradiation of radiation that does not pass through the object 109 as gain correction data is known.

The computer 104 has a function of controlling the entire radiation imaging system SYS in accordance with, for example, settings made by a user. The user inputs settings such as an imaging mode at the time of capturing a radiographic image to the computer 104 via the console 108. The computer 104 controls the radiation imaging apparatus 100 and the radiation controller 106 according to the set imaging mode. The radiation controller 106 causes the radiation generator 105 to operate under the control of the computer 104. The radiation generator 105 irradiates the radiation imaging apparatus 100 with radiation under the control of the radiation controller 106.

Fig. 2 is a block diagram illustrating the arrangement of the memories 203, 204, and 205 of the radiation imaging apparatus 100 and the procedure of the correction processing of the control unit 103. A plurality of first gain correction data respectively corresponding to a plurality of imaging modes are stored in the memory 205 in advance to allow the radiation imaging apparatus 100 to perform imaging in the plurality of imaging modes. After the activation of the radiation imaging apparatus 100, the control unit 103 stores, in the memory 204, a plurality of second gain correction data respectively corresponding to the plurality of first gain correction data based on the plurality of first gain correction data stored in the memory 205. In this case, the second gain correction data corresponding to the data of interest of the first gain correction data will be referred to as corresponding data. At this time, the data of interest may be the same as the corresponding data. That is, the corresponding data stored in the memory 204 may be data obtained by transferring the data of interest stored in the memory 205. In addition, for example, the data of interest may be data obtained by compressing the corresponding data, and the control unit 103 may store the corresponding data obtained by decompressing and expanding the data of interest in the memory 204. The memory 204 is a fast memory having a higher reading speed than the nonvolatile memory 205, and may be, for example, a volatile memory. When the data stored in the memory 205 is distinguished from the data stored in the memory 204, the respective data will be referred to as "first gain correction data" and "second gain correction data" as described above. In addition, when each data is simply referred to as "gain correction data", the data represents data stored in the memory 204 and used for gain correction.

Offset correction data for offset correction is acquired at the time of acquiring radiation image data after an imaging request is issued by a user and stored in the memory 203. The memory 203 is a fast memory having a higher reading speed than the nonvolatile memory 205, and may be, for example, a volatile memory. According to the arrangement shown in fig. 1 and 2, memory 203 and memory 204 are shown as separate components. However, it is not limited thereto, and one memory may be used as the memory 203 and the memory 204.

When the user issues an imaging request, the control unit 103 acquires radiation image data and offset correction data. The offset correction data is stored in the memory 203. Then, the control unit 103 performs correction processing on the radiation image data by using the offset correction data stored in the memory 203 and the second gain correction data stored in the memory 204. For example, as shown in fig. 2, the offset correction unit 201 of the control unit 103 performs offset correction processing on radiation image data read out from the imaging panel 102 as an input image by using offset correction data stored in the memory 203. Subsequently, the gain correction unit 202 of the control unit 103 performs gain correction processing using the gain correction data stored in the memory 204, and transmits the resultant data as an output image to the computer 104.

Next, an imaging mode of the radiation imaging apparatus 100 will be described with reference to fig. 3 and 4. Fig. 3 and 4 show examples of image capturing modes that can be edited and used by a user in accordance with usage conditions and the like. Fig. 3 is a table showing a list of imaging modes in which the radiation imaging apparatus 100 can perform imaging. The radiation imaging apparatus 100 has a plurality of imaging modes, each having a combination of an angle of view, a frame rate, sensitivity, and the like corresponding to an imaging technique. Each image pickup mode is assigned an image pickup mode number to be managed. The first gain correction data is linked to the image sensing mode number and stored in the nonvolatile memory 205. Fig. 4 shows an example of grouping the image capturing modes shown in fig. 3 according to priority. Referring to fig. 3, the imaging modes that need to be used immediately after the activation of the radiation imaging apparatus 100 are classified into a priority imaging mode group, and the remaining imaging modes are classified into a normal imaging mode group. The grouping between the priority imaging mode group and the normal imaging mode group may be performed at the time of shipment from the factory, or may be performed by the user in accordance with the use condition of the radiation imaging apparatus 100.

The operation of the radiation imaging apparatus 100 during the period from the startup of the radiation imaging apparatus 100 to the storage of all the gain correction data in the memory 204 will be described below with reference to the flowchart of fig. 5.

First, in step S101, the control unit 103 acquires an image capture mode number belonging to the priority image capture mode group shown in fig. 4. In step S102, the control unit 103 then reads data of the plurality of first gain correction data stored in the memory 205, the data corresponding to the image capturing modes in the priority image capturing mode group in a predetermined order, and stores second gain correction data corresponding to the first gain correction data in the memory 204 in the predetermined order. When all the gain correction data corresponding to the priority image capturing mode group are completely stored in the memory 204, the control unit 103 notifies the computer 104 that the storage of the gain correction data of the priority image capturing mode group into the memory 204 has been completed (step S103). According to this operation, the computer 104 can notify that the storage of all the gain correction data corresponding to the priority image capturing mode group to the memory 204 has been completed by using the display device 107. In other words, the display device 107 may function as a notification unit of the radiation imaging apparatus 100. Alternatively, for example, the radiation imaging apparatus 100 may include a display and a lamp, and have the display and the lamp as a notification unit that storage of all gain correction data corresponding to the priority imaging mode group in the memory 204 has been completed.

After the storage of the gain correction data corresponding to the priority image capturing mode group is completed, the flow proceeds to step S104. Then, the control unit 103 acquires an image pickup mode number belonging to the normal image pickup mode group shown in fig. 3. In step S105, the control unit 103 reads data in a predetermined order among the plurality of first gain correction data stored in the memory 205, the data corresponding to the normal image capturing mode group in the predetermined order, and stores second gain correction data corresponding to the first gain correction data in the memory 204 in the predetermined order. After the storage of all the gain correction data corresponding to the normal image capturing mode group into the memory 204 is completed, the control unit 103 notifies the computer 104 that the storage of all the gain correction data into the memory 204 is completed (step S106). According to this operation, the computer 104 can notify that the storage of all gain correction data to the memory 204 has been completed by using the display device 107. Further, as described above, the radiation imaging apparatus 100 may include a display and a lamp, and notify that storing all the gain correction data to the memory 204 has been completed by causing the display or the lamp to function as a notification unit. Through the above-described operation, the control unit 103 terminates the step of storing all the second gain correction data corresponding to the plurality of first gain correction data in the memory 204 based on the plurality of first gain correction data stored in the memory 205 at the time of startup of the radiation imaging apparatus 100.

The operation of the radiation imaging apparatus 100 upon receiving an imaging request from the user during the period from the startup of the radiation imaging apparatus 100 to the storage of all gain correction data into the memory 204 will be described below with reference to flowcharts shown in fig. 6 and 7. Steps S201 to S203 may be performed in a similar manner to steps S101 to S103, and thus their description will be omitted.

The control unit 103 notifies the computer 104 that the storage of the gain correction data corresponding to the priority image capturing mode group into the memory 204 has been completed, and then determines whether an image capturing request from the user is received in step S204. When it is determined in step S204 that an image capturing request from the user is received, the control unit 103 shifts the process to step S205 to determine whether the requested image capturing mode associated with the image capturing request is included in the priority image capturing mode group. When it is determined in step S204 that an image capturing request is not received from the user, the control unit 103 shifts the process to step S207.

When it is determined in step S205 that the requested image capturing mode is included in the priority image capturing mode group, the control unit 103 shifts the process to step S206 to execute the image capturing process. The image capturing process will be described later with reference to fig. 7. When it is determined in step S205 that the requested image capturing mode is not included in the priority image capturing mode group, the control unit 103 shifts the process to step S207.

Step S207 and subsequent steps will be described next. In step S207, the control unit 103 determines whether or not the gain correction data in all the image capturing modes is stored in the memory 204. When it is determined in step S207 that the storage of the gain correction data in all the image capturing modes in the memory 204 has not been completed, the control unit 103 shifts the process to step S208. In step S208, the control unit 103 acquires information of image capturing modes of the normal image capturing mode group for which storage of gain correction data has not been completed. In step S209, the control unit 103 reads out the first gain correction data in the image capturing mode obtained in step S208 from the memory 205, and stores the corresponding second gain correction data in the memory 204. After completion of step S209, the control unit 103 returns the process of determining the image capturing request from the user to step S204, and repeats the steps from step S204 onward.

When it is determined in step S207 that the storage of the gain correction data in all the image capturing modes in the memory 204 has been completed, the control unit 103 shifts the process to step S210. As described in the above-described step S106, in step S210, the control unit 103 notifies the computer 104 that the storage of all the gain correction data in the memory 204 has been completed. In step S211, the control unit is set to the device operation condition in which the storage period has ended and all the image capturing modes can be used.

The image capturing process in step S206 in fig. 6 will be described next with reference to fig. 7. First, in step S301, the control unit 103 sets image capturing conditions such as an angle of view, a frame rate, and sensitivity corresponding to a requested image capturing mode corresponding to an image capturing request. In step S302, the control unit 103 then acquires offset correction data by performing image capturing without radiation irradiation, and stores the data in the memory 203. In step S303, the control unit 103 acquires radiation image data by irradiating the object 109 with radiation to image it. In step S304, the control unit 103 executes offset correction and gain correction processing shown in fig. 2 as described above by using the radiation image data obtained in step S303 as an input image, and transfers the subject output image to the computer 104, thereby terminating the imaging processing. In the flowchart shown in fig. 7, the radiation imaging apparatus 100 acquires offset correction data in the requested imaging mode before acquiring radiation image data in the requested imaging mode corresponding to the imaging request. However, it is not limited thereto. The radiation imaging apparatus 100 can acquire offset correction data after acquiring radiation image data.

In the present embodiment, the plurality of first gain correction data respectively corresponding to the plurality of image capturing modes constitute a priority group corresponding to a priority image capturing mode group and a normal group corresponding to a normal image capturing mode group, each group including one or more gain correction data. After the radiation imaging apparatus 100 is activated, the control unit 103 stores priority group corresponding data of second gain correction data corresponding to the priority group data in the memory 204 based on the priority group data included in the priority group in the first gain correction data (steps S201 to S203). Then, the control unit 103 stores the normal group corresponding data of the second gain correction data corresponding to the normal group data in the memory 204 based on the normal group data included in the normal group in the first gain correction data (steps S207 to S209). At this time, in a period after the priority group data is stored in the memory 204, when the user issues an image capturing request and requested gain correction data corresponding to the requested image capturing mode (associated with the image capturing request) of the second gain correction data is included in the priority group corresponding data, the control unit 103 starts acquisition of radiation image data and offset correction data in the requested image capturing mode corresponding to the image capturing request (step S206).

As described above, in the radiation imaging apparatus 100, the second gain correction data corresponding to the first gain correction data corresponding to the priority imaging mode having a high priority among the imaging modes allowing imaging is stored in the memory 204 in advance. Then, the second gain correction data corresponding to the first gain correction data corresponding to the normal image capturing mode is stored in the memory 204. Radiation image data can be acquired when a user issues an imaging request in a priority imaging mode in a period after second gain correction data corresponding to first gain correction data corresponding to the priority imaging mode is stored in a memory. Therefore, when the user issues an imaging request in the priority imaging mode in a period in which the second gain correction data corresponding to the normal imaging mode is stored in the memory 204, radiation image data can be acquired. This shortens the time until imaging can be performed in the priority imaging mode after the radiation imaging apparatus 100 is started up. In addition, in the present embodiment, when acquiring radiation image data, the radiation imaging apparatus acquires offset correction data. Since the amount of shift changes in characteristics depending on the environment such as temperature, acquiring the shift correction data before or after acquiring the radiation image data can cope with the change in characteristics. This can improve the quality of the corrected radiographic image. In the present embodiment, after the radiation imaging apparatus 100 is started up, the apparatus does not acquire offset correction data corresponding to all imaging modes. This also enables shortening of the time until image capturing can be performed in all image capturing modes.

In the present embodiment, the control unit 103 may not accept an image capturing request from the user until all priority group corresponding data corresponding to the priority image capturing mode group is stored in the memory 204. That is, as shown in fig. 6, the control unit 103 may not determine whether an image capturing request is issued by the user until the storage of the gain correction data in the priority image capturing mode group to the memory 204 is completed in step S203 and the process shifts to step S204.

A modification of the above-described first embodiment of the operation of the radiation imaging apparatus 100 when an imaging request is issued by a user during a period from the startup of the radiation imaging apparatus 100 to the storage of all gain correction data in the memory 204 will be described below with reference to fig. 8 and 9. Fig. 8 is a diagram showing the order of storing gain correction data in the memory 204 according to the second embodiment. Fig. 9 is a flowchart for explaining the operation of the radiation imaging apparatus 100 when the user issues an imaging request during the period from the startup of the radiation imaging apparatus 100 to the storage of all the gain correction data in the memory 204 according to the second embodiment. The arrangement of the radiation imaging apparatus 100 and the type of the imaging mode are similar to those in the first embodiment, and thus the description thereof will be omitted.

Fig. 8 shows a list of the imaging modes shown in fig. 3, which are rearranged in the order in which the respective information is stored in the memory 204 after the power of the radiation imaging apparatus 100 is turned on. The control unit 103 reads out the plurality of first gain correction data stored in the memory 205 in a predetermined order, and stores the plurality of second gain correction data corresponding to the plurality of first gain correction data in the memory 204 in a predetermined order. The user may set the order in which the second gain correction data is stored in the memory 204. The second gain correction data corresponding to the image capturing mode having a high frequency of use or a high possibility of use in an emergency is first stored in the memory 204. This can shorten the time from the start-up of the radiation imaging apparatus 100 until imaging can be performed in an imaging mode having a high frequency of use or a high possibility of use in an emergency.

Next, an operation to be performed when an imaging request is input from the user during a period from the startup of the radiation imaging apparatus 100 to the storage of all the gain correction data in the memory 204 will be described with reference to a flowchart shown in fig. 9. After the radiation imaging apparatus 100 is started up, the control unit 103 starts storing a plurality of gain correction data in the memory 204, and determines whether an imaging request is issued by the user in step S401. When it is determined in step S401 that an image capturing request is issued by the user, the control unit 103 shifts the process to step S402. In step S402, the control unit 103 determines whether requested gain correction data corresponding to the requested image capture mode associated with the image capture request among the plurality of gain correction data has been stored in the memory 204. When it is determined in step S401 that the image capturing request has not been issued, the control unit 103 shifts the process to step S404.

When it is determined in step S402 that the requested gain correction data corresponding to the image capturing mode corresponding to the image capturing request has been stored in the memory 204, the control unit 103 shifts the process to step S403 to execute the image capturing process. The image capturing process in step S403 may be similar to the image capturing process in step S206 shown in fig. 6, and each of steps S301 to S304 in fig. 7 may be executed. When it is determined in step S402 that the requested gain correction data is not stored in the memory 204, the control unit 103 shifts the process to step S404.

Step S404 and subsequent steps will be described next. In step S404, the control unit 103 determines whether gain correction data corresponding to all image capturing modes has been stored in the memory 204.

When it is determined in step S404 that the storage of all the gain correction data in the memory 204 has not been completed, the control unit 103 moves the process to step S405. In step S405, the control unit 103 acquires information of an image capturing mode in which the gain correction data is not completely stored. In step S406, the control unit 103 reads the first gain correction data in the image capturing mode obtained in step S405 from the memory 205, and stores the corresponding second gain correction data in the memory 204. In step S407, the control unit 103 notifies the computer 104 that an image capturing mode corresponding to the gain correction data stored in step S406 can be used. According to this operation, the computer 104 can notify the gain correction data stored in the memory 204 among the plurality of gain correction data using the display device 107. In other words, the display device 107 can function as a notification unit of the radiation imaging apparatus 100. Alternatively, the radiation imaging apparatus 100 may include a display and a lamp, and cause the display and the lamp to serve as a notification unit to notify the gain correction data stored in the memory 204 among the plurality of gain correction data.

When it is determined in step S402 that any requested gain correction data is not stored in the memory 204, the control unit 103 may preferentially read out data corresponding to the requested gain correction data from the memory 205 in the order shown in fig. 8 and store the data in the memory 204 in steps S405 and S406. Further, in step S407, the display device 107 or the radiation imaging apparatus 100 may notify that the requested gain correction data is stored in the memory 204 using a display, a lamp, or the like. This can realize a more user-friendly radiation imaging apparatus.

After completion of step S407, the control unit 103 returns to step S401 to determine an image capturing request from the user, and repeats the steps from step S401. When it is determined in step S404 that the gain correction data in all the image capturing modes have been completely stored in the memory 204, the control unit 103 moves the process to step S408. In step S408, the control unit 103 notifies the computer 104 of completion of gain data development (gain data development) in all image capturing modes. According to the notification, the computer 104 can notify that all gain correction data has been completely stored in the memory 204 using the display device 107. Alternatively, as described above, the radiation imaging apparatus 100 may include a display and a lamp, and have the display and the lamp function as a notification unit to notify that the storage of all the gain correction data in the memory 204 is completed. In step S409, the control unit is set to the device operation condition in which the storage period ends and all the image capturing modes can be used.

After the activation of the radiation imaging apparatus 100, the control unit 103 stores a plurality of second gain correction data respectively corresponding to the plurality of first gain correction data in the memory 204 based on the plurality of first gain correction data stored in the memory 205. In the present embodiment, during a period from the startup of the radiation imaging apparatus 100 to the storage of all gain correction data in the memory 204, when an imaging request is issued by a user and gain correction data corresponding to a request of an imaging mode associated with the imaging request among the gain correction data is stored in the memory 204, the control unit 103 acquires radiation image data and offset correction data in the requested imaging mode. Then, the control unit 103 performs correction processing on the radiation image data by using the requested gain correction data and offset correction data stored in the memory 204. This can shorten the time from the start-up of the radiation imaging apparatus 100 until imaging can be performed in an imaging mode having a high frequency of use or a high possibility of use in an emergency. Also in the present embodiment, when radiation image data is acquired, offset correction data is acquired. This can cope with a change in characteristics such as the shift amount, and improve the quality of the corrected radiographic image. In addition, in the present embodiment, after the start-up of the radiation imaging apparatus 100, the apparatus does not acquire offset correction data corresponding to all imaging modes. This also enables shortening of the time until image capturing is performed in all image capturing modes.

Other embodiments

The embodiments of the present invention can also be realized by a method in which software (programs) that perform the functions of the above-described embodiments are supplied to a system or an apparatus through a network or various storage media, and a computer or a Central Processing Unit (CPU), a Micro Processing Unit (MPU) of the system or the apparatus reads out and executes the methods of the programs.

While the present invention has been described in connection with the exemplary embodiments, it should be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all modifications and equivalent structures and functions.