JP2019115557A - Radiography apparatus and radiography system - Google Patents

Abstract

To provide a technique advantageous for displaying a preview image in capturing a radiographic image.SOLUTION: A radiography apparatus includes: an image capturing unit for capturing a radiographic image; a storage unit for storing offset image data for offset correction of the radiographic image; and an image processing unit; the radiography apparatus being capable of capturing images in a plurality of imaging modes. The plurality of imaging modes includes a first imaging mode and a second imaging mode, each of the imaging modes allowing capturing of an image of which image size is different from an image captured in the other imaging mode. The image processing unit, when image capturing in the first mode is followed by image capturing in the second mode, outputs preview image data of the image captured in the second mode on the basis of the radiographic image data generated by the image capturing unit in the image capturing in the second mode and of correction image data generated in accordance with the image size of the image captured in second mode from the offset image data obtained by the image capturing in the first mode and stored in the storage unit.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a radiation imaging apparatus and a radiation imaging system.

  In medical image diagnosis and nondestructive inspection, a radiation imaging apparatus using a flat panel detector (flat panel detector: FPD) made of a semiconductor material is widely used. In FPD, even in the absence of radiation, a charge called dark charge is generated. When the dark charge is superimposed on the signal charge generated by the radiation irradiation, the non-uniform offset component is added to the image and the image quality is degraded. In order to prevent this, it is performed to correct an offset component caused by dark charge on image data obtained by irradiation of radiation. When an offset component is acquired after imaging of a radiation image and the radiation image is corrected, the waiting time until the radiation image is displayed becomes long. In imaging where it is difficult to keep still for a long time, such as imaging of a child, after imaging a radiation image, in order to judge whether the captured image can be used for diagnosis, the preview image has a short waiting time It needs to be displayed.

  Patent Document 1 discloses that correction data for correcting an offset, a temperature when acquiring the correction data, and an integration time are stored in the storage unit in advance. When imaging a radiation image, the correction data is corrected using a correction equation based on the temperature at the time of imaging, the integration time, the temperature at the time of acquisition of the correction data, and the integration time. By applying this corrected correction data to the data of the imaged radiation image, it becomes possible to display the preview image in a short time after the imaging.

JP, 2006-239117, A

  In the imaging of a radiation image, imaging is performed under various conditions such as imaging of moving images and still images and resolution of each image. Depending on the imaging conditions, the calorific value of the circuit disposed in the FPD or the circuit for operating the FPD disposed in the radiation imaging apparatus may change, and a temperature distribution may occur in the plane of the FPD. When a temperature distribution occurs in the plane of the FPD, the generation characteristic of dark charge changes accordingly. Since the temperature in the plane of the FPD may have a different distribution with respect to one temperature in the radiation imaging apparatus, in the correction shown in Patent Document 1, the image quality of the preview image may be degraded depending on the imaging conditions There is sex.

  An object of the present invention is to provide an advantageous technique for displaying a preview image in capturing a radiation image.

  In view of the above problems, a radiation imaging apparatus according to an embodiment of the present invention includes an imaging unit for capturing a radiation image, a storage unit for storing offset image data for performing offset correction of the radiation image, and image processing A radiation imaging apparatus including an imaging unit capable of imaging in a plurality of imaging modes, the plurality of imaging modes including a first imaging mode and a second imaging mode for performing imaging with mutually different image sizes, When imaging in the second imaging mode after imaging in the first imaging mode, the image processing unit stores radiation image data generated by the imaging unit in imaging in the second imaging mode, and the storage unit. The second imaging mode is generated based on the offset image data obtained by imaging in the first imaging mode and the correction image data generated according to the image size of imaging in the second imaging mode. And outputs the preview image data in the imaging.

  The above means provide an advantageous technique for displaying a preview image in capturing a radiation image.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the structural example of the radiation imaging system using the radiation imaging device which concerns on embodiment of this invention. FIG. 2 is a view showing an example of the arrangement of an imaging unit of the radiation imaging apparatus of FIG. FIG. 2 is a view for explaining imaging using the radiation imaging apparatus of FIG. 1; FIG. 2 is a view for explaining imaging using the radiation imaging apparatus of FIG. 1; FIG. 2 is a view for explaining imaging using the radiation imaging apparatus of FIG. 1; A diagram for explaining imaging using the radiation imaging apparatus of FIG. 1 The figure which shows the timing which acquires offset image data.

  Hereinafter, specific embodiments of a radiation imaging system according to the present invention will be described with reference to the attached drawings. In the following description and the drawings, the same reference numerals are given to the same configuration throughout the plurality of drawings. Therefore, the common configuration will be described with reference to a plurality of drawings, and the description of the configuration having the same reference numeral will be omitted as appropriate. Moreover, in the present invention, in addition to alpha rays, beta rays, gamma rays, etc. which are beams produced by particles (including photons) emitted by radiation decay, beams having similar or higher energy, for example X It may also include rays, particle rays, cosmic rays, etc.

First Embodiment The configuration and operation of a radiation imaging apparatus 101 according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a schematic view showing a configuration example of a radiation imaging system 100 using the radiation imaging apparatus 101 according to the first embodiment of the present invention. The radiation imaging system 100 includes a radiation imaging apparatus 101, a radiation source 109 for irradiating the radiation imaging apparatus 101 with radiation, and a control unit 113 for controlling each configuration of the radiation imaging system 100.

  The radiation imaging apparatus 101 acquires radiation image data of the subject 112 based on the radiation 111 emitted from the radiation source 109 and transmitted through the subject 112. For the radiation imaging apparatus 101, a flat panel detector (FPD) or the like can be used.

  The radiation imaging apparatus 101 includes an imaging unit 200 that generates image data according to the incident radiation to capture a radiation image, and an imaging control unit 102. The imaging control unit 102 relates to a drive control unit 106 that performs drive control of the imaging unit 200, an image processing unit 107 that performs various image processing on captured image data, storage of image data, determination of transfer timing, and transfer control. It includes a transfer control unit 108 that performs processing. The image data processed by the imaging control unit 102 is transferred to the control unit 113 or the like. Further, the radiation imaging apparatus 101 includes a wireless communication unit 103, a storage unit 104, and a power supply 105. Furthermore, the radiation imaging apparatus 101 can include a temperature monitoring unit 119.

  The image processing unit 107 performs image processing including, for example, processing for correcting defects and offsets of an image and processing for reducing various noises. In addition, a preview image generation process may be performed in which reduced image data for preview is generated using data output from a part of pixels of the captured image data. The image processing unit 107 does not need to transfer to the control unit 113 and perform all the processing required to create the image data to be displayed on the display unit 114, and only the necessary processing may be performed. The image processing unit 107 may perform minimum necessary processing on the image data generated by the imaging of the imaging unit 200, and the control unit 113 may perform the remaining image processing, for example.

  The transfer control unit 108 performs transfer control of the image data on which the image processing necessary for the image processing unit 107 has been performed. Here, the transfer control includes a transfer determination process of determining whether to transfer the image data generated by the imaging unit 200 to the control unit 113. Not only when the entire image data is output from the image processing unit 107, but also when preview image data generated from part of the captured image data may be output. When only partial pixel data is thinned out as preview image data and transferred first, the remaining pixel data not used in the preview image data may be output as untransferred image data.

  Here, the transfer determination process refers to the information of the radiation imaging system 100 at the time of moving image imaging for acquiring radiation images continuously, and determines whether to transfer image data acquired for each frame to the control unit 113 in real time Do. The image data of each frame determined to be required to be transferred in real time is immediately transferred to the control unit 113 by the wireless communication unit 103. All acquired image data of each frame may be stored in the storage unit 104 regardless of whether the transfer is performed in real time or not.

  In the configuration shown in FIG. 1, the drive control unit 106, the image processing unit 107, and the transfer control unit 108 are included in the imaging control unit 102, but the configuration is not limited to this. For example, the image processing unit 107 and the transfer control unit 108 may be configured independently of the imaging control unit 102.

  The storage unit 104 is a unit for storing the image data generated by the imaging unit 200. In addition, the storage unit 104 may store together the image data processed by the image processing unit 107 and various information attached to the image data. For example, devices such as flash memory can be used. The various information attached to the image data includes, for example, information on a patient who has been photographed, information on a photographer, information on a region to be photographed, information on a date and time of photographing, and identification of an acquisition frame when a moving image is photographed. Including information such as unique ID for. One or some of these pieces of information can be combined and stored in association with image data. Further, transfer execution information as to whether or not image data has been transferred in real time by the transfer control unit 108 described above may be stored in association with the image data. The storage unit 104 may store defect information, gain information, offset information, etc. of pixels arranged in the imaging unit 200 for use in image correction, and the operation log of the radiation imaging apparatus 101 may be stored. It may be done.

  The wireless communication unit 103 is a unit for wirelessly transmitting image data and the like stored in the storage unit 104 to the control unit 113 and the like outside the radiation imaging apparatus 101 under the control of the transfer control unit 108. including. Further, the information communicated by the wireless communication unit 103 is not limited to image data. The information communicated by the wireless communication unit 103 may include command communication such as operation mode setting for the radiation imaging apparatus 101 from the control unit 113 and status confirmation of the radiation imaging apparatus 101. Further, the information communicated by the wireless communication unit 103 includes radiation imaging such as an imaging start request signal and stop request signal according to the imaging switch of the radiation control unit 110, a radiation irradiation available period notification output from the radiation imaging apparatus 101, etc. Synchronization information etc. may be included. In the configuration shown in FIG. 1, the radiation imaging apparatus 101 is connected to the control unit 113 by wireless communication, but may be connected by wired communication.

  The power supply 105 is an operation power supply unit of the radiation imaging apparatus 101. The power source 105 may be configured as a battery detachable from the radiation imaging apparatus 101, or may be configured as a battery or a capacitor that can be charged by receiving an external power supply. In addition, the power supply 105 may not have a charging function such as a battery. In this case, the power supply 105 may only have a function of converting a power supply voltage supplied from the outside into a voltage corresponding to each component in the radiation imaging apparatus 101.

  The temperature monitoring unit 119 includes a temperature sensor disposed in a housing 120 in which the imaging unit 200 of the radiation imaging apparatus 101 is disposed. The temperature monitoring unit 119 has a role of monitoring the temperature in the housing 120 in which the imaging unit 200 is disposed.

  The control unit 113 is a unit that performs various controls such as the operation of the radiation imaging system 100, the control of an imaging mode, and the processing of image data captured by the radiation imaging apparatus 101. The control unit can use various computers, workstations, and the like. The control unit 113 can be connected to a display unit 114 such as a control menu or a display for displaying a captured radiation image or the like, and an input device 115 such as a mouse or a keyboard for performing various inputs.

  The radiation source 109 includes an electron gun, a rotor, and the like for generating the radiation 111. In the radiation source 109, radiation is generated as the electrons are accelerated by the high voltage generated by the radiation control unit 110 and collide with the rotor. The radiation control unit 110 may be connected to a switch for the user to request radiation imaging, such as an irradiation switch or a fluoroscopic pedal, or an operation unit for the user to set radiation irradiation conditions and the like.

  In the configuration shown in FIG. 1, communication between the radiation imaging apparatus 101 and the control unit 113 is performed by a wireless LAN via the access point 116. However, the present invention is not limited to this configuration, and either the radiation imaging apparatus 101 or the control unit 113 may directly communicate as the access point without passing through the access point 116. The communication between the radiation imaging apparatus 101 and the control unit 113 may use another wireless communication means such as Bluetooth (registered trademark) instead of the wireless LAN.

  Further, an interface unit 118 is provided between the control unit 113 and the radiation control unit 110. The interface unit 118 has a circuit that mediates communication performed between the radiation imaging apparatus 101 and the radiation control unit 110, and relays exchange of synchronization signals and the like. By monitoring the states of the radiation imaging apparatus 101 and the radiation control unit 110, for example, the irradiation timing of the radiation from the radiation source 109 can be adjusted according to the state of the radiation imaging apparatus 101. Furthermore, the interface unit 118 is also connected to the control unit 113, so that exchange of various control signals and information can be relayed between the components of the radiation imaging system 100.

  The interface unit 118 is connected to the control unit 113 by Ethernet (registered trademark) via the HUB 117 in the configuration shown in FIG. The HUB 117 is a unit for connecting a plurality of network devices. Furthermore, by connecting the access point 116 to the HUB 117, it is also connected to the radiation imaging apparatus 101 via the wireless LAN.

  FIG. 2 is a view showing a configuration example of the imaging unit 200. As shown in FIG. The imaging unit 200 includes a sensor array 204 including a plurality of pixels arranged in a two-dimensional array so as to configure a plurality of rows and a plurality of columns. Each of the pixels 207 arranged in the sensor array 204 includes, for example, a switch element 208 such as a thin film transistor (TFT) and a photoelectric conversion element 209. In addition, a scintillator (not shown) is disposed to cover each pixel 207. In this case, radiation incident on the imaging unit 200 is converted into light of a wavelength detectable by the photoelectric conversion element 209 by the scintillator, and the converted light is incident on the photoelectric conversion element 209 of each pixel 207, and the photoelectric conversion element At 209, charge is generated according to the incident light. In the present embodiment, the configuration of a conversion element that converts incident radiation into charge by the scintillator and the photoelectric conversion element 209 will be described. However, a configuration may be made using a direct conversion type conversion element that directly converts incident radiation into charge without arranging a scintillator. By switching the switch element 208 between ON and OFF, charge accumulation and charge readout can be performed, and image data generated by the imaging unit 200 can be acquired.

  In the pixels 207 in any row on the sensor array 204 of the imaging unit 200, when the drive circuit 201 applies a voltage for turning on the switch element 208 to the drive line 211, the switch elements 208 of each pixel 207 in the row are turned on. ON works. As a result, the charge of each of the pixels 207 arranged in the row connected to the drive line 211 to which the voltage is applied is transferred to the sample and hold circuit 202 through the signal line 210 corresponding to each of the pixels 207. Will be held by Thereafter, the held charges are sequentially read out via the multiplexer 203, amplified by the amplifier 205, and then converted by the A / D converter 206 into digital value image data. Further, in the row in which the charge readout is completed, the drive circuit 201 applies a voltage to the drive line 211 to turn off the switch element 208. As a result, the respective pixels 207 arranged in the corresponding row return to the state of accumulating charge. As described above, the drive circuit 201 sequentially scans each row of the sensor array 204, and finally the charges output from all the pixels 207 are converted into digital values. Thereby, radiation image data can be read out. The control of the driving and the reading operation of the imaging unit 200 can be performed by the drive control unit 106 of the imaging control unit 102 illustrated in FIG. 1. Further, the image data converted into the digital value can be stored in the storage unit 104 shown in FIG.

  Next, imaging of a radiation image by the radiation imaging apparatus 101 will be described. For example, in the case of capturing a moving image, the radiation imaging apparatus 101 performs imaging without applying radiation in advance for each mode such as a plurality of types of frame rates, and stores the obtained image data in the storage unit 104 as offset image data. . That is, under the control of the imaging control unit 102, the imaging unit 200 performs imaging for each mode in a state in which radiation is not irradiated, and the storage unit 104 offsets image data obtained by imaging without irradiating radiation. Remember as. Next, when imaging a radiation image, the image processing unit 107 extracts offset image data acquired in the corresponding imaging mode from the storage unit 104 as correction image data, and offsets the radiation image data imaged during radiation irradiation Do. As a result, there is no need to acquire offset image data for offset correction again after capturing a moving image, and a high frame rate is realized.

  If the offset image data acquired in advance and stored in the storage unit 104 is image data acquired under conditions that are significantly different from the conditions for actually capturing a moving image, the offset component is not sufficient even if offset correction is performed. It can not be removed. Therefore, while the radiation imaging apparatus 101 operates in the imaging mode for capturing a moving image, the offset image data for offset correction is updated to the latest state as needed during a period in which the moving image is not captured.

  On the other hand, when imaging a still image in the radiation imaging apparatus 101, basically, after imaging the still image, the imaging unit 200 performs imaging without irradiating radiation, and the storage unit 104 acquires the acquired offset image data. Remember. Next, the image processing unit 107 performs offset correction of the radiation image data, using the offset image data acquired after the imaging of the still image as the correction image data. In other words, in each of the imaging modes for imaging a moving image and a still image, the imaging unit 200 performs imaging in a state where radiation is not irradiated, and the storage unit 104 is image data obtained by imaging that does not irradiate radiation. Are stored as offset image data. By performing imaging for acquiring offset image data immediately after imaging a radiation image in imaging a still image, it is possible to acquire offset image data in a state where the imaging of the radiation image does not significantly change. As a result, the accuracy of the offset correction can be enhanced, and the image quality of the obtained still image can be improved.

  However, when offset image data for offset correction is acquired after imaging a radiation image, it takes a long time to display the corrected radiation image. In imaging where it is difficult to stand still for a long time, such as imaging of a child, after imaging a radiation image, in order to quickly determine whether the imaged image can be used for diagnosis, wait for a short time for the preview image It is necessary to display it by time. Therefore, when imaging a still image, the radiation imaging apparatus 101 according to the present embodiment performs offset correction using offset image data stored in advance in the storage unit 104 in order to display a preview image at high speed.

  The corrected preview image data is transferred to the control unit 113 via the wireless communication unit 103. Here, only the offset correction processing is described as the correction processing in the image processing unit 107. For example, correction processing such as correction of defective pixels, gain correction for correcting amplifier gain variations of the imaging unit 200, etc. It may be done. Further, these correction processes are not limited to the implementation by the image processing unit 107 of the radiation imaging apparatus 101, and for example, the acquired radiation image data and offset image data are transferred to the control unit 113, and Correction processing may be performed. Also, as offset image data used for offset correction processing, for example, even if a plurality of offset image data are obtained in advance by imaging a plurality of times and image data subjected to noise component reduction processing or the like by averaging or the like is used. Good.

  If the user determines that the captured image can be used for diagnosis by the preview image, the user is corrected for diagnostic using the imaging of the radiographic image and the offset image data captured immediately after the imaging of the radiographic image Wait until the radiation image is displayed. If the user determines that the captured image can not be used for diagnosis by the preview image, the user may immediately prepare for re-shooting.

  Next, a process of selecting offset image data to be used for offset correction from a plurality of offset image data stored in the storage unit 104 and using it to correct radiation image data will be described.

  As described above, the radiation imaging apparatus 101 is configured to be capable of imaging in a plurality of imaging modes such as moving images and still images. For example, the image size may be different in moving image capturing and still image capturing. This is because, in order to perform imaging at a high frame rate, there are cases where the image size is made smaller than imaging of a still image which performs precise imaging. In addition, even in the imaging mode for capturing a moving image, imaging with different image sizes and frame rates may be performed. Similarly, also in imaging of a still image, imaging with different image sizes may be performed depending on a site to be imaged. That is, the plurality of imaging modes may include a plurality of imaging modes in which imaging is performed with different image sizes. Therefore, as the offset image data stored in the storage unit 104, image data of various image sizes are stored, and the image size of the correction image data used for offset correction and the image size of the radiation image data may differ. In addition, when the imaging interval in the same imaging mode is wide, the offset component does not change due to the temperature change of the imaging unit 200 of the radiation imaging apparatus 101 and the like in the offset image data acquired in the same imaging mode. There is a possibility that correction can not be made.

  Here, with reference to FIG. 3, the case of performing imaging with different image sizes before and after will be briefly described. FIG. 3 shows a case where the radiation imaging apparatus 101 operating in the imaging mode for imaging a moving image is switched to the imaging mode for imaging a still image and imaged.

  As described above, while the radiation imaging apparatus 101 operates in an imaging mode for capturing a moving image, offset image data for offset correction is updated as needed for each mode such as a frame rate and stored in the storage unit 104. Ru. In FIG. 3, six types of offset image data of the offset image data 304 (1) to (6) are stored in the storage unit 104 in correspondence with each mode of the moving image imaging mode. Here, a case where the control unit 113 instructs the radiation imaging apparatus 101 operating in the imaging mode for capturing a moving image to switch to the imaging mode for capturing a still image will be described.

  When an instruction to switch the imaging mode is received, the radiation imaging apparatus 101 switches to an imaging mode for capturing a still image even when offset image data is updated in the imaging mode for capturing a moving image, and the still image is captured. Take an image of In this case, the correction image data used for offset correction of the preview image data may use offset image data acquired last among a plurality of offset image data acquired in the imaging mode for imaging a moving image. For example, consider the case of using offset image data 304 (1). At this time, the offset image data 304 (1) acquired in an imaging mode in which the image size is different from the imaging mode for imaging a still image can not be used as it is as data for correction for offset correction. Therefore, the image processing unit 107 uses the offset image data 304 (1) obtained by the imaging of the moving image stored in the storage unit 104 for correction according to the image size of the imaging of the still image. A processing unit 301 that generates the image data 311 is included. For example, the processing unit 301 of the image processing unit 107 may generate the correction image data 311 by enlarging or reducing the size of the offset image data according to the image size. Also, for example, when the offset image data is larger in image size than the radiation image data, a part of the offset image data may be used as the correction image data 311. In this case, the signal used for the correction image data 311 may be a signal output from the pixel 207 that outputs the radiation image data signal among the signals of the offset image data. That is, the image processing unit 107 previews the imaging of the still image imaging mode based on the radiation image data generated by the imaging unit 200 in imaging of the still image imaging mode and the generated correction image data 311. Output image data. More specifically, the image processing unit 107 corrects the radiation image data generated by the imaging unit 200 in imaging of the still image imaging mode using the generated correction image data 311. Then, the corrected radiation image data is output to the display unit 114 via the wireless communication unit 103 and the control unit 113 as preview image data of imaging in a still image imaging mode.

  Next, it will be described in more detail with reference to FIG. For example, the image processing unit 107 corrects the offset image data acquired at the end, in other words, the latest date and time, of the offset image data 304 (1) to (6) stored in the storage unit 104. Used as source data of data. This is because it is considered that the conditions and characteristics at the time of imaging such as the temperature of the imaging unit 200 at the time of imaging a radiation image are similar to the imaging at the current imaging mode. However, the offset image data acquired in the imaging mode for capturing a moving image (here, described as using the offset image data 304 (5)) has an image size different from the imaging mode for capturing a current still image. It is. Therefore, the processing unit 301 included in the image processing unit 107 performs processing according to the image size to generate the correction image data 311 in order to match the image size of the radiation image data at the time of capturing a still image. . Then, the image processing unit 107 corrects the radiation image data generated by the imaging unit 200 in imaging of the still image imaging mode using the generated correction image data 311. The imaging of the radiation image by the imaging unit 200 and the generation of the correction image data by the image processing unit 107 may be performed in parallel. Further, when the imaging mode is switched, the image processing unit 107 starts generation of correction image data according to the switched imaging mode, and the generated correction image data 311 is stored in the storage unit 104 or the image processing unit. It is stored in the temporary memory 302 of 107. Thereafter, offset correction may be performed on radiation image data generated by the imaging unit 200 in imaging in the imaging mode after switching, using the correction image data 311 generated and stored in advance.

  Thus, when imaging a radiation image, even if imaging is performed in imaging modes different from each other in image size, offset image data acquired in a situation where the condition of the radiation imaging apparatus 101 is closer is used for offset correction. Can. This ensures the quality of the preview image displayed by the corrected preview image data. In addition, the time until the preview image is displayed is shortened, and the user can quickly determine whether it is necessary to re-shoot.

  Here, in the method of selecting the offset image data 304 to generate the correction image data 311 out of the plurality of offset image data 304 (1) to (6), the offset image data 304 (5) acquired last is selected It is not limited to doing. For example, the imaging unit 200 performs a reset operation to reset the pixels 207 arranged in the imaging unit 200 before radiation irradiation. At this time, the image processing unit 107 calculates an average value of the reset signal data output by the reset operation. Next, the image processing unit 107 selects offset image data in which the average value of the signals of the image data is closest to the average value of the signals of the reset signal data among the plurality of offset image data 304 (1) to (6). The processing unit 301 may generate the correction image data 311 from the offset image data whose average value is close. At this time, it may take time to calculate the average value of the plurality of offset image data signals. Therefore, when acquiring offset image data, the image processing unit 107 calculates in advance the average value of the signals of the offset image data as data attached to the offset image data, and the storage unit 104 calculates the signal together with the offset image data. An average value may be stored.

  Furthermore, for example, in order to display a preview image at high speed, the image transfer from the radiation imaging apparatus 101 to the control unit 113 at an early stage is started, or to increase the transfer speed, the size of transferred data is reduced. It is conceivable. In order to realize this, for example, it is conceivable to reduce the resolution by thinning out radiation image data captured at the time of radiation irradiation. In this case, the processing unit 301 of the image processing unit 107 generates, from the offset image data 304, correction image data 311 according to not only the image size of the radiation image data but also the resolution of the preview image data. As described above, the correction image data 311 may be generated in advance from the offset image data 304 and stored in the storage unit 104 or the like. After the resolution of the radiation image data generated by the imaging unit 200 is reduced, the image processing unit 107 may correct the radiation image data using the correction image data 311 and output the corrected radiation image data as preview image data. . This can further reduce the time to display the preview image.

  Heretofore, the case has been described by way of example where the imaging is performed by switching from the imaging mode for capturing a moving image to the imaging mode for capturing a still image. However, the present invention is not limited to this. For example, even in the case of capturing a still image, the present invention can also be applied to correction between imaging modes that capture still images of different image sizes.

  Also, consider the case of operating in an imaging mode in which still images of the same image size are captured before and after. At this time, as shown in FIG. 5, a plurality of offset image data 304 acquired at any time from different image sizes in the imaging mode for capturing a moving image as offset image data stored in the storage unit 104 as previously captured. (1) to (3) may be included. In addition, the storage unit 104 may include offset image data 310 acquired after capturing of the previous still image. In this case, the image processing unit 107 selects, as the correction image data 311, the offset image data 310 acquired at the latest date and time among the plurality of offset image data stored in the storage unit 104 and corrects the radiation image data. To generate preview image data. This makes it possible to display the preview image more quickly than in the case of acquiring offset image data after imaging of a radiation image. In addition, since the offset image data acquired under the condition where the condition of the imaging unit 200 is close is used as the correction image data 311, it is possible to suppress the deterioration of the generated preview image.

Second Embodiment The configuration and operation of a radiation imaging apparatus 101 according to an embodiment of the present invention will be described with reference to FIGS. According to the second embodiment of the present invention, in the radiation imaging apparatus 101 shown in FIG. 1, the casing 120 outputted from the temperature monitoring unit 119 that monitors the temperature in the casing 120 in which the imaging unit 200 is disposed. Offset image data is acquired according to a change in temperature. That is, in a state in which radiation is not irradiated, the imaging unit 200 performs imaging according to a change in temperature output from the temperature monitoring unit 119, and the storage unit 104 acquires image data obtained by imaging that does not irradiate radiation. Are stored as offset image data. As shown in FIG. 6, the imaging control unit 102 receives the temperature in the housing 120 output from the temperature monitoring unit 119, and the imaging control unit 102 offsets the temperature in the housing 120 every time it changes by 1 ° C., for example. An operation for acquiring image data may be performed on the imaging unit 200 or the storage unit 104. The operation for acquiring offset image data may be performed each time the temperature changes by 1 ° C. or more, or may be every 2 ° C. or more, or every 5 ° C. or more. It is also good. Further, even for a change of 1 ° C. or less, an operation for acquiring offset image data may be performed. It may be set appropriately according to the configuration of the radiation imaging apparatus 101 and the type of radiation image to be imaged.

  As shown in FIG. 7, when the temperature fluctuation tends to increase or decrease, the radiation imaging apparatus 101 acquires offset image data 305 each time the temperature in the housing 120 changes. At this time, as illustrated in FIG. 6, the storage unit 104 may delete old offset image data and update it to new offset image data.

  In imaging of a radiation image to be imaged by irradiating radiation, the image processing unit 107 performs radiation using the offset image data 305 stored in the storage unit 104 before the imaging unit 200 captures a radiation image. The radiation image data generated by the imaging unit 200 in the imaging of the image is corrected. The image processing unit 107 outputs the corrected radiation image data as preview image data from the radiation imaging apparatus 101 to the control unit 113 via the wireless communication unit 103. The preview image data output to the control unit 113 is displayed on the display unit 114 as a preview image.

  When the temperature in the housing 120 tends to decrease, the radiation imaging apparatus 101 may not be used for a while. When imaging a radiation image in such a situation, even if the offset image data stored last is used, the temperature of the circuit arranged in the imaging unit 200 changes, and the distribution of the offset component changes. It is conceivable that Therefore, it is conceivable that the offset component can not be corrected sufficiently. In order to prevent such a situation, in the present embodiment, the temperature in the housing 120 is monitored, offset image data is acquired according to the change, and this is used for offset correction when generating preview image data. As a result, also in the present embodiment, as in the first embodiment described above, it is possible to display a preview image with high speed and good image quality.

  The offset image data 305 may be acquired in accordance with each of a plurality of imaging modes of the radiation imaging apparatus 101. Further, the offset image data 305 may be acquired in the imaging mode in which the frequency of use is high. Further, as described above, in the imaging mode for capturing a moving image, the offset image data 305 may be acquired according to a temperature change in the imaging mode for capturing a still image in order to acquire offset image data as needed. That is, the imaging unit 200 may perform imaging for acquiring the offset image data 305 under conditions according to the conditions for imaging a radiation image. In addition, the imaging unit 200 may perform imaging for acquiring the offset image data 305 under the same conditions as the imaging conditions of the still image of the radiation image.

  Also in the present embodiment, the imaging mode is to perform imaging of different image sizes for the previous imaging and the subsequent imaging, and the acquired offset image data 305 and radiation image data imaged by irradiating radiation are: Different image sizes may be used. In this case, the processing unit 301 of the image processing unit 107 generates correction image data corresponding to the image size of the radiation image data from the offset image data 305 as in the first embodiment described above. The image processing unit 107 may correct the radiation image data using the correction image data corrected from the offset image data 305 to generate preview image data.

  Further, offset image data can be acquired when the radiation imaging apparatus 101 is in a standby state, such as when the temperature in the housing 120 tends to decrease. For this reason, offset image data may be acquired in a mode for reading out an image having a small data size such as addition readout which consumes less power.

  In addition, also in the present embodiment, the preview image data may have a lower resolution than the captured radiation image data. By reducing the resolution of the preview image data, the amount of image data for displaying the preview image decreases, the amount of data transfer from the radiation imaging apparatus 101 to the control unit 113 is suppressed, and the preview image is displayed. Time can be suppressed.

  Although the embodiments according to the present invention have been described above, it goes without saying that the present invention is not limited to these embodiments, and the embodiments described above can be appropriately modified or combined without departing from the scope of the present invention. It is possible. For example, in the first embodiment, the temperature monitoring unit 119 may be used to monitor the temperature in the housing 120 of the radiation imaging apparatus 101. In each imaging mode, not only acquisition of offset image data corresponding to imaging of a radiation image but also offset image data is acquired by temperature change. For example, by acquiring offset image data according to a temperature change, for example, when there is an interval between imaging and imaging, the accuracy of correction using the correction image data can be enhanced.

101: radiation imaging apparatus, 104: storage unit, 107: image processing unit, 200: imaging unit, 301: processing unit

Claims (18)

A radiation imaging apparatus capable of imaging in a plurality of imaging modes, including an imaging unit for imaging a radiation image, a storage unit for storing offset image data for offset correction of the radiation image, and an image processing unit. There,
The plurality of imaging modes include a first imaging mode and a second imaging mode for performing imaging with different image sizes.
When the image processing unit performs imaging in the second imaging mode after imaging in the first imaging mode, radiation image data generated by the imaging unit in imaging in the second imaging mode; Based on the offset image data obtained by the imaging of the first imaging mode stored in the storage unit, and the correction image data generated according to the image size of the imaging of the second imaging mode A radiation imaging apparatus outputting preview image data of imaging in the second imaging mode.   The image processing unit generates the offset image data obtained by the imaging of the first imaging mode stored in the storage unit, the radiation image data generated by the imaging unit in the imaging of the second imaging mode Correction is performed using correction image data generated according to the image size of imaging in the second imaging mode, and the corrected radiation image data is output as preview image data of imaging in the second imaging mode The radiation imaging apparatus according to claim 1,   In each of the plurality of imaging modes, the imaging unit performs imaging in a state where radiation is not irradiated, and the storage unit stores, as the offset image data, image data obtained by imaging that does not irradiate radiation. The radiation imaging apparatus according to claim 1 or 2, wherein The radiation imaging apparatus further includes a housing in which the imaging unit is disposed, and a temperature monitoring unit for monitoring a temperature in the housing.
In the first imaging mode, the imaging unit performs imaging in a state where radiation is not irradiated according to a change in temperature output from the temperature monitoring unit, and the storage unit performs imaging by not irradiating radiation. The radiation image pickup apparatus according to any one of claims 1 to 3, wherein the obtained image data is stored in the storage unit as the offset image data.   The image processing unit uses the offset image data obtained by imaging in the first imaging mode stored in the storage unit to generate correction image data according to the image size of imaging in the second imaging mode. The radiation imaging apparatus according to any one of claims 1 to 4, further comprising a processing unit that generates the radiation. In the first imaging mode, the imaging unit performs imaging a plurality of times in a state where radiation is not irradiated, and the storage unit offsets each of the image data obtained by the plurality of imagings. Stored as data,
The radiation imaging according to claim 5, wherein the processing unit generates the correction image data from offset image data acquired last in the first imaging mode among the plurality of offset image data. apparatus. In the first imaging mode, the imaging unit performs imaging a plurality of times in a state where radiation is not irradiated, and the storage unit offsets each of the image data obtained by the plurality of imagings. Stored as data,
In the second imaging mode,
The imaging unit performs a reset operation to reset pixels arranged in the imaging unit before radiation irradiation.
The image processing unit calculates an average value of signals of reset signal data output by the reset operation,
The processing unit is characterized in that the correction image data is generated from offset image data in which an average value of signals of image data among the plurality of offset image data is closest to an average value of signals of the reset signal data. The radiation imaging device according to claim 5.   The radiation imaging apparatus according to any one of claims 1 to 7, wherein, in the first imaging mode, the imaging unit captures a moving image during irradiation of radiation.   The radiation imaging apparatus according to any one of claims 1 to 8, wherein, in the second imaging mode, the imaging unit captures a still image during irradiation of radiation. The preview image data has a lower resolution than the radiation image data,
The image processing unit
The image data for correction according to the image size of the radiation image data and the resolution of the preview image data are generated from the offset image data,
10. The radiation image data is reduced in resolution, then corrected using the correction image data, and the corrected radiation image data is output as preview image data. The radiation imaging device according to. An imaging unit for imaging a radiation image disposed in a housing, a storage unit for storing offset image data for offset correction of the radiation image, an image processing unit, and a temperature in the housing And a temperature monitoring unit for monitoring the
In a state in which radiation is not irradiated, the imaging unit performs imaging according to a change in temperature output from the temperature monitoring unit, and the storage unit performs image data obtained by imaging that does not irradiate radiation. Store as offset image data,
In imaging of a first radiation image which is irradiated and imaged with radiation,
The image processing unit is configured to capture the offset image data stored in the storage unit and the imaging unit before capturing the first radiation image before the imaging unit captures the first radiation image. What is claimed is: 1. A radiation imaging apparatus, which outputs preview image data on the basis of the radiation image data generated in the above.   In the imaging of the first radiation image, the image processing unit uses the offset image data stored in the storage unit before and before the imaging unit captures the first radiation image. The radiation imaging apparatus according to claim 11, wherein the radiation image data generated by the imaging unit is corrected, and the corrected radiation image data is output as the preview image data.   The radiation imaging apparatus according to claim 11, wherein the imaging unit performs imaging for acquiring the offset image data under conditions according to conditions for imaging the first radiation image.   The imaging unit according to any one of claims 11 to 13, wherein the imaging unit performs imaging for acquiring the offset image data under the same conditions as imaging conditions of the first radiation image. Radiation imaging device. The image processing unit includes a processing unit that generates correction image data corresponding to the image size of the radiation image data from the offset image data.
When the image sizes of the offset image data and the radiation image data are different, the radiation image data generated by the imaging unit in the imaging of the first radiation image is corrected using the correction image data, and the correction is performed. 12. The radiation imaging apparatus according to claim 11, wherein the selected radiation image data is output as preview image data.   The radiation imaging apparatus according to any one of claims 11 to 15, wherein the imaging of the first radiation image is imaging of a still image. The preview image data has a lower resolution than the radiation image data,
The image processing unit
Correction image data corresponding to the resolution of the preview image data is generated from the offset image data;
17. The radiation image data according to any one of claims 11 to 16, wherein the radiation image data is reduced in resolution and then corrected using the correction image data, and the corrected radiation image data is output as preview image data. The radiation imaging device according to. A radiation imaging apparatus according to any one of claims 1 to 17,
A radiation source for irradiating the radiation imaging apparatus with radiation;
Radiation imaging system.

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