JP2018023794A - Radiography apparatus and radiography system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make shorter than before the wait time until an image is displayed on an external device, while avoiding the risk of recapturing the image.SOLUTION: A radiography apparatus 10 includes a plurality of radiation detection panels 20 for detecting respective radiation made incident after being transmitted through a subject to generate radiographic images and arranged in a direction intersecting the incident direction of the radiation. The radiography apparatus 10 specifies a display target image from among a plurality of radiographic images respectively generated by the plurality of radiation detection panels 20, and transmits the specified display target image to a console 70. At least radiographic images other than the target image are stored in image memory 43. The console 70 displays on a display unit 71 the received display target image, and in response to information indicating a display request for a radiographic image other than the display target image, displays the radiographic image other than the display target image read from the image memory 43 on the display unit 71.SELECTED DRAWING: Figure 5

Description

  The disclosed technology relates to a radiographic imaging apparatus and a radiographic imaging system.

  In recent years, radiation detection panels such as an FPD (Flat Panel Detector) capable of directly converting radiation into digital data by arranging a radiation sensitive layer on a TFT (Thin Film Transistor) active matrix substrate have been put into practical use. In addition, a radiographic imaging apparatus such as an electronic cassette that generates a radiographic image represented by irradiated radiation using a radiation detection panel has been put into practical use. As a method of converting radiation into an electrical signal, there are an indirect conversion method in which radiation is converted into light by a scintillator and then converted into charges by a photodiode, a direct conversion method in which radiation is converted into charges by a semiconductor layer containing amorphous selenium, etc. is there. In each system, there are various materials that can be used for the semiconductor layer of the radiation detection panel.

  In a radiographic imaging device, in order to enable imaging over a relatively wide range such as chest X-ray imaging, a plurality of radiation detection panels are arranged in a line along an imaging surface and are long. Yes. For example, in Patent Document 1, a plurality of sensor units each including an X-ray detection unit (CsI) provided on an imaging surface of an image detection unit (CCD: Charge Coupling Device) are arranged so that a part of the captured image overlaps. In the X-ray image sensor having an expanded imaging range, an X-ray imaging apparatus is described in which the outer shape of the X-ray detection means does not exceed the effective imaging range of each image detection means and falls within the overlapping range. Has been.

  In addition, a system in which a radiographic image capturing apparatus having an FPD and a console are communicably connected is known. For example, Patent Documents 2 and 3 describe a medical image system including an FPD cassette and a console.

  The FPD cassettes described in Patent Document 2 and Patent Document 3 include radiation detection means in which a plurality of elements that convert radiation transmitted through a subject into electrical signals are two-dimensionally arranged, and electrical signals acquired by the radiation detection means. Reading means for reading and generating image data of a subject, divided image data generating means for dividing the image data generated by the reading means into divided image data, transmission management means for setting the transmission order of the divided image data, and transmission Detector communication means for transmitting the divided image data to the outside according to the order. The consoles described in Patent Literature 2 and Patent Literature 3 include display means having a two-dimensional display area, console communication means for acquiring divided image data from an FPD cassette, and display control means for controlling the display means. Have.

  In Patent Document 2, the detector communication means transmits the division setting and transmission order as auxiliary data together with the divided image data, and the display control means sets the display area of the display means based on the division setting in the auxiliary data. It is described that the image data is divided into a plurality of divided display areas, and the divided image data acquired by the console communication means is assigned to each divided display area based on the transmission order in the accompanying data and displayed on the display means. .

  In Patent Document 3, the display control means divides the display area of the display means into a plurality of divided display areas based on the imaging part information, and the divided image data acquired by the console communication means according to a predetermined allocation order. It is described that each divided display area is assigned and displayed in each divided display area.

JP 2000-292546 A JP 2010-222752 A JP 2010-17296 A

  As described in Patent Document 1, it is possible to perform imaging over a relatively wide range by connecting a plurality of radiation detection panels to form a long radiation image capturing apparatus. However, there is a case where it is desired to take a radiographic image using only some of the radiation detection panels constituting the long radiographic imaging device. In such a case, if all of the images generated by each of the plurality of radiation detection panels are transmitted to an external device having a display unit such as a console, the time until the image is displayed on the display unit of the external device is long. The workflow is degraded.

  Therefore, it is conceivable to transmit only an image generated by a radiation detection panel (hereinafter referred to as “use panel”) used for imaging to an external device such as a console. As a result, the number of images transmitted from the radiographic imaging device to an external device such as a console can be reduced, so that the waiting time until image display can be shortened. However, there may be a case where the subject is reflected in another radiation detection panel other than the use panel or the use panel is not properly specified. In such a case, if imaging is not performed on a radiation detection panel other than the use panel, or if an image generated on a radiation detection panel other than the use panel is not stored, the Shooting may be required.

  The disclosed technology has been made in view of the above points, and among the plurality of radiation detection panels juxtaposed in a direction crossing the radiation incident direction, images generated by some radiation detection panels are externally provided. An object of the present invention is to reduce the waiting time until image display on an external device, while avoiding the risk of re-shooting, when displaying on the display unit of the device.

  According to the technique of the disclosure, based on radiation that has a plurality of radiation image capturing units and a control unit that controls the plurality of radiation image capturing units, and is simultaneously irradiated to the plurality of radiation image capturing units. A plurality of radiation imaging units each including a first radiation imaging unit and a second radiation imaging unit, wherein each of the plurality of radiation imaging units is a radiation imaging system. A sensor that detects a radiographic image signal, a signal processing unit that reads and processes the radiographic image signal, and a communication unit that outputs a radiographic image based on the radiographic image signal, and the control means includes: In response to the completion of the transmission of the radiation image from the first radiation imaging unit, the second radiation imaging unit is notified, and the second radiation imaging unit responds to the notification with a radiation image. The Radiographic imaging system is provided for the force.

  According to the disclosed technique, a radiographic imaging system is provided in which the second radiographic imaging unit restricts transmission of radiographic images until a notification is received after the radiographic image signal is read.

  According to the disclosed technology, the radiographic imaging system further includes a display control unit that displays a synthesized image obtained by synthesizing the radiographic images on the display unit when reception of radiographic images from a plurality of radiographic imaging units is completed. Is provided.

  According to the disclosed technology, the radiographic imaging system that causes the display control unit to display an image based on the received radiographic image on the display unit when the reception of the radiographic image from the first radiographic imaging unit is completed. Provided.

  According to the disclosed technology, the control unit transmits a radiological image transmission request to the second radiographic unit after an image based on the radiographic image transmitted from the first radiographic unit is displayed on the display unit. A radiographic imaging system is provided.

  According to the disclosed technique, a plurality of radiation detection panels, each of which detects radiation incident through a subject to generate radiation image data and is juxtaposed in a direction intersecting the radiation incidence direction, A designation unit that designates image data of a display target image among image data of a plurality of radiation images generated by each of a plurality of radiation detection panels, and at least image data of the display target image among the plurality of radiation images In response to completion of transmission of the display target image from the first radiation detection panel of the plurality of radiation detection panels and a transmission unit that transmits to the outside of the radiation image capturing apparatus, the plurality of radiation detection panels A control unit for notifying a second radiation detection panel different from the first radiation detection panel, and the second radiation detection panel , Radiographic imaging apparatus is provided which outputs a display target image in response to the notification.

  According to the disclosed technique, the designation unit is provided for each of the plurality of radiation detection panels and outputs a detection signal having a magnitude corresponding to the dose of the irradiated radiation. A radiographic imaging device that designates a display target image on the basis thereof is provided.

  According to the disclosed technology, the designation unit is provided with a radiographic imaging device that designates a display target image based on attribute information indicating an attribute of a subject.

  According to the disclosed technique, the designation unit is provided with a radiographic imaging device that designates a display target image based on information that designates the display target image supplied from the outside of the radiographic imaging device.

  According to the disclosed technology, an external device provided outside the radiographic image capturing apparatus provides a detection signal corresponding to each of the plurality of radiation detection panels and having a magnitude corresponding to the dose of the irradiated radiation. Radiation image capturing that determines the presence or absence of a subject on each radiation detection panel based on a detection signal from each of the sensors to be output, and the designation unit designates a display target image based on the result of determination of the presence or absence of the subject by an external device An apparatus is provided.

  According to the technology disclosed herein, the transmission unit derives the transmission order of the image data of the plurality of display target images when the plurality of images are designated as the display target images, and the plurality of display target images according to the derived transmission order. A radiographic image capturing apparatus that sequentially transmits the image data to the outside of the radiographic image capturing apparatus is provided.

  According to the disclosed technique, the transmission unit is provided for each of the plurality of radiation detection panels and outputs a detection signal having a magnitude corresponding to the dose of the irradiated radiation. A radiographic imaging apparatus that derives the transmission order of image data of a plurality of display target images based on the image data is provided.

  According to the disclosed technology, a radiographic imaging apparatus is provided in which the transmission unit derives the transmission order of image data of a plurality of display target images based on attribute information indicating an attribute of a subject.

  According to the disclosed technology, the transmission unit specifies the transmission order of the image data of each of the plurality of display target images supplied from the outside of the radiographic imaging device when the plurality of images are specified as display target images. There is provided a radiographic imaging apparatus that sequentially transmits image data of a plurality of display target images to the outside of the radiographic imaging apparatus in accordance with a transmission order indicated by the information to be transmitted.

  According to the disclosed technology, when a plurality of images are designated as display target images, an external device provided outside the radiation image capturing device is provided corresponding to each of the plurality of radiation detection panels and irradiated. The transmission order of the image data of the plurality of display target images is derived based on the detection signal from each of the sensors that output a detection signal having a magnitude corresponding to the dose of the emitted radiation, and the transmission unit derives the derived transmission order Accordingly, there is provided a radiographic imaging apparatus that sequentially transmits image data of a plurality of display target images to the outside of the radiographic imaging apparatus.

  According to the disclosed technology, each of the plurality of radiation detection panels is arranged so that the adjacent radiation detection panels and the end portions of the imaging regions capable of generating a radiation image are overlapped with each other, and the transmission unit is Of the image data of the two display target images generated by each of the radiation detection panels, the image data to be transmitted later is determined from the portion corresponding to the end portion on the side adjacent to the image indicated by the previously transmitted image data. There is provided a radiographic imaging apparatus that sequentially transmits to the outside of the radiographic imaging apparatus.

  According to the technology disclosed herein, each of the plurality of radiation detection panels is arranged such that the adjacent radiation detection panels and the end portions of the imaging regions capable of generating a radiation image are overlapped with each other, and the transmission unit is not a display target image. There is provided a radiographic imaging apparatus that transmits image data of an image portion included in a predetermined range starting from an end portion adjacent to a display target image among radiographic images to the outside of the radiographic imaging apparatus.

  According to the disclosed technology, each of the plurality of radiation detection panels shares detection information indicating that radiation is detected by any of the radiation detection panels, and shifts to a radiographic image capturing operation based on the detection information. A radiographic imaging device is provided.

  According to the disclosed technology, each of the plurality of radiation detection panels is arranged such that the adjacent radiation detection panels and the end portions of the imaging region capable of generating a radiation image overlap each other in the radiation irradiation direction, Generate image data of a radiographic image other than the display target image adjacent to the first radiation detection panel arranged on the downstream side in the radiation irradiation direction for generating the image data of the display target image among the plurality of radiation detection panels. Among the radiation images generated by the second radiation detection panel arranged upstream in the radiation irradiation direction, at least the overlap of the imaging region of the first radiation detection panel and the imaging region of the second radiation detection panel overlaps each other. Provided is a radiographic imaging apparatus that transmits image data of an image portion corresponding to a section as image data of a correction image to the outside of the radiographic imaging apparatus.

  According to the disclosed technology, the transmission unit identifies and identifies a subject image spread range based on a point spread function based on information indicating at least one of a subject attribute, a plurality of radiation images, and imaging conditions. In the case where the expansion range of the subject image is included in the radiation image other than the display target image, the image data of at least the image portion including the expansion range of the subject image is included in the radiation image other than the display target image. Provided is a radiographic image capturing apparatus that transmits image data of a correction image to the outside of the radiographic image capturing apparatus.

  According to the disclosed technology, the image processing apparatus further includes a storage medium that stores at least image data of a radiation image other than the display target image among the plurality of radiation images, and the transmission unit stores the image data of the display target image among the plurality of radiation images. Provided is a radiographic image capturing device that transmits to the outside of the radiographic image capturing device.

  According to the disclosed technique, the radiographic image capturing apparatus, a storage medium that stores image data of radiographic images other than at least the display target image among a plurality of radiographic images, and a display target image received from the radiographic image capturing apparatus are stored. A control device having a display control unit that displays on a display unit and displays a radiographic image other than a display target image indicated by image data stored in a storage medium together with the display target image when the display is requested; A radiographic imaging system is provided.

  According to the disclosed technique, the radiographic image capturing apparatus described above, a storage medium that stores image data of a radiographic image other than at least a display target image among a plurality of radiographic images, and image data received from the radiographic image capturing apparatus are indicated. The display target image is displayed on the display unit, and when there is a display request, a radiation image other than the display target image indicated by the image data stored in the storage medium is displayed on the display unit together with the display target image. There is provided a radiographic imaging system including a control device having a display control unit that corrects a display target image indicated by image data generated by a radiation detection panel using a correction image.

  According to the technique of the disclosure, the display control unit, except for the image portion corresponding to the overlapping portion, among the display target images indicated by the image data generated by the first radiation detection panel, from the image portion corresponding to the overlapping portion. In addition, there is provided a radiographic imaging system that is displayed on a display unit before, and an image portion corresponding to the overlapping portion is corrected using a correction image and then displayed on the display unit.

  According to the disclosed technique, the radiographic image capturing apparatus described above, a storage medium that stores image data of a radiographic image other than at least a display target image among a plurality of radiographic images, and image data received from the radiographic image capturing apparatus are indicated. The display target image is displayed on the display unit, and when there is a display request, a radiation image other than the display target image indicated by the image data stored in the storage medium is displayed on the display unit together with the display target image. And a control apparatus having a display control unit that corrects the image using a correction image.

  According to the disclosed technology, a radiographic imaging device and a display target image indicated by image data received from the radiographic imaging device are displayed on a display unit, and a display target stored in a storage medium when a display request is made Control having a display control unit that requests the radiographic imaging device to transmit image data of a radiographic image other than an image and causes the display unit to display a radiographic image other than the display target image indicated by the image data received from the radiographic imaging device And a radiographic imaging system including the apparatus.

  According to the disclosed technology, the display control unit is a radiographic imaging system that causes a display unit to display a plurality of display target images in the order received when image data of a plurality of display target images is transmitted from the radiographic imaging device. Provided.

  According to the disclosed technology, the display control unit recognizes each pixel of the display target image indicated by the shape recognition based on the display target image indicated by the image data received from the radiographic image capturing apparatus and the image data received from the radiographic image capturing apparatus. A radiographic imaging system that issues a display request based on a value is provided.

  According to the disclosed technology, a radiographic imaging system is provided that erases image data of a display target image from a storage medium after the control device receives the image data of the display target image.

  According to the disclosed technique, a radiographic imaging system that erases image data stored in a storage medium based on an instruction from a control device is provided.

  According to the technology of the disclosure, when displaying an image generated by some radiation detection panels among a plurality of radiation detection panels juxtaposed in a direction intersecting the radiation incident direction on the display unit of the external device, It is possible to shorten the waiting time until the image is displayed on the external apparatus as compared with the conventional technique while avoiding the risk of re-photographing.

It is a figure which shows the structure of the radiographic imaging system 100 which concerns on embodiment of this invention. It is sectional drawing which shows the structure of the radiographic imaging apparatus which concerns on embodiment of this invention. It is a figure which shows the electrical constitution of the radiation detection panel which concerns on embodiment of this invention. It is a top view which shows arrangement | positioning on the radiation detection panel of the pixel for irradiation detection which concerns on embodiment of this invention. It is a block diagram which shows the electric constitution of the radiographic imaging apparatus which concerns on embodiment of this invention. It is a block diagram which shows the detailed structure of the imaging | photography unit control part which concerns on embodiment of this invention. It is a block diagram which shows the detailed structure of the console which concerns on embodiment of this invention. It is a block diagram which shows the detailed structure of the radiation irradiation apparatus which concerns on embodiment of this invention. It is a flowchart which shows the flow of the imaging | photography preparation process implemented by running the imaging | photography preparation program which concerns on embodiment of this invention. It is a flowchart which shows the flow of the imaging | photography control processing implemented by executing the imaging | photography control program which concerns on embodiment of this invention. It is a flowchart which shows the flow of the display target image designation | designated process implemented by executing the display target image designation program which concerns on embodiment of this invention. It is a flowchart which shows the flow of the transmission control process implemented by executing the transmission control program which concerns on embodiment of this invention. It is a flowchart which shows the flow of the display control process implemented by executing the display control program which concerns on embodiment of this invention. It is a figure which shows an example of the radiographic image produced | generated by the radiographic imaging apparatus which concerns on embodiment of this invention. It is a figure which shows the flow of a process of the whole radiographic imaging system which concerns on embodiment of this invention. It is a flowchart which shows the flow of the transmission control process implemented by executing the transmission control program which concerns on embodiment of this invention. It is a flowchart which shows the flow of the display control process implemented by executing the display control program which concerns on embodiment of this invention. It is a flowchart which shows the flow of the transmission control process implemented by executing the transmission control program which concerns on embodiment of this invention. It is a figure which shows the content of the transmission control process which concerns on embodiment of this invention. It is a flowchart which shows the flow of the transmission control process implemented by executing the transmission control program which concerns on embodiment of this invention. It is a figure which shows the content of the transmission control process which concerns on embodiment of this invention. It is a figure which shows the luminance distribution of the radiographic image which concerns on embodiment of this invention. It is a flowchart which shows the flow of the transmission control process implemented by executing the transmission control program which concerns on embodiment of this invention. It is a figure which shows the content of the transmission control process which concerns on embodiment of this invention. It is a flowchart which shows the flow of the display control process implemented by executing the display control program which concerns on embodiment of this invention. It is a typical block diagram of the radiation detection panel 20 and signal processing part which concern on embodiment of this invention. It is a flowchart which shows the flow of the transmission control process implemented by executing the transmission control program which concerns on embodiment of this invention. It is a figure which shows the content of the transmission control process which concerns on embodiment of this invention. It is a flowchart which shows the flow of the display control process implemented by executing the display control program which concerns on embodiment of this invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings. In the drawings, the same reference numerals are assigned to the same components.

[First Embodiment]
FIG. 1 is a diagram showing a configuration of a radiographic image capturing system 100 according to an embodiment of the present invention. The radiographic image capturing system 100 includes a radiographic image capturing device 10, a console 70, and a radiation irradiation device 90. The radiographic image capturing apparatus 10 is an example of a radiographic image capturing apparatus in the present invention, and the console 70 is an example of a control apparatus in the present invention.

  The radiation irradiation apparatus 90 has a function of irradiating the subject O with X-rays according to the X-ray irradiation conditions (tube voltage, tube current, and irradiation time) notified from the console 70. The radiographic image capturing apparatus 10 has a function of generating a radiographic image corresponding to the X-ray dose distribution that has passed through the subject O and reached the imaging surface 10 </ b> S, and transmits the generated radiographic image to the console 70. The console 70 controls the radiation irradiating apparatus 90 and the radiation image capturing apparatus 10 as a whole, and has a function of displaying a radiation image transmitted from the radiation image capturing apparatus 10. The console 70 and the radiographic image capturing apparatus 10, and the console 70 and the radiation irradiation apparatus 90 transmit and receive image data, control signals, and the like via the communication cables 110 and 111, respectively. The communication between the console 70 and the radiation image capturing apparatus 10 and between the console 70 and the radiation irradiation apparatus 90 may be performed wirelessly. In this case, the communication cables 110 and 111 are unnecessary. It becomes.

  FIG. 2 is a cross-sectional view showing the structure of the radiographic image capturing apparatus 10. As illustrated in FIG. 2, the radiographic image capturing apparatus 10 includes a housing 12 and three imaging units 11A, 11B, and 11C housed in the housing 12. The imaging units 11A, 11B, and 11C have the same configuration, and include radiation detection panels 20A, 20B, and 20C configured by laminating a TFT substrate 21, a photoelectric conversion layer 22, and a scintillator 23, respectively. Yes. In FIG. 2, the other components (the gate line driving unit 41, the signal processing unit 42, the imaging unit control unit 50, etc. shown in FIG. 5) other than the radiation detection panels 20A, 20B, and 20C are not shown. doing. The radiation detection panels 20A, 20B, and 20C are examples of the radiation detection panel in the present invention. In the following, when the photographing units 11A, 11B, and 11C are not distinguished or collectively referred to, they are referred to as the photographing unit 11. Further, when the radiation detection panels 20A, 20B, and 20C are not distinguished or collectively referred to, they are referred to as the radiation detection panel 20.

  The scintillator 23 includes a phosphor that absorbs radiation and emits visible light. When X-rays are used as the radiation, the phosphor used in the scintillator 23 preferably includes cesium iodide (CsI), and CsI (Tl) (thallium added) has an emission spectrum at 400 nm to 700 nm upon X-ray irradiation. It is particularly preferred to use cesium iodide).

  The photoelectric conversion layer 22 is provided between the scintillator 23 and the TFT substrate 21 and is made of an organic photoelectric conversion material that generates charges by absorbing light emitted from the scintillator 23. The photoelectric conversion layer 22 containing an organic photoelectric conversion material has a sharp absorption spectrum in the visible region, and electromagnetic waves other than visible light emitted from the scintillator 23 are hardly absorbed by the photoelectric conversion layer 22. Therefore, it is possible to effectively suppress noise generated when radiation such as X-rays is absorbed by the photoelectric conversion layer 22. The organic photoelectric conversion material constituting the photoelectric conversion layer 22 is preferably as the absorption peak wavelength is closer to the emission peak wavelength of the scintillator 23. Examples of the organic photoelectric conversion material that can satisfy such conditions include quinacridone-based organic compounds and phthalocyanine-based organic compounds. Although not shown, an electrode is provided so as to sandwich the photoelectric conversion layer 22 therebetween, and a bias voltage is applied to the photoelectric conversion layer 22 through this electrode during photographing. The electrode on the TFT substrate 21 side is divided into a matrix corresponding to a plurality of pixels.

  The TFT substrate 21 includes a glass substrate provided with a switching element (TFT 34 shown in FIG. 3) for reading out the electric charge generated in the photoelectric conversion layer 22.

In the radiation detection panels 20A, 20B, and 20C, peripheral edges of the TFT substrate 21 are insensitive areas R _AX , R _BX, and R _CX in which the photoelectric conversion layer 22 and the scintillator 23 are not stacked, and the insensitive areas R _AX , R _BX and R _CX and the inner side (center side of the radiation detection panel 20) are imaging regions R _A , R _B , and R _C in which the photoelectric conversion layer 22 and the scintillator 23 are stacked. Radiation images can be generated in the imaging regions R _A , R _B , and _RC .

In the radiographic imaging apparatus 10, the radiation detection panels 20A, 20B, and 20C are juxtaposed in a direction that intersects the X-ray incident direction. More specifically, the one end portion of the imaging region R _A in the radiation detection panel 20A, and one end of the imaging region R _B in the radiation detection panel 20B is overlapped with each other in the irradiation direction of the X-ray photographing region one end of the shooting at the other end and the radiation detection panel 20C of R _B region R _C are stacked with each other in the irradiation direction of the X-ray. The radiation detection panel 20B disposed in the center is disposed downstream of the radiation detection panels 20A and 20C at both ends in the X-ray irradiation direction. As described above, in the radiographic image capturing apparatus 10, the three radiation detection panels 20A, 20B, and 20C are connected to form a long imaging region. In the radiation detection panels adjacent to each other, the continuity of the imaging regions can be ensured by overlapping the ends of the imaging regions. That is, even when the relative positions of the radiation detection panels 20A, 20B, and 20C vary due to manufacturing variations, impacts, vibrations, ambient temperature fluctuations, and the like, discontinuous portions of the imaging region (that is, missing portions of images) at the joints of the radiation detection panels. Can be prevented. In addition, even when X-rays are incident on the imaging surface 10S from an oblique direction, it is possible to prevent a discontinuous portion of the imaging region from occurring.

  In addition, the radiographic imaging apparatus 10 employs a so-called surface reading system (ISS: Irradiation Side Sampling) imaging system in which the photoelectric conversion layer 22 is disposed on the X-ray incident side. Compared with the case where a so-called back side reading method (PSS: Pentration Side Sampling) in which the scintillator 23 is arranged on the X-ray incident side by adopting the surface reading method, the strong light emission position and photoelectric conversion in the scintillator 23 The distance between the layers 22 can be shortened, and as a result, the resolution of the radiation image can be increased. In addition, the radiographic imaging apparatus 10 may employ a back side scanning method, or may include each of them.

  FIG. 3 is a diagram showing an electrical configuration of the radiation detection panel 20. The radiation detection panel 20 has not only a function of generating a radiation image but also an irradiation detection function of detecting the presence or absence of X-ray irradiation. In order to realize the above-described irradiation detection function, the radiation detection panel 20 includes a plurality of irradiation detection pixels for detecting the presence / absence of X-ray irradiation in addition to the plurality of imaging pixels 31 for capturing a radiation image. 32.

  Each of the imaging pixels 31 includes a radiation image capturing sensor 310 including the photoelectric conversion layer 22, and a TFT 34 as a switching element that is turned on when a charge generated by the sensor 310 is read. It is out. The imaging pixels 31 are arranged two-dimensionally in rows and columns on the entire surface of the TFT substrate 21.

  The radiation detection panel 20 extends in a certain direction (row direction) along the arrangement of the imaging pixels 31 and has a plurality of gate lines 35 for supplying gate signals for turning on / off the TFTs 34 to the TFTs 34. . The radiation detection panel 20 extends in a direction (column direction) intersecting with the extending direction of the gate line 35, and a plurality of signal lines 36 for reading out the electric charges generated in the sensor 310 via the TFT 34 in the on state. , Is provided. Each of the imaging pixels 31 is provided corresponding to each intersection of the gate line 35 and the signal line 36.

  The irradiation detection pixel 32 includes an irradiation detection sensor 320 that includes the photoelectric conversion layer 22. The irradiation detection sensor 320 is directly connected to the signal line 36, and the charge generated by the sensor 320 flows through the signal line 36 as it is. The irradiation detection sensors 320 are distributed over the entire area of the TFT substrate 21. In the present embodiment, the number of irradiation detection sensors 320 is smaller than the number of radiation image capturing sensors 310. That is, the irradiation detection pixels 32 are formed on the TFT substrate 21 at a lower density than the imaging pixels 31. A bias voltage is supplied to the radiation image capturing sensor 310 and the irradiation detection sensor 320 via a bias line (not shown), and both output detection signals having a magnitude corresponding to the dose of the irradiated radiation. The sizes of the radiation image capturing sensor 310 and the irradiation detection sensor 320 may be the same or different. In the present embodiment, the irradiation detection pixel 32 is used as means for detecting the presence or absence of X-ray irradiation. However, the present invention is not limited to this. For example, other means exemplified below are used. It is also possible to use.

(1) A pixel arbitrarily selected from the imaging pixels 31 may function as a pixel (irradiation detection pixel) exclusively for detecting the presence or absence of X-ray irradiation. In this case, the source and drain of the TFT 34 of the imaging pixel 31 that functions as an irradiation detection pixel may be short-circuited (short pixel method).

(2) Bias current detection means for detecting a bias current flowing through each of the sensors 310 in accordance with application of a bias voltage to each of the radiographic imaging sensors 310 is provided, and the magnitude of the bias current detected by the bias current detection means is provided. The presence or absence of X-ray irradiation may be detected based on the length.

(3) An additional TFT may be provided in a pixel selected from the imaging pixels 31, and the presence or absence of X-ray irradiation may be detected based on the leakage current of the additionally provided TFT.

(4) The magnitude of the current flowing from the gate line driving unit 41 to each gate line 35 may be detected, and the presence or absence of X-ray irradiation may be detected based on the detected magnitude of the current.

(5) A sensor for detecting the presence or absence of radiation irradiation may be provided in a layer different from the layer in which the imaging pixels 31 are provided in the radiation detection panel 20. In addition, a sensor that detects the presence or absence of radiation irradiation may be provided separately from the radiation detection panel 20.

  FIG. 4 is a plan view illustrating the arrangement of the irradiation detection pixels 32 on the radiation detection panel 20. The irradiation detection pixels 32 are connected to each of the signal lines 36, and the irradiation detection pixels 32 are arranged so as to be uniformly distributed in the radiation detection panel 20. FIG. 4 shows a case where one irradiation detection pixel 32 is connected to one signal line 36, but there is one irradiation detection pixel 32 adjacent in the extending direction of the signal line 36. It may be connected to the signal line 36. In this case, the charges generated by the plurality of irradiation detection pixels 32 connected to the same signal line 36 are added by joining on the signal line 36. In this embodiment, the irradiation detection pixel 32 is provided on the TFT substrate 21 together with the photographing pixel 31. However, the irradiation detection pixel 32 may be provided in a different layer from the photographing pixel 31. .

  FIG. 5 is a block diagram showing an electrical configuration of the entire radiographic image capturing apparatus 10 including the three image capturing units 11A, 11B, and 11C. The imaging unit 11A includes a gate line driving unit 41 arranged along one side of two adjacent sides of the radiation detection panel 20A, and a signal processing unit 42 arranged along the other side. Each of the gate lines 35 is connected to a gate line driving unit 41, and each of the signal lines 36 is connected to a signal processing unit 42. Further, the photographing unit 11A includes an image memory 43, a communication unit 44, a power supply unit 45, and a photographing unit control unit 50. Since the photographing units 11B and 11C have the same configuration as that of the photographing unit 11A, overlapping description of the photographing units 11B and 11C is omitted.

  In the radiation detection panels 20A, 20B, and 20C, the TFTs 34 constituting the imaging pixels 31 are turned on in units of rows by a gate signal supplied from the gate line driving unit 41 via the gate line 35 (FIG. 3, FIG. (See FIG. 5). When the TFT 34 is turned on, electric charges generated by the imaging sensor 310 are read out as electric signals to the signal lines 36 and transmitted to the signal processing unit 42 (see FIGS. 3 and 5). On the other hand, charges generated by the irradiation detection sensor 320 constituting the irradiation detection pixel 32 flow out to the signal line 36 regardless of the gate signal from the gate line driving unit 41 and are transmitted to the signal processing unit 42 (FIG. 3, see FIG.

  The signal processing unit 42 includes an amplifier and a sample hold circuit (not shown) provided for each signal line 36. The charge signal transmitted to each signal line 36 is amplified by an amplifier in the signal processing unit 42 and then held in a sample and hold circuit. Further, a multiplexer and an A / D (analog / digital) converter (not shown) are sequentially connected to the output side of the sample hold circuit. The charge signals held by the individual sample and hold circuits are sequentially input to the multiplexer, converted into digital signals by the A / D converter, and supplied to the photographing unit controller 50. The photographing unit control unit 50 generates, as image data, data in which the digital signal generated by the A / D converter and the position information of the photographing pixels 31 are associated with each other.

  An image memory 43 is connected to the photographing unit controller 50, and image data generated by the photographing unit controller 50 is stored in the image memory 43. The image memory 43 has a storage capacity capable of storing image data for a plurality of frames. Every time a radiographic image is captured, the image data obtained by the imaging is sequentially stored in the image memory 43. The image memory 43 according to the first embodiment of the present invention is an example of a storage medium according to the present invention. In the present embodiment, the image memory 43 is built in the photographing unit 11, but the image memory 43 may be detachable from the photographing unit 11.

  The communication unit 44 controls communication performed between the other photographing unit 11 and the console 70 which are external devices. The photographing units 11 </ b> A, 11 </ b> B, and 11 </ b> C are connected so as to be able to communicate with each other via a communication wiring 46 connected to the communication unit 44. Thereby, various types of information are shared between the photographing units 11A, 11B, and 11C. Furthermore, it is possible to synchronize the operation among the photographing units 11A, 11B, and 11C. The communication units 44 of the photographing units 11A, 11B, and 11C are connected to the communication terminal 47 via the communication wiring 46, respectively. One end of the communication cable 110 is connected to the communication terminal 47, and the other end of the communication cable 110 is connected to the console 70. The photographing units 11 </ b> A, 11 </ b> B, and 11 </ b> C exchange image data, control signals, and the like with the console 70 via the communication cable 110.

  The power supply unit 45 supplies power to each component of the imaging unit 11 (the radiation detection panel 20, the imaging unit control unit 50, the gate line driving unit 41, the signal processing unit 42, the image memory 43, and the communication unit 44). In FIG. 5, illustration of power supply wiring for connecting the power supply unit 45 and various circuits is omitted. In the present embodiment, each of the imaging units 11A, 11B, and 11C is configured to include the power supply unit 45. However, the configuration is not limited thereto, and at least one power supply unit is provided in the radiographic image capturing apparatus 10. It only has to be done.

  The imaging unit control unit 50 is connected to the gate line driving unit 41, the signal processing unit 42, the image memory 43, and the communication unit 44, and includes a microcomputer that comprehensively controls these operations. FIG. 6 is a block diagram illustrating a detailed configuration of the photographing unit control unit 50. The photographing unit control unit 50 includes a CPU (Central Processing Unit) 51, a RAM (Random Access Memory) 52, a ROM (Read Only Memory) 53, and a bus 54 that interconnects them. The ROM 53 stores a shooting control program 55, a display target image designation program 56, and a transmission control program 57, which will be described later.

  FIG. 7 is a block diagram showing a detailed configuration of the console 70 constituting the radiographic image capturing system 100 according to the embodiment of the present invention. The console 70 is configured as a computer. The console 70 includes a display unit 71 that displays an operation menu, a captured radiographic image, and the like, and an operation input unit 72 that can input various information and operation instructions. The operation input unit 72 may have a keyboard form as an example, or may have a touch panel form integrated with the display unit 71. Further, the operation input unit 72 may include a camera, and may have a form in which an operation instruction is input by causing the camera to recognize an operator's gesture. The console 70 includes a CPU 73, a RAM 74, a hard disk drive (HDD) 75, and a ROM 76. The console 70 also includes a display drive unit 77 that controls display of various types of information on the display unit 71 and an operation input detection unit 78 that detects an operation input to the operation input unit 72. In addition, the console 70 includes a communication unit 79 that controls communication between the radiographic imaging device 10 and the radiation irradiation device 90. The communication unit 79 is connected to the radiation image capturing apparatus 10 via the communication terminal 80 and the communication cable 110, and is connected to the radiation irradiation apparatus 90 via the communication terminal 80 and the communication cable 111. The CPU 73, RAM 74, ROM 76, HDD 75, display drive unit 77, operation input detection unit 78, and communication unit 79 are connected to each other via a bus 81. The ROM 76 stores a shooting preparation program 82 and a display control program 83 which will be described later.

  FIG. 8 is a block diagram showing a detailed configuration of the radiation irradiating apparatus 90 constituting the radiographic image capturing system 100 according to the embodiment of the present invention. The radiation irradiating apparatus 90 receives from the console 70 via the communication cable 111 and the communication unit 92 that controls communication between the radiation source 91 that generates X-rays and the console 70 that is performed via the communication cable 111. And a radiation source control unit 93 that controls the radiation source 91 based on the X-ray irradiation conditions. The communication unit 92 is connected to the console 70 via the communication terminal 94 and the communication cable 111. The radiation source control unit 93 includes a microcomputer and stores the X-ray irradiation conditions transmitted from the console 70. The X-ray irradiation conditions transmitted from the console 70 include information such as tube voltage, tube current, and irradiation time. Note that the radiation irradiation apparatus 90 is configured so that the user can directly and manually set X-ray irradiation conditions such as tube voltage, tube current, and irradiation time for the radiation irradiation apparatus 90, and set X-rays. You may provide the display part for displaying irradiation conditions. In addition, the radiation irradiation apparatus 90 transmits information indicating the manual setting, the setting value by the manual setting, and the current status (standby state, preparation state, during exposure, completion of exposure) to the console 70.

(Shooting preparation process)
FIG. 9 is a flowchart showing the flow of shooting preparation processing executed by the CPU 73 of the console 70 executing the shooting preparation program 82 stored in the ROM 76. The shooting preparation program 82 is started, for example, when the user instructs the start of shooting preparation via the operation input unit 72.

  In step S <b> 11, the CPU 73 controls the display driving unit 77 to display the subject information input screen on the display unit 71. On the subject information input screen, a message for prompting input of the subject, such as sex, age, height, weight, body thickness, imaging target region, imaging posture and X-ray irradiation conditions, and an input area for these information Is displayed. In step S12, the CPU 73 waits for input of subject information. When subject information is input via the operation input unit 72, an affirmative determination is made in step S12, and the process proceeds to the next step S13.

  In step S <b> 13, the CPU 73 transmits the input subject information to the radiation image capturing apparatus 10 via the communication unit 79. In step S <b> 14, the CPU 73 transmits the X-ray irradiation conditions input in step S <b> 12 to the radiation irradiation apparatus 90 via the communication unit 79. The radiation source control unit 93 of the radiation irradiation apparatus 90 prepares for X-ray irradiation to perform X-ray irradiation under the X-ray irradiation conditions received via the communication unit 92.

  Thereafter, when an operation switch (not shown) for performing X-ray irradiation is operated, the radiation source 91 of the radiation irradiation apparatus 90 causes the tube voltage and the tube in accordance with the X-ray irradiation conditions received from the console 70. X-rays are emitted with current and irradiation time. X-rays emitted from the radiation irradiating apparatus 90 pass through the subject O and are irradiated to the radiographic image capturing apparatus 10.

(Shooting control processing)
FIG. 10 is a flowchart showing the flow of a shooting control process performed by the CPU 51 configuring the shooting unit control unit 50 of each of the shooting units 11A, 11B, and 11C executing the shooting control program 55 stored in the ROM 53. is there. The imaging control program 55 is started, for example, by receiving a control signal instructing the start of X-ray irradiation transmitted from the console 70 in step S15 of the imaging preparation process.

  In step S <b> 21, the CPU 51 configuring the imaging unit control unit 50 of each imaging unit 11 (imaging units 11 </ b> A, 11 </ b> B, and 11 </ b> C) determines whether or not X-rays emitted from the radiation irradiation apparatus 90 have been detected. That is, when the CPU 51 of each imaging unit 11 has reached a predetermined threshold value, the dose of X-rays indicated by the amount of charge generated by the irradiation detection pixel 32 provided in the radiation detection panel 20 corresponding to itself. It is determined that X-rays have been detected.

  Here, when a radiographic image is captured by using a part of the imaging units 11A, 11B, and 11C, normally, only a part of the imaging units 11 used for imaging are irradiated with X-rays. The imaging unit 11 that is not used is not irradiated with X-rays. Therefore, when a radiographic image is captured using a part of the imaging units 11A, 11B, and 11C, only the imaging unit 11 used for imaging detects X-rays. If the CPU 51 of each imaging unit 11 determines that X-rays are detected in step S21, the process proceeds to step S22. If no X-rays are detected, the process proceeds to step S23.

  In step S22, the CPU 51 of the imaging unit 11 that has detected the X-ray transmits an X-ray detection signal indicating that the X-ray has been detected to the other imaging unit 11 via the communication unit 44 and the communication wiring 46. Then, the process proceeds to step S24. On the other hand, the imaging unit 11 that does not detect X-rays waits for reception of an X-ray detection signal from another imaging unit in step S23. If the imaging unit 11 that does not detect X-rays receives an X-ray detection signal from another imaging unit 11, the process proceeds to step S <b> 24, and if no X-ray detection signal is received from another imaging unit 11, the process is performed. Return to step S21.

  When X-rays are detected in some imaging units 11 by the processes in steps S21 to S23 described above, detection information indicating that X-rays are detected in some imaging units 11 detects X-rays. It is also shared with other photographing units 11 that do not.

  In step S24, the CPU 51 of each photographing unit 11 shifts to a photographing operation. That is, the CPU 51 of each photographing unit 11 supplies a control signal to the gate line driving unit 41 corresponding to the photographing unit 11 to drive all the TFTs 34 of the photographing pixels 31 to the OFF state. As a result, the charge generated by the sensor 310 of each imaging pixel 31 with the X-ray irradiation is accumulated in the sensor 310. In step S24, charge accumulation processing is performed in all the imaging units 11 including the imaging unit 11 that does not detect X-rays (not used for imaging) in step S21. On the other hand, the charges generated by the sensor 320 of the irradiation detection pixel 32 accompanying the X-ray irradiation are supplied to the signal processing unit 42 via the signal line 36 without being accumulated.

  In step S25, the CPU 51 of each photographing unit 11 determines whether or not a predetermined accumulation time has elapsed since the start of charge accumulation in step S24. If the CPU 51 of each photographing unit 11 determines that the predetermined accumulation time has elapsed, the process proceeds to step S26.

  In step S <b> 26, the CPU 51 of each imaging unit 11 supplies a control signal to the gate line driving unit 41 to read out the electric charge accumulated in the sensor 310 of the imaging pixel 31 of each radiation detection panel 20. The gate line drive unit 41 of each photographing unit 11 that has received the control signal from the CPU 51 sequentially outputs an ON signal to each gate line 35, and sequentially turns on the TFTs 34 connected to each gate line 35 line by line. As a result, the electric charge accumulated in the sensor 310 of each photographing pixel 31 is read out to each signal line 36 as an electric signal and transmitted to the signal processing unit 42. The signal processing unit 42 of each photographing unit 11 is a digital signal (pixel value of each photographing pixel 31) indicating each pixel value of the photographing pixel 31 based on the electric signal supplied via each signal line 36. And the generated digital signal is supplied to the CPU 51. In step S26, charge readout processing is performed in all the imaging units 11 including the imaging unit 11 that does not detect X-rays (not used for imaging) in step S21.

  In step S <b> 27, the CPU 51 of each photographing unit 11 sets the data in which the digital signal (pixel value of each photographing pixel 31) supplied from the signal processing unit 42 is associated with the position information of the photographing pixel 31 as image data. Generate as In step S27, image data generation processing is performed in all the imaging units 11 including the imaging unit 11 that does not detect X-rays (not used for imaging) in step S21.

  In step S28, the CPU 51 of each photographing unit 11 stores the generated image data in the image memory 43 corresponding to itself, and ends this routine. In step S28, image data storage processing is performed in all the imaging units 11 including the imaging unit 11 that does not detect X-rays (not used for imaging) in step S21.

  As described above, in the radiographic image capturing apparatus 10, even when imaging is performed using some of the imaging units 11 </ b> A, 11 </ b> B, and 11 </ b> C, all the imaging units perform the charge accumulation process at the same timing. The charge reading process, the image data generation process, and the image data storage process are performed. That is, when the start of radiation irradiation is detected in any of the imaging units 11 for one irradiation of X-rays, each of the imaging units 11A, 11B, and 11C detects X-rays. Even if not, a radiation image is generated and the image data is stored in the image memory 43. For example, when radiographic images are captured using only the imaging unit 11B, the imaging units 11A and 11C also perform processing for generating radiographic images, and the generated radiographic images are the images of the respective imaging units 11. Stored in the memory 43.

(Display target image specification processing)
The radiographic image capturing apparatus 10 is an image to be displayed on the display unit 71 of the console 70 (hereinafter referred to as a display target image) among the radiographic images generated in the respective imaging units 11A, 11B, and 11C by the above-described imaging control process. Is specified. For example, the radiographic image capturing apparatus 10 designates an image presumed to include a subject image among the radiographic images generated by the respective imaging units 11A, 11B, and 11C as a display target image. For example, when the radiographic imaging device 10 estimates that the subject image is included only in the image generated in the imaging unit 11B, only the image generated by the imaging unit 11B is specified as a display target image, and the specified image is displayed. Is transmitted to the console 70.

  FIG. 11 shows a flow of display target image designation processing executed by the CPU 51 of the photographing unit control unit 50 of each of the photographing units 11A, 11B, and 11C executing the display target image designation program 56 stored in the ROM 53. It is a flowchart. The display target image designation program 56 is started, for example, with the start of the shooting control process (see FIG. 10). That is, the display target image designation program 56 is executed in parallel with the shooting control program 55. The CPU 51 of each photographing unit 11 that executes the display target image designation program 56 is an example of a designation unit in the present invention.

  In step S <b> 31, the CPU 51 of each photographing unit 11 acquires the pixel value of each of the irradiation detection pixels 32 from the signal processing unit 42. The electrical signals generated by the charges generated by the sensors 320 of the irradiation detection pixels 32 of the imaging units 11 in accordance with the X-ray irradiation are supplied to the signal processing unit 42 via the signal lines 36. The signal processing unit 42 of each photographing unit 11 generates a digital signal indicating each pixel value of the irradiation detection pixel 32 based on the electric signal supplied via each signal line 36, and supplies this to the CPU 51. To do. This step S31 is executed before step S26 (charge reading) in the above-described photographing control process (see FIG. 10).

  This step S31 is a process for detecting the presence or absence of X-ray irradiation on the radiation detection panel 20. In the present embodiment, the irradiation detection pixel 32 is used to detect the presence or absence of X-ray irradiation on the radiation detection panel 20, but as described above, the irradiation detection pixel 32 is obtained by other means. It is possible to substitute, and it is possible to detect the presence or absence of X-ray irradiation on the radiation detection panel 20 also by an alternative means.

  For example, instead of the irradiation detection pixel 32, a pixel arbitrarily selected from the imaging pixels 31 is caused to function exclusively as a pixel (short pixel) for detecting the presence or absence of X-ray irradiation (the above ( In the case of 1), in this step S31, the CPU 51 of each imaging unit 11 acquires the pixel value of the pixel (short pixel) exclusively for detecting the presence or absence of X-ray irradiation from the signal processing unit 42. Thus, the presence or absence of X-ray irradiation on the radiation detection panel 20 is detected.

  Also, there is provided a bias current detecting means for detecting a bias current flowing in each of the sensors 310, and detecting the presence or absence of X-ray irradiation based on the magnitude of the bias current detected by the bias current detecting means (above (2 In the case of ()), in this step S31, the CPU 51 of each imaging unit 11 acquires information indicating the magnitude of the bias current from the bias current detecting means, whereby X on the radiation detection panel 20 is obtained. Detects the presence or absence of radiation.

  In addition, an additional TFT is provided in a pixel selected from the imaging pixels 31, and the presence or absence of X-ray irradiation is detected based on the leakage current of the additionally provided TFT (in the case of (3) above) ) Is used, in this step S31, the CPU 51 of each imaging unit 11 obtains information indicating the magnitude of the leakage current of the additional TFT, thereby performing X-ray irradiation on the radiation detection panel 20. Detect the presence or absence.

  Further, a method of detecting the magnitude of current flowing from the gate line driving unit 41 to each gate line 35 and detecting the presence or absence of X-ray irradiation based on the detected current magnitude (in the case of (4) above). If used, in this step S31, the CPU 51 of each imaging unit 11 acquires information indicating the magnitude of the current flowing through each gate line 35, so that the presence or absence of X-ray irradiation on the radiation detection panel 20 is detected. Is detected.

  In addition, a method for providing a sensor for detecting the presence or absence of radiation irradiation in a layer different from the layer in which the imaging pixels 31 are provided in the radiation detection panel 20 and a sensor for detecting the presence or absence of radiation irradiation are used for radiation detection. In the case of using a method provided separately from the panel 20 (in the case of (5) above), the CPU 51 of each photographing unit 11 has a sensor provided in a layer different from the layer in which the photographing pixels 31 are provided. The presence or absence of X-ray irradiation on the radiation detection panel 20 is detected based on the output value or the output value (pixel value) of a sensor provided separately from the radiation detection panel 20.

  In step S32, the CPU 51 of each imaging unit 11 determines whether or not the subject is arranged on the radiation detection panel 20 corresponding to itself based on the pixel value of each of the irradiation detection pixels 32 acquired in step S31. Determine. For example, when the CPU 51 of each photographing unit 11 determines that the ratio of pixels that output a pixel value that exceeds a predetermined threshold among the plurality of irradiation detection pixels 32 is greater than or equal to a predetermined value, it corresponds to itself. It is determined that the subject is placed on the radiation detection panel 20.

  For example, when a radiographic image is captured using only the imaging unit 11B, X-rays are not normally applied to the imaging units 11A and 11C that are not used for imaging. In this case, since a significant difference appears between the pixel value of the irradiation detection pixel 32 of the photographing unit 11B used for photographing and the pixel value of the irradiation detection pixel 32 of the photographing units 11A and 11C not used for photographing, The presence or absence of a subject can be determined by the above determination. Here, the X-rays irradiated to the subject arranged on the imaging unit 11B may be scattered, and the X-rays may enter the imaging units 11A and 11C that are not used for imaging. In this case, in the imaging units 11A and 11C, scattered rays are detected, and there is a possibility that an erroneous determination is made if a subject is placed on the radiation detection panels 20A and 20C. Therefore, in order to prevent such erroneous determination, it is preferable to appropriately set a threshold value for the pixel value. Since the dose of scattered radiation is very small, it is possible to eliminate the influence of scattered radiation by appropriately setting a threshold for the pixel value.

  In addition, since the radiation detection panel 20 of each imaging unit 11 is provided with a plurality of irradiation detection pixels 32 uniformly, a simple radiation image can be obtained based on the pixel value of each irradiation detection pixel 32. It is possible to generate. Therefore, the CPU 51 of each imaging unit 11 analyzes the simple radiation image generated based on the pixel value of each irradiation detection pixel 32 to determine whether the subject is arranged on the radiation detection panel 20 corresponding to itself. It may be determined whether or not. Here, there is a high possibility that the continuous region on the radiation detection panel 20 where the X-ray irradiation dose is relatively small is a region that is transmitted through the subject and irradiated with X-rays. Therefore, as an example, the CPU 51 of each imaging unit 11 detects a region where the X-ray dose is relatively large and a continuous region where the X-ray dose is relatively small based on the pixel value of the irradiation detection pixel 32. In such a case, it may be determined that the subject is arranged on the radiation detection panel 20. Even in this case, in order to eliminate the influence of the scattered radiation, it is preferable to specify the pattern of the image generated by the scattered radiation in advance so that the image pattern of the scattered radiation can be distinguished from the subject image.

  In the case where the above-described alternative means for the irradiation detection pixel 32 is used, whether or not the subject is arranged on the radiation detection panel 20 corresponding to itself based on the information acquired by using the alternative means. Determine.

  If the CPU 51 of each imaging unit 11 determines that the subject is arranged on the radiation detection panel 20 corresponding to the CPU 51 as a result of the determination process in step S32, the process proceeds to step S33. In step S33, the CPU 51 of each imaging unit 11 designates the radiation image (radiation image based on the imaging pixel 31) generated by itself in step S27 of the imaging control process (see FIG. 10) as a display target image.

  On the other hand, if the CPU 51 of each imaging unit 11 determines that the subject is not arranged on the radiation detection panel 20 corresponding to the CPU 51 as a result of the determination process in step S32, the process proceeds to step S34. In step S34, the CPU 51 of each imaging unit 11 designates the radiation image generated by itself in step S27 of the imaging control process (see FIG. 10) as a non-display target image.

  In step S35, the CPU 51 of each imaging unit 11 stores the designation result in step S33 or step S34 in the RAM 52 in association with the radiation image.

  As described above, in each of the imaging units 11A, 11B, and 11C, in parallel with the generation of the radiographic image based on the pixel value of each imaging pixel 31, the radiographic image based on the pixel value of each irradiation detection pixel 32 The presence or absence of a subject image at is determined. Further, based on the determination result of the presence / absence of the subject image, either a display target image or a non-display target image is designated for the radiographic image generated in each of the imaging units 11A, 11B, and 11C. As described above, the radiographic image capturing apparatus 10 displays a display target image from among the process of generating a radiographic image in each imaging unit 11 and the radiographic image generated in each imaging unit 11 for one irradiation of radiation. Process to specify is performed in parallel.

  In the present embodiment, the radiographic imaging is performed based on each pixel value of the irradiation detection pixel 32 to determine whether or not the subject is arranged on the radiation detection panel 20 corresponding to the pixel (step S32). Although the apparatus 10 is supposed to perform the processing, the console 70 may perform this processing. In this case, each imaging unit 11 of the radiographic imaging device 10 transmits data in which the pixel value of the irradiation detection pixel 32 is associated with the position information of the irradiation detection pixel 32 to the console 70. The console 70 determines on which radiation detection panel 20 the subject is placed based on this data, and transmits the determination result to the radiation image capturing apparatus 10. The radiographic imaging device 10 designates a display target image and a non-display target image based on the determination result received from the console 70.

(Transmission control processing)
The radiographic image capturing apparatus 10 transmits only the display target image specified by the display target image specifying process (see FIG. 11) to the console 70. According to the display target image specifying process according to the present embodiment, a plurality of radiation images generated by each of the plurality of imaging units 11 may be specified as display target images. For example, when it is determined that the subject images are included in the radiographic images generated by the two imaging units 11A and 11B, the two radiographic images are designated as display target images. Thus, when a plurality of radiographic images are designated as display target images, the radiographic imaging device 10 derives a transmission order for each of the plurality of radiographic images designated as display target images, and the derived transmission order. Each of the display target images is transmitted to the console 70 according to the above.

  FIG. 12 is a flowchart showing a flow of a transmission control process performed by the CPU 51 constituting each of the photographing unit control units 50 of the photographing units 11A, 11B, and 11C executing the transmission control program 57 stored in the ROM 53. is there. For example, the transmission control program 57 is executed by the CPU 51 of each photographing unit 11 after the above photographing control processing (see FIG. 10) and display target image designation processing (see FIG. 11). The CPU 51 of each photographing unit 11 that executes the transmission control program 57 is an example of a transmission unit in the present invention.

  In step S41, the CPU 51 of each photographing unit 11 that has generated the display target image determines itself based on the pixel value of the irradiation detection pixel 32 acquired in step S31 of the display target image designation process (see FIG. 11). An estimated value of the area of the subject image included in the corresponding radiation image (display target image) is derived. Here, there is a high possibility that the continuous region where the radiation dose of X-rays on the radiation detection panel 20 is relatively small is a region irradiated with X-rays transmitted through the subject. Therefore, as an example, the CPU 51 of each imaging unit 11 that has generated the display target image specifies a continuous region with a relatively small X-ray irradiation dose based on the pixel value of the irradiation detection pixel 32, and The area may be derived as an estimated value of the area of the subject image.

  In step S42, the CPU 51 of each photographing unit 11 that has generated the display target image transmits the estimated value of the area of the subject image derived in the previous step S41 to the other photographing units 11 via the communication wiring 46. Then, the estimated value of the area of the subject image derived in the other photographing unit 11 is received from the other photographing unit 11 via the communication wiring 46. Thereby, the estimated value of the area of the subject image derived in each photographing unit 11 is shared by the other photographing units 11.

  In step S43, the CPU 51 of each photographing unit 11 that has generated the display target image compares the estimated value of the area of the subject image derived by itself with the estimated value of the area of the subject image derived by the other photographing units 11. By doing so, the transmission order of the radiation image (display target image) corresponding to itself is derived. That is, the CPU 51 of each photographing unit 11 that has generated the display target image transmits the display target image having a larger estimated area of the subject image included in the display target image to the console 70 in advance. Deriving the transmission order.

  In step S44, the CPU 51 of each photographing unit 11 that has generated the display target image transmits the display target image generated by itself to the console 70 via the communication cable 110 in accordance with the transmission order derived in step S43. . Identification information indicating that the images are display target images and the transmission order of the images may be given to each of the display target images to be transmitted. Note that images other than the display target image (non-display target image) are not transmitted to the console 70 but are held in the image memory 43. Each display target image transmitted to the console 70 is stored in the RAM 74 or the HDD 75 of the console 70.

The flow of the above transmission control process will be described with a specific example. For example, in a case where the radiographic image I _A generated in the imaging unit 11A, a radiation image I _B generated in the photographing unit 11B has been designated as a display target image, the area of the subject image included in the radiographic image I _B estimate of, consider the case larger than the estimated value of the area of the subject image included in the radiographic image I _a. In this case, CPU 51 of the imaging unit 11B derives the "1" as the transmission order of the radiation image _{I B} generated by itself. On the other hand, CPU 51 of the imaging unit 11A derives the "2" as the transmission order of the radiation image _{I A} generated by itself.

CPU51 of the photographing unit 11B generating the radiation image _{I B} to be displayed on the image to be transmitted to the first transmits the radiation image _{I B} to the console 70. CPU51 of the photographing unit 11B, the radiation image _I other imaging units 11A that it has completed the transmission of _B, and notifies the 11C. Radiation image _I capturing unit 11A receives the notification of completion of transmission of _B, of 11C, the imaging unit 11A which generates a radiation image _{I A} is a display target image to be transmitted to the second CPU51, the radiation image _{I A} Send to console 70. Since the radiographic image I _C generated by the imaging unit 11C is not designated as a display target image, the radiographic image I _C is not transmitted to the console 70 at this stage and is held in the image memory 43.

  As described above, the radiographic image capturing apparatus 10 according to the present embodiment determines the transmission order of the plurality of display target images generated by the plurality of imaging units 11 to the console 70 and the area of the subject image included in the display target image. Derived based on the estimated value of. More specifically, the transmission order of the display target images is derived so that a display target image having a larger estimated value of the area of the subject image included in the display target image is transmitted to the console 70 in advance. The radiographic image capturing apparatus 10 sequentially transmits a plurality of display target images to the console 70 according to the derived order. On the other hand, the radiographic image capturing apparatus 10 holds an image other than the display target image (non-display target image) in the image memory 43 without transmitting it to the console 70.

  According to the transmission control process according to the present embodiment, an image with higher importance can be transmitted to the console 70 in advance. In addition, since an image other than the display target image (non-display target image) is not transmitted to the console 70, the amount of data transmitted to the console 70 can be suppressed. Thereby, compared with the case where all the radiographic images produced | generated by each imaging | photography unit 11 are transmitted to the console 70, data transfer time can be shortened.

  In the present embodiment, a process for deriving an estimated value of the area of the subject image based on the pixel value of the irradiation detection pixel 32 (step S41), and the derived estimated value of the area of the subject image is shared by each photographing unit 11. However, although the radiation image capturing apparatus 10 performs the process of deriving the transmission order of the radiographic image (display target image) (step S43), the console 70 may perform each of these processes.

  In this case, each imaging unit 11 of the radiographic imaging device 10 transmits data in which the pixel value of the irradiation detection pixel 32 is associated with the position information of the irradiation detection pixel 32 to the console 70. The console 70 derives the estimated value of the area of the subject image based on this data, and derives the transmission order of the radiation images based on the derived estimated value. The console 70 transmits information indicating the transmission order of the derived radiation images to each imaging unit 11. Each photographing unit 11 transmits the display target image to the console 70 according to the transmission order derived in the console.

(Display control processing)
FIG. 13 is a flowchart showing the flow of display control processing performed by the CPU 73 of the console 70 executing the display control program 83 stored in the ROM 76. The display control program 83 is started, for example, when the console receives a display target image transmitted from the radiation image capturing apparatus 10. The CPU 73 of the console 70 that executes the display control program 83 is an example of a display control unit in the present invention.

  In step S <b> 51, the CPU 73 of the console 70 controls the display driving unit 77 to display the display target images for each imaging unit 11 transmitted from the radiographic image capturing apparatus 10 on the display unit 71 in the order received. In other words, the display target images are displayed on the display unit 71 in the transmission order set in the radiation image capturing apparatus 10. Note that the CPU 73 of the console may display the display target images on the display unit 71 in the order according to the transmission order indicated by the identification information given to each of the display target images.

  In step S52, the CPU 73 of the console 70 needs to analyze the display target image already displayed on the display unit 71, and display an image other than the display target image (non-display target image) on the display unit 71 in step S53. Determine the presence or absence.

  As described above, the radiographic image capturing apparatus 10 determines the presence / absence of a subject image based on the pixel values of the irradiation detection pixels 32 provided in the radiation detection panel 20 of each imaging unit 11 and includes the subject image. An image determined to be displayed is designated as a display target image. However, the number of pixels 32 for irradiation detection provided in each radiation detection panel 20 is smaller than the number of pixels for photographing 31, and it may not be possible to appropriately determine the presence or absence of the subject image. That is, in the radiographic imaging device 10, a case where the subject image is not included in the image specified as the display target image or a case where the subject image is included in the non-display target image is assumed. Therefore, the CPU 73 of the console 70 performs image analysis on the display target image transmitted from the radiation image capturing apparatus 10 and determines whether or not the subject image is appropriately included in the display target image. Since the display target image is a high-definition image generated using the imaging pixels 31, it is possible to perform analysis with higher accuracy than the analysis using the irradiation detection pixels 32.

  For example, the CPU 73 of the console 70 recognizes the shape based on the display target image transmitted from the radiographic image capturing apparatus 10, and when the shape estimated as the subject image is not included in the display target image, other than the display target image May be determined to be displayed on the display unit 71. Further, the CPU 73 of the console 70, for example, an image other than the display target image (non-display target image) when the pixel value histogram pattern in the display target image transmitted from the radiation image capturing apparatus 10 does not satisfy a predetermined condition. May be determined to be displayed on the display unit 71. Further, for example, as shown in FIG. 14, the CPU 73 of the console 70 has the subject image Z recognized in the display target image I transmitted from the radiographic imaging device 10 in contact with the image end E, and the subject image Z However, it may be determined that it is necessary to display the non-display target image on the display unit 71 when it is determined that the non-display target image is not included in the radiation image capturing apparatus 10.

  If the CPU 73 of the console 70 determines in step S53 that an image other than the display target image (non-display target image) needs to be displayed on the display unit 71, the process proceeds to step S54 and is not necessary. If it is determined, the routine is terminated.

  In step S <b> 54, the CPU 73 of the console 70 generates information indicating that an image other than the display target image (non-display target image) needs to be displayed on the display unit 71, and transmits the information to the radiation image capturing apparatus 10. Thus, the radiographic imaging apparatus 10 is requested to transmit an image other than the display target image (non-display target image). For example, if the CPU 73 of the console 70 cannot recognize the subject image in the display target image transmitted from the radiographic image capturing device 10, all the non-display targets held in the image memory 43 of the radiographic image capturing device 10. An image transmission may be requested. Further, the CPU 73 of the console 70 is a non-display target that is estimated to include a missing portion of the subject image Z when the display target image transmitted from the radiation image capturing apparatus 10 is interrupted as shown in FIG. An image transmission may be requested. The radiographic imaging device 10 that has received the transmission request for the non-display target image from the console 70 reads the non-display target image related to the transmission request from the image memory 43 and transmits it to the console 70.

  In step S55, the CPU 73 of the console 70 waits for reception of the non-display target image. When the non-display target image is received, the process proceeds to step S56.

  In step S <b> 56, the CPU 73 of the console 70 controls the display driving unit 77 to display the received non-display target image together with the display target image already displayed on the display unit 71. In other words, the display unit 71 displays a composite image of an image specified as a display target image in the radiographic image capturing apparatus 10 and a non-display target image transmitted later in response to a request from the console 70. . Note that if the image of the console 70 cannot recognize the subject image in the display target image as a result of the image analysis in step S <b> 52, the CPU 73 of the console 70 displays the non-display target image transmitted later instead of the display target image on the display unit 71. You may control the display drive part 77 so that it may display.

  As described above, the console 70 causes the display unit 71 to display the display target images received from the radiographic image capturing apparatus 10 in the order received, and the image memory 43 of the radiographic image capturing apparatus 10 according to the display request for the non-display target image. The non-display target image read from is displayed on the display unit 71 together with the display target image or instead of the display target image.

(System-wide processing)
FIG. 15 is executed in the above-described imaging control processing (see FIG. 10), display target image designation processing (see FIG. 11), transmission control processing (see FIG. 12) performed in the radiographic imaging device 10, and the console 70. It is a figure which shows the flow of a process of the whole system including said imaging | photography preparation process (refer FIG. 9) and display control process (refer FIG. 13).

  First, photographing preparation processing P1 shown in FIG. In the imaging preparation process P1, when a control signal indicating an instruction to start X-ray irradiation is transmitted from the console 70 to the radiographic imaging apparatus 10 (step S15 in FIG. 9), the radiographic imaging apparatus 10 performs an imaging control process P2. The display target image designation process P3 is performed in parallel.

  In the imaging control process P2, each imaging unit 11 generates a radiation image based on the pixel value of the imaging pixel 31, and stores the generated radiation image in the image memory 43 included in each. Each imaging unit 11 shares detection information indicating that X-rays have been detected, and starts an operation for generating a radiation image based on the detection information. Each photographing unit 11 performs photographing processing such as charge accumulation and charge reading at the same timing. For example, even when a subject is placed on the imaging unit 11B and a radiographic image is captured using only the imaging unit 11B, not only the imaging unit 11B but also the imaging units 11A and 11C generate radiographic images. The generated radiation image is stored in its own image memory 43.

  In the display target image designation process P3, each imaging unit 11 determines whether or not the radiographic image generated by itself includes a subject image based on the pixel value of the irradiation detection pixel 32. When each radiographing unit 11 determines that the radiographic image generated by itself includes a subject image, it designates the image as a display target image, and when it determines that the radiographic image generated by itself does not include the subject image. The image is designated as a non-display target image.

  After the imaging control process P2 and the display target image designation process P3 are completed, the radiographic imaging apparatus 10 performs a transmission control process P4. In the transmission control process P4, each photographing unit 11 that has generated the display target image derives an estimated value of the area of the subject image included in the display target image generated by itself based on the pixel value of the irradiation detection pixel 32. . Each imaging unit 11 that has generated the display target image derives the transmission order of the display target images so that the display target image with a larger estimated area of the subject image included in the display target image is transmitted to the console 70 in advance. Then, the display target images are sequentially transmitted to the console 70 in accordance with the derived transmission order.

  When the display target image transmitted from the radiation image capturing apparatus 10 is received by the console 70, the display control process P5 is performed in the console 70. In the display control process P5, the display target images transmitted from the radiation image capturing apparatus 10 are displayed in the order of reception on the display unit 71 of the console 70. Further, whether or not the display target image needs to be displayed on the display unit 71 in accordance with the determination result of whether or not the display target image is appropriately included in the display target image after image analysis of the display target image is performed in the console 70 Is determined. When the console 70 determines that the non-display target image needs to be displayed on the display unit 71, the console 70 requests the radiographic imaging device 10 to transmit the non-display target image. The radiographic imaging device 10 that has received the transmission request for the non-display target image from the console 70 reads the non-display target image related to the transmission request from the image memory 43 and transmits it to the console 70. The console 70 replaces the non-display target image transmitted later from the radiographic imaging apparatus 10 with the display target image already displayed on the display unit 71 or with the display target image already displayed on the display unit 71. Are displayed on the display unit 71.

  As is clear from the above description, in the radiographic image capturing system 100 according to the embodiment of the present invention, it is estimated that the radiographic images generated in the plurality of imaging units 11A, 11B, and 11C include subject images. Only the image to be displayed is designated as the display target image and transmitted to the console 70. Thus, by carefully selecting the images to be transmitted to the console 70, the amount of data transmitted to the console 70 can be suppressed, whereby all the radiographic images generated by each imaging unit 11 are displayed on the console 70. The data transfer time can be shortened as compared with the case of transmitting to. Therefore, it is possible to shorten the waiting time until the image is displayed on the display unit 71 of the console 70 as compared with the conventional case.

  In addition, since the transmission order of the display target images is determined in accordance with the estimated area of the subject included in the display target images generated by each photographing unit 11, an image with higher importance is promptly displayed on the display unit 71 of the console 70. Can be displayed.

  In addition, the display target image designation process and the display target image transmission order derivation process performed in the radiation image capturing apparatus 10 are performed using the irradiation detection pixels 32 having a smaller number of pixels than the imaging pixels 31. Therefore, each of the above processes can be performed in a relatively short time. Therefore, the influence on the display waiting time by the display target image specifying process and the display target image transmission order derivation process is limited.

  Further, when the display target image is analyzed in the console 70 and it is determined that the display of the image designated as the non-display target image in the radiographic image capturing apparatus 10 is necessary, the radiographic image capturing apparatus 10 is instructed. A transmission request for a non-display target image is made. The radiographic images generated in each of the imaging units 11A, 11B, and 11C are stored in the image memory 43 regardless of whether or not the images are display target images, and even after the display target images are transmitted to the console 70. It is held in the image memory 43. Therefore, when there is a non-display target image transmission request from the console 70, the radiographic image capturing apparatus 10 can transmit the non-display target image to the console 70 in response to the transmission request. As described above, in the radiographic image capturing system 100, the non-display target image can be displayed even when the designation of the display target image in the radiographic image capturing apparatus 10 is not appropriate, thereby avoiding the risk of re-imaging. be able to.

  In addition, each imaging unit 11A, 11B, 11C starts imaging operations all at once by sharing detection information indicating that X-rays generated in any of the imaging units are detected. A radiographic image can be generated even in the imaging unit 11 that is not. Thereby, even when the subject image is included in the radiation image generated by the imaging unit 11 that was not supposed to be used at the beginning, the subject image can be displayed. According to the radiographic image capturing apparatus 10 according to the embodiment of the present invention, it is possible to avoid the risk of re-imaging from such a viewpoint. In addition, the user can set the arrangement of the subject with respect to the radiographic image capturing apparatus 10 without considering the boundaries between the image capturing units 11A, 11B, and 11C.

  As described above, according to the radiographic image capturing system 100 according to the embodiment of the present invention, it is possible to shorten the waiting time until image display on the external apparatus, while avoiding the risk of re-imaging.

  In the present embodiment, even after the display target image is transmitted to the console 70, a corresponding radiation image (display target image or non-display target image) is stored in each of the image memories 43 of the imaging units 11A, 11B, and 11C. However, the present invention is not limited to this mode. For example, after the display target image is transmitted to the console 70 (after the console 70 receives the display target image), only the non-display target image may be held in the image memory 43. That is, after the display target image is transmitted to the console 70 (after the console 70 receives the display target image), the display target image may be deleted from the image memory 43. Thereby, the storage area of the image memory 43 can be secured.

  Further, from the viewpoint of securing the storage area of the image memory 43 of each photographing unit 11, it is preferable to delete the image stored in the image memory 43 as appropriate. The image erasure from the image memory 43 may be performed at the following timing, for example. (1) Before the next X-ray irradiation is performed, (2) After completion of imaging of the same patient, (3) After the user operating the console 70 determines an image to be used for diagnosis, (4) A radiographic image After the image generated by the imaging apparatus 10 is transmitted to the PACS (Picture Archiving and Communication System) connected to the radiographic imaging system 100 via the network, (5) the diagnosis of the doctor is completed and the electronic medical record or the like (6) After the user operating the console 70 instructs the image erasing by operating the operation input unit 72.

  In either case, an instruction to erase an image is transmitted from the console 70 to the radiographic imaging apparatus 10. The radiographic image capturing apparatus 10 erases all or part of the image from the image memory 43 based on the above instruction. Note that the user may erase all or part of the images stored in the image memory 43 by directly manually operating the radiation image capturing apparatus 10.

[Second Embodiment]
FIG. 16 shows a second embodiment of the present invention which is implemented by the CPU 51 constituting the photographing unit control unit 50 of each of the photographing units 11A, 11B, and 11C executing the transmission control program 57 stored in the ROM 53. It is a flowchart which shows the flow of the transmission control process which concerns.

  The processes in steps S61 to S63 in the transmission control process according to the second embodiment are the same as the processes in steps S41 to S43 in the transmission control process (see FIG. 12) according to the first embodiment described above, and therefore overlapping. Description to be omitted.

  The CPU 51 of each photographing unit 11 that has generated the display target image in step S64 transmits the display target image generated by itself to the console 70 via the communication cable 110 according to the transmission order derived in step S63. Identification information indicating that the images are display target images and the transmission order of the images is assigned to each of the display target images to be transmitted. In step S65, the CPU 51 of each photographing unit 11 determines whether or not a non-display target image exists. When the CPU 51 of each photographing unit 11 determines that there is a non-display target image, the process proceeds to step S66, and when it is determined that there is no non-display target image, this routine is terminated.

  In step S <b> 66, the CPU 51 of each photographing unit 11 that has generated the non-display target image transmits the non-display target image generated by itself to the console 70 via the communication cable 110. Identification information indicating that the image is a non-display target image is given to the non-display image to be transmitted. The display target image and the non-display target image transmitted to the console 70 are stored in the RAM 74 or the HDD 75 of the console 70. Note that the RAM 74 or the HDD 75 according to the second embodiment of the present invention is an example of a storage medium in the present invention.

  As described above, in the transmission control processing according to the second embodiment, regardless of whether all the radiographic images generated in each of the imaging units 11A, 11B, and 11C are display target images or non-display target images. To the console 70. Since the display target image is transmitted prior to the non-display target image, the console 70 receives the display target image prior to the non-display target image.

  In the present embodiment, a process of deriving an estimated value of the area of the subject image based on the pixel value of the irradiation detection pixel 32 (step S61), and the estimated value of the area of the derived subject image is used as each imaging unit 11. (Step S62), and the radiographic imaging apparatus 10 performs the process of deriving the transmission order of the radiographic image (display target image) (step S63). Good.

  FIG. 17 is a flowchart showing the flow of display control processing according to the second embodiment of the present invention, which is performed when the CPU 73 of the console 70 executes the display control program 83 stored in the ROM 76.

  Since the process of steps S71 to S73 in the display control process according to the second embodiment is the same as the process of steps S51 to S53 in the display control process (see FIG. 13) according to the first embodiment described above, The description to be omitted is omitted. In step S71, the CPU 73 of the console reads the display target image from the RAM 74 or the HDD 75 and displays it on the display unit 71. In this case, the display target image may be identified by referring to the identification information given to the display target image.

  In step S <b> 74, the CPU 73 of the console 70 reads the non-display target image that is transmitted from the radiation image capturing apparatus 10 and stored in the RAM 74 or the HDD 75. In this case, the non-display target image may be identified by referring to the identification information given to the non-display target image.

  In step S <b> 75, the CPU 73 of the console 70 controls the display driving unit 77 to display the non-display target image read from the RAM 74 or the HDD 75 together with the display target image already displayed on the display unit 71. That is, the display unit 71 displays a composite image of an image designated as a display target image in the radiographic image capturing apparatus 10 and a non-display target image. Note that the CPU 73 of the console 70 displays the non-display target image read from the RAM 74 or the HDD 75 instead of the display target image on the display unit 71 when the subject image cannot be recognized in the display target image as a result of the image analysis in step S72. You may control the display drive part 77 so that it may display.

  As described above, in the radiographic image capturing system 100 according to the second embodiment of the present invention, all the radiographic images generated in the respective imaging units 11A, 11B, and 11C are transmitted to the console 70. Of the radiographic images generated in each of the imaging units 11A, 11B, and 11C, an image designated as a display target image is transmitted to the console 70 in advance of the non-display target image, and is displayed on the display unit 71 of the console 70. Is displayed. Therefore, according to the radiographic image capturing system 100 according to the second embodiment, it is possible to shorten the waiting time until image display as compared with the first embodiment, as in the first embodiment.

  Further, since the non-display target image can be displayed even when the designation of the display target image in the radiographic image capturing apparatus 10 is not appropriate, the risk of re-imaging can be avoided.

  According to the radiographic image capturing system 100 according to the second embodiment, since the non-display target image is held in the RAM 74 or the HDD 75 of the console 70, the non-display is performed after it is determined that the display of the non-display target image is necessary. The time until the target image is displayed on the display unit 71 can be shortened as compared with the first embodiment. Note that according to the radiographic image capturing system 100 according to the first embodiment, the radiographic image capturing apparatus 10 does not need to transmit a non-display target image unless there is a transmission request from the console 70. Can be shortened. Thereby, in the radiographic imaging device 10 which concerns on 1st Embodiment, it can transfer to the following imaging | photography process rapidly.

  In addition, from the viewpoint of securing the storage area of the RAM 74 or the HDD 75 of the console 70, it is preferable to delete the images stored in these appropriately. The image erasure from the RAM 74 or the HDD 75 may be performed, for example, at the timings (1) to (6) described above.

[Third Embodiment]
FIG. 18 shows a third embodiment of the present invention which is implemented by the CPU 51 configuring the photographing unit control unit 50 of each of the photographing units 11A, 11B, and 11C executing the transmission control program 57 stored in the ROM 53. It is a flowchart which shows the flow of the transmission control process which concerns.

  Since the processes of steps S81 to S83 in the transmission control process according to the third embodiment are the same as the processes of steps S41 to S43 in the transmission control process (see FIG. 12) according to the first embodiment described above, The description to be omitted is omitted.

  In step S <b> 84, the CPU 51 of the photographing unit 11 that has generated the display target image to be transmitted first transmits the display target image generated by itself to the console 70 via the communication cable 110.

  In step S85, the CPU 51 of each photographing unit 11 determines whether there is a display target image to be transmitted second. When the CPU 51 of each photographing unit 11 determines that there is a display target image to be transmitted second, the process proceeds to step S86 and determines that there is no display target image to be transmitted second. This routine is terminated.

  In step S86, the CPU 51 of the photographing unit 11 that has generated the display target image to be transmitted secondly consoles the display target image generated by itself in order from the end side adjacent to the display target image transmitted first. 70. That is, the CPU 51 of the photographing unit 11 that has generated the display target image to be transmitted secondly transmits the display target image generated by itself to the image data on the edge side adjacent to the first display target image. Is sent to the console 70 so as to precede. In other words, the CPU 51 of the photographing unit 11 that has generated the display target image to be transmitted secondly displays the display target image generated by itself and the radiation detection panel 20 that has generated the display target image transmitted first and the CPU 51 itself. Are transmitted to the console 70 in order from the end side forming the overlapping portion of the imaging region with the radiation detection panel 20 corresponding to.

  In step S87, the CPU 51 of each photographing unit 11 determines whether there is a display target image to be transmitted third. When the CPU 51 of each photographing unit 11 determines that there is a third display target image to be transmitted, the process proceeds to step S88 and determines that there is no third display target image to be transmitted. This routine is terminated.

  In step S88, the CPU 51 of the photographing unit 11 that has generated the display target image to be transmitted thirdly displays the display target image generated by itself on the end side adjacent to the display target image transmitted first or second. To the console 70 in order. The CPU 51 of the photographing unit 11 that has generated the display target image to be transmitted thirdly displays the display target image generated by itself on the edge side image data adjacent to the first or second transmitted display target image. It transmits to the console 70 so that transmission may precede. In other words, the CPU 51 of the photographing unit 11 that has generated the display target image to be transmitted thirdly, the radiation detection panel that has generated the display target image that has been transmitted first or second. 20 and the radiation detection panel 20 corresponding to itself are transmitted to the console 70 in order from the end side forming the overlapping portion of the imaging region.

  In the present embodiment, a process for deriving an estimated value of the area of the subject image based on the pixel value of the irradiation detection pixel 32 (step S81), and the estimated value of the area of the derived subject image is used as each imaging unit 11. (Step S82), and the radiographic imaging apparatus 10 performs the process of deriving the transmission order of the radiographic image (display target image) (step S83). Good.

The contents of the transmission control process according to the third embodiment will be described with reference to FIG. Here, it is assumed that the subject O is disposed across the three photographing units 11A, 11B, and 11C. The radiation image I _B generated by the imaging unit 11B, is specified as a display target image, the transmitting sequence of the radiation image I _B is assumed to be set first. The radiation image I _A generated by the imaging unit 11A, is specified as a display target image, the transmitting sequence of the radiation image I _A is assumed to be set to the second. In addition, it is assumed that the radiation image I _C generated by the imaging unit 11C is designated as a display target image, and the transmission order of the radiation image I _C is set to the third.

CPU51 of the photographing unit 11A which generates a display target image I _A to be transmitted to the second is the display target image I _A generated by itself, the end portion adjacent to the display target image I _B sent to the first E _B1 The data is transmitted to the console 70 in the order from the side toward the opposite end _EB2 side. In other words, the radiation detection panel 20B that CPU51 produced a display target image I _B sent to the first imaging unit 11A which generates a display target image I _A to be transmitted to the second, to be transmitted to the second transmitting a display target image I _a in the order toward the end portion E _B2 from the end portion E _B1 side to form the overlapping portion Y1 of the imaging area of the other side of the radiation detection panel 20A which generates a display target image I _a to the console 70 To do. That is, the transmission of the image data of the end portion E _B1 side, the display target image I _A to the preceding is transmitted than the transmission of the image data of the end portion E _B2 side.

End Similarly, CPU 51 of the imaging unit 11C which generates a display target image I _C to be transmitted to the third, the adjacent displayed images I _C generated by itself, a display target image I _B sent to the first The data is transmitted to the console 70 in the order from the part E _C1 side to the opposite end E _C2 side. In other words, CPU 51 of the imaging unit 11C which generates a display target image I _C to be transmitted to the third is a radiation detection panel 20B which generates a display target image I _B transmitted to the first, be transmitted to the third It displayed images I _C to the console 70 in the order toward the end portion E _C2 opposite from the end portion E _C1 side to form the overlapping portion Y2 of the imaging region of the radiation detection panel 20C which generates a display target image I _C to Send. That is, the display target image I _C is transmitted so that the transmission of the image data on the end E _C1 side precedes the transmission of the image data on the end E _C2 side.

The display unit 71 of the console 70, after which the display target image I _B is displayed, the display target image I _A is displayed in this order from the end portion E _B1 side adjacent to the display target image I _B, the display target image I _A after There is displayed, the display target image I _C are displayed in order from the end E _C1 side adjacent to the display target image I _B.

  In this way, among the display target images generated by each of the two radiation detection panels 20 adjacent to each other, the image to be transmitted later is sequentially displayed from the end side forming the overlapping portion of the two radiation detection panels 20. By transmitting, the entire image of the subject can be quickly displayed on the display unit 71 of the console 70.

[Fourth Embodiment]
FIG. 20 shows a fourth embodiment of the present invention which is implemented when the CPU 51 constituting each photographing unit control unit 50 of the photographing units 11A, 11B, and 11C executes the transmission control program 57 stored in the ROM 53. It is a flowchart which shows the flow of the transmission control process which concerns.

  Since the processes of steps S91 to S94 in the transmission control process according to the fourth embodiment are the same as the processes of steps S41 to S44 in the transmission control process (see FIG. 12) according to the first embodiment described above, The description to be omitted is omitted.

  In step S95, the CPU 51 of each photographing unit 11 determines whether or not a non-display target image exists. If the CPU 51 of each photographing unit 11 determines that there is a non-display target image, the process proceeds to step S96. If it is determined that there is no non-display target image, the routine is terminated.

  In step S <b> 96, the CPU 51 of the photographing unit 11 that has generated the non-display target image includes, on the console 70, an image portion included in a predetermined range starting from an end on the side adjacent to the display target image. Send.

The contents of the transmission control process according to the fourth embodiment will be described with reference to FIG. Here, only the radiation image I _B generated by the imaging unit 11B is specified as a display target image, the radiation image I _C generated by the radiation image I _A and the photographing unit 11C generated by the imaging unit 11A, the non It is assumed that the image is a display target image.

CPU51 of the photographing unit 11A, among the non-display target image _{I A} generated by itself, the display target image _I console 70 the image portion included in the predetermined range _{I AE} originating an end _{E B1} on the side _B and the adjacent Send to. Similarly, CPU 51, among the non-display target image _{I C} generated by itself, the image portion included in the predetermined range _{I CE} originating side end _{E C1} adjacent to the display target image _{I B} of the photographing unit 11C Is transmitted to the console 70.

  In the present embodiment, a process for deriving an estimated value of the area of the subject image based on the pixel value of the irradiation detection pixel 32 (step S91), and the estimated value of the area of the derived subject image is used as each imaging unit 11. (Step S92) and the radiographic image capturing apparatus 10 performs the process of deriving the transmission order of the radiographic image (display target image) (step S93). Good.

As described above, since the accuracy of subject recognition using the irradiation detection pixels 32 in the display target image designation process (see FIG. 11) is not high, as shown in FIG. 21, the radiation image I including a part of the subject image. _A and I _C may not be designated as display target images. In this case, in an embodiment of the transmission control process (FIG. 12) according to a first embodiment of the radiation image I _A and I _C is not transmitted to the console 70. Accordingly, the display control process performed by the console 70 radiographic images I _A and I _C according to the result of the image analysis in (see FIG. 13) becomes the be displayed with a delay to the radiation image I _B, total subject The waiting time until the image is displayed on the display unit 71 becomes longer.

  According to the transmission control process according to the fourth embodiment, even for a non-display target image, an image portion included in a predetermined range starting from an end on the side adjacent to the display target image is transmitted to the console 70. The Accordingly, as shown in FIG. 21, the image of the subject O arranged across the imaging units 11A, 11B, and 11C (radiation detection panels 20A, 20B, and 20C) and generated in any of the imaging units 11 is not displayed. Even in the case of an image, the entire image of the subject can be quickly displayed on the display unit 71 of the console 70.

[Fifth Embodiment]
FIG. 22 is a diagram illustrating a luminance distribution of a radiographic image generated when a uniform dose of X-rays is irradiated to the radiation detection panel 20B of the imaging unit 11B arranged in the center. The radiation detection panel 20B is disposed downstream of the radiation detection panel 20A of the imaging unit 11A and the radiation detection panel 20C of the imaging unit 11C in the X-ray irradiation direction. One end of the imaging region R _B in the radiation detection panel 20B is superposed on the irradiation direction of the one end portion and the X-ray imaging area R _A of the radiation detection panel 20A, imaging region R in a radiation detection panel 20B The other end of _B overlaps with one end of the imaging region _RC in the radiation detection panel 20C in the X-ray irradiation direction. Hereinafter, imaging area designated as R _A and the photographing region R _B and overlaps the overlap portion section Y1, referred to as imaging region R _B and imaging region R _C and overlapping portions overlapping portion Y2.

The overlapping portions Y1 and Y2 of the radiation detection panel 20B are irradiated with X-rays attenuated by passing through the imaging region _RA of the radiation detection panel 20A and the imaging region _RC of the radiation detection panel 20C, respectively. For this reason, as shown in FIG. 22, the brightness | luminance of the part corresponding to the overlapping parts Y1 and Y2 of the radiographic image produced | generated by the radiation detection panel 20B becomes lower than the brightness | luminance in another part. Therefore, it is preferable to perform luminance correction on the portions corresponding to the overlapping portions Y1 and Y2 of the radiation images generated by the radiation detection panel 20B.

  The luminance correction of the image portion corresponding to the overlapping portion Y1 of the radiation image generated by the radiation detection panel 20B is performed using the pixel value of the image portion corresponding to the overlapping portion Y1 of the radiation image generated by the radiation detection panel 20A. be able to. This is because the pixel value is based on X-rays that include image information corresponding to the image portion corresponding to the overlapping portion Y1 of the radiation images generated by the radiation detection panel 20B and that are not attenuated.

  Similarly, the luminance correction of the image portion corresponding to the overlapping portion Y2 of the radiation image generated by the radiation detection panel 20B is performed by changing the pixel value of the image portion corresponding to the overlapping portion Y2 of the radiation image generated by the radiation detection panel 20C. Can be used. This is because the pixel value is based on X-rays that include image information corresponding to the image portion corresponding to the overlapping portion Y2 of the radiation images generated by the radiation detection panel 20B and that are not attenuated.

  Therefore, in the radiographic image capturing system according to the fifth embodiment of the present invention, the radiographic image capturing apparatus 10 is a radiographic image generated by the image capturing unit 11A (radiation detection panel 20A) and the image capturing unit 11C (radiation detection panel 20C). However, even when the non-display target image is selected, the image portions corresponding to the overlapping portions Y1 and Y2 are transmitted to the console 70 as correction images. The console 70 corrects the radiation image as the display target image generated by the imaging unit 11B (radiation detection panel 20B) using the correction image.

  FIG. 23 shows a fifth embodiment of the present invention which is implemented when the CPU 51 constituting each photographing unit controller 50 of the photographing units 11A, 11B, and 11C executes the transmission control program 57 stored in the ROM 53. It is a flowchart which shows the flow of the transmission control process which concerns.

  Since the processes of steps S101 to S104 in the transmission control process according to the fifth embodiment are the same as the processes of steps S41 to S44 in the transmission control process (see FIG. 12) according to the first embodiment described above, The description to be omitted is omitted.

  In step S105, the CPU 51 of each imaging unit 11 determines whether or not the radiation image generated in the imaging unit 11B arranged on the downstream side in the X-ray irradiation direction is a display target image. If the CPU 51 of each imaging unit 11 determines that the radiographic image generated in the imaging unit 11B is a display target image, the process proceeds to step S106. End the routine.

  In step S106, the CPU 51 of each imaging unit 11 determines whether or not the radiation image generated in the imaging units 11A and 11C arranged on the upstream side in the X-ray irradiation direction is a non-display target image. If the CPU 51 of each imaging unit 11 determines that the radiation image generated in the imaging units 11A and 11C is a non-display target image, the process proceeds to step S107 and determines that the image is not a non-display target image. If so, this routine is terminated.

  In step S107, the CPU 51 of the photographing unit 11 (one or both of the photographing units 11A and 11B) that has generated the non-display target image corresponds to the overlapping portion Y1 or Y2 among the non-display target images generated by itself. The image portion is transmitted to the console 70 as a correction image.

  In the present embodiment, processing for deriving an estimated value of the area of the subject image based on the pixel value of the irradiation detection pixel 32 (step S101), and the estimated value of the area of the derived subject image is used for each photographing unit 11. (Step S102), and the radiographic imaging apparatus 10 performs the process (step S103) for deriving the transmission order of the radiographic image (display target image). Good.

The contents of the transmission control process according to the fifth embodiment will be described with reference to FIG. Here, only the radiation image I _B generated by the imaging unit 11B (radiation detection panel 20B) is displayed is designated as the target image, photographing unit 11A (radiation detection panel 20A) radiation images I _A and a photographing unit generated by 11C radiographic image I _C generated by the (radiation detection panel 20C) is assumed to be a non-display target image.

CPU51 of the photographing unit 11A, among the non-display target image _{I A} generated by itself, and transmits to the console 70 the image part _{I AP} corresponding to the overlapping portion Y1 as correction image. Similarly, CPU 51 of the imaging unit 11C, among the non-display target image I _C generated by itself, and transmits to the console 70 the image part I _CP corresponding to the overlapping portion Y2 of the shooting area as a correction image.

  FIG. 25 is a flowchart showing the flow of display control processing according to the fifth embodiment of the present invention, which is performed when the CPU 73 of the console 70 executes the display control program 83 stored in the ROM 76.

  In step S111, the CPU 73 of the console 70 displays the display target images transmitted from the radiation image capturing apparatus 10 on the display unit 71 in the order of reception. In this case, the end portion (image portion corresponding to the overlapping portions Y1 and Y2) of the display target image generated by the imaging unit 11B (radiation detection panel 20B) is set to non-display or black display.

  In step S112, the CPU 73 of the console 70 transmits, from the radiographic image capturing device 10, the end portion of the display target image generated by the imaging unit 11B (radiation detection panel 20B) (the image portion corresponding to the overlapping portions Y1 and Y2). Correction is performed using the corrected image. That is, the luminance value of each pixel at the end of the display target image generated by the imaging unit 11B (radiation detection panel 20B) (the image portion corresponding to the overlapping portions Y1 and Y2) is used as the luminance of the corresponding pixel in the correction image. Correct based on Such correction eliminates the influence of X-ray attenuation at the end of the display target image generated by the imaging unit 11B (radiation detection panel 20B) (the image portion corresponding to the overlapping portions Y1 and Y2).

  In step S113, the CPU 73 of the console 70 displays the image portion corrected in step S112 on the display unit 71. That is, the image portion that was not displayed or displayed in black in step S111 is displayed through the correction process. As a result of the above correction processing, the luminance step as shown in FIG. 21 is eliminated in the radiographic image generated by the imaging unit 11B (radiation detection panel 20B).

  The subsequent processes in steps S114 to S118 are the same as the processes in steps S52 to S56 in the display control process (see FIG. 13) according to the first embodiment described above, and a duplicate description will be omitted.

  As described above, according to the radiographic image capturing system of the fifth embodiment of the present invention, at least of the radiographic images generated in the image capturing unit 11A (radiation detection panel 20A) and the image capturing unit 11C (radiation detection panel 20C). Even when one of the images is a non-display target image, luminance correction processing can be performed using a part of the non-display target image as a correction image, and the display target generated in the imaging unit 11B (radiation detection panel 20B). The image quality can be improved.

  Further, the display target image other than the end portions (image portions corresponding to the overlapping portions Y1 and Y2) of the display target image generated by the imaging unit 11B (radiation detection panel 20B) is received by the console 70, and then the above Since it is displayed immediately without waiting for the end of the correction process, an increase in waiting time until image display can be avoided. In addition, after the above correction processing is completed, all the display target images may be displayed on the display unit 71 all at once.

  Further, since the radiographic image capturing apparatus 10 transmits only the image portion necessary for correction among the non-display target images to the console 70, the data transmission time and the correction are compared with the case of transmitting the entire non-display target image. The processing time can be shortened, and as a result, the display wait time for the image after the correction process can be shortened.

  In the present embodiment, when the radiographic image generated in the imaging unit 11B is a display target image and at least one of the radiographic images generated in the imaging units 11A and 11C is a non-display target image, Although the non-display target image is always transmitted to the console 70 as a correction image, the present invention is not limited to this mode. For example, the radiographic image capturing apparatus 10 may transmit a correction image to the console 70 in response to a transmission request from the console 70. For example, the console 70 issues a transmission request for the correction image to the radiographic image capturing apparatus 10 based on the analysis result of the display target image or an instruction given by the user via the operation input unit 72, and the correction is performed after the correction image is received. Processing may be performed.

Here, FIG. 26 is a schematic configuration diagram of the radiation detection panel 20A and the signal processing unit 42 constituting the imaging unit 11A. The signal processing unit 42 includes a plurality of signal processing circuits 42 a each connected to a plurality of signal lines 36. That is, the signal transmitted to each of the signal lines 36 provided in the radiation detection panel 20A is processed by the corresponding signal processing circuit 42a. In FIG. 26, the overlapping portion Y1 is indicated by hatching in a portion where the imaging region _RA and the imaging region R _B (not shown in FIG. 26) overlap. As shown in FIG. 26, it is preferable that the overlapping portion Y1 is within the processing target range in the single signal processing circuit 42a. As a result, in the photographing unit 11A, it is possible to generate image data for the correction image by driving the single signal processing circuit 42a (the rightmost signal processing circuit 42a in FIG. 26), and the correction image can be generated. Generation can be done quickly. Similarly, in the photographing unit 11C, it is preferable that the overlapping portion Y2 is within the processing target range in the single signal processing circuit 42a.

[Sixth Embodiment]
In the field of image processing, there is known a method for specifying blurring of an image by a point spread function (PSF). That is, the point image is not projected as it is, but is projected while being diffused according to the point spread function.

Here, when the original image before deterioration is f (x, y), the image after deterioration is g (x, y), and the spatial filter corresponding to the point spread function is h (x, y), the image after deterioration is obtained. G (x, y) can be expressed by the following equation (1).
g (x, y) = f (x, y) * h (x, y) (1)
When the equation (1) is Fourier transformed, the following equation (2) is obtained.
G (u, v) = F (u, v) H (u, v) (2)
From the formula (2), the following formula (3) is obtained.
F (u, v) = G (u, v) / H (u, v) (3)
Therefore, the original image before degradation can be restored by performing inverse Fourier transform on the product of the Fourier transform G (u, v) of the degraded image and the inverse filter 1 / H (u, v). Hereinafter, such restoration processing is referred to as point diffusion correction processing.

  Since the image after deterioration is an image formed by diffusing each point image constituting the original image before deterioration, in order to perform point diffusion correction processing, the spread range of the image after deterioration (the original image is It is necessary to specify a diffusion range of a point image based on a point spread function, that is, an outer edge of a blurred image (outer edge of a blurred image). The spread range of the image after deterioration is considered to change according to the diffusion angle and the diffusion distance, and the diffusion angle and the diffusion distance have a correlation with the thickness of the subject (height from the imaging surface, body thickness). Conceivable. That is, it is considered that as the subject thickness (body thickness) increases, the point image diffusion range increases and the subject image extension range increases.

  Therefore, in the radiographic imaging system according to the sixth exemplary embodiment of the present invention, the radiographic imaging apparatus 10 is included in the subject information notified from the console 70 in step S13 of the imaging preparation process (see FIG. 9). The range of the subject image based on the point spread function is specified based on the thickness of the subject to be measured (body thickness). The radiographic imaging device 10, when the non-display target image includes the specified range of the subject image, includes at least an image portion of the non-display target image that includes the range of the subject image. The image is transmitted to the console 70 as a correction image for the point diffusion correction process. Note that the entire non-display target image may be transmitted to the console 70 as a correction image for the point diffusion correction process. When the range of the subject image extends to the non-display target image, the console 70 deteriorates a series of images including the display target image and the image portion of the non-display target image that is the correction image after degradation. The above point diffusion correction processing is performed on the image g (x, y).

  FIG. 27 shows a sixth embodiment of the present invention which is implemented by the CPU 51 constituting each photographing unit controller 50 of the photographing units 11A, 11B, and 11C executing the transmission control program 57 stored in the ROM 53. It is a flowchart which shows the flow of the transmission control process which concerns.

  Since the processes of steps S121 to S124 in the transmission control process according to the sixth embodiment are the same as the processes of steps S41 to S44 in the transmission control process (see FIG. 12) according to the first embodiment described above, The description to be omitted is omitted.

  In step S125, the CPU 51 of each imaging unit 11 detects the subject thickness (body thickness) and irradiation detection included in the subject information notified from the console 70 in step S13 of the imaging preparation process (see FIG. 9). Based on the result of subject recognition using the pixels 32, the extent of the subject image (the range in which the original image is diffused, the outer edge of the blurred image) is estimated. For example, a table that defines the correspondence between the thickness of the subject (body thickness) and the extent of the subject image may be used to estimate the extent of the subject image. The table may be created based on actual measurement using a phantom, for example.

  In step S126, the CPU 51 of each photographing unit 11 determines whether or not the non-display target image includes the range of the subject image estimated in step S125. When the CPU 51 of each photographing unit 11 determines that the subject image expansion range is included in the non-display target image, the process proceeds to step S127, and the subject image expansion range is included in the non-display target image. If it is determined that it is not, the routine is terminated.

  In step S127, the CPU 51 of the photographing unit 11 that has generated the non-display target image including the expansion range of the subject image includes an image including the expansion range of the subject image among the non-display target images generated by itself. Send the part to the console 70.

  In the present embodiment, a process for deriving an estimated value of the area of the subject image based on the pixel value of the irradiation detection pixel 32 (step S121), and the estimated value of the area of the derived subject image is used as each imaging unit 11. (Step S122), and the radiographic imaging apparatus 10 performs the process (step S3) for deriving the transmission order of the radiographic image (display target image). Good.

The contents of the transmission control process according to the sixth embodiment will be described with reference to FIG. Here, only the radiation image I _B generated by the imaging unit 11B (radiation detection panel 20B) is displayed is designated as the target image, photographing unit 11A (radiation detection panel 20A) radiation images I _A and a photographing unit generated by 11C radiographic image I _C generated by the (radiation detection panel 20C) is assumed to be a non-display target image. Further, it is assumed that the range Q of the subject image estimated in each imaging unit 11 is included in each of the radiographic images I _A , I _B , and I _C as shown in FIG.

CPU51 of the photographing unit 11A, among the non-display target image I _A generated by itself, and transmits to the console 70 the image part I _AP that contains the spreading range Q of the object image as a correction image. Similarly, CPU 51 of the imaging unit 11C, among the non-display target image I _C generated by itself, and transmits to the console 70 the image part I _CP that contains the spreading range Q of the object image as a correction image.

  FIG. 29 is a flowchart showing the flow of display control processing according to the sixth embodiment of the present invention, which is performed when the CPU 73 of the console 70 executes the display control program 83 stored in the ROM 76.

  In step S <b> 131, the CPU 73 of the console 70 controls the display driving unit 77 to display the display target images for each imaging unit 11 stored in the RAM 74 or the HDD 75 on the display unit 71 in the order received from the radiation image capturing apparatus 10. Let That is, in step S131, the display unit 71 displays an image before the point diffusion correction process.

  In step S <b> 132, the CPU 73 of the console 70 performs point diffusion correction processing on the display target image displayed on the display unit 71. When the image portion of the non-display target image is transmitted as the correction image from the radiation image capturing apparatus 10, the CPU 73 of the console 70 includes the display target image and the image portion of the non-display target image that is the correction image; A point diffusion correction process is performed on a series of images including the image g (x, y) after deterioration.

  In step S <b> 133, the CPU 73 of the console 70 causes the display unit 71 to display the display target image subjected to the point diffusion correction process.

  Subsequent processes in steps S134 to S138 are the same as the processes in steps S52 to S56 in the display control process (see FIG. 13) according to the first embodiment described above, and thus redundant description is omitted.

  As described above, according to the radiographic image capturing system according to the sixth embodiment of the present invention, even for a non-display target image, an image portion that includes the expansion range of the subject image is corrected. Therefore, even when the non-display target image includes the range of the subject image, the point diffusion correction process can be performed on the display target image.

  In addition, since the display target image is received by the console 70 and immediately displayed in the state before the correction process without waiting for the end of the point diffusion correction process, an increase in waiting time until the image display is avoided. be able to. Note that the display target image after the correction process may be displayed on the display unit 71 after the point diffusion correction process is completed.

  Further, since the radiographic image capturing apparatus 10 transmits only the image portion necessary for correction among the non-display target images to the console 70, the data transmission time and the correction are compared with the case of transmitting the entire non-display target image. The processing time can be shortened, and as a result, the display wait time for the image after the correction process can be shortened.

  In the present embodiment, when the non-display target image includes the expansion range of the subject image, the image portion of the non-display target image is always transmitted to the console 70 as a correction image. It is not limited. For example, the radiographic image capturing apparatus 10 may transmit the correction image to the console 70 in response to a transmission request from the console 70. For example, the console 70 issues a transmission request for the correction image to the radiographic image capturing apparatus 10 based on the analysis result of the display target image or an instruction given by the user via the operation input unit 72, and the correction is performed after the correction image is received. Processing may be performed.

In the present embodiment, the subject image expansion range Q is based on the subject thickness (body thickness) included in the subject information notified from the console 70 and the result of subject recognition using the irradiation detection pixels 32. Is extracted to extract the image portions I _AP and I _CP as the correction images, but the present invention is not limited to this. For example, the radiographic image capturing apparatus 10 analyzes the image generated by itself in each imaging unit 11 to estimate the range of the subject image and extract the image portions I _AP and I _CP as correction images. May be.

Further, the radiographic imaging apparatus 10, information other than thick body of subject information notified from the console 70 (e.g., gender, weight, age) image part I _AP as correction image in consideration also, I _CP may be extracted. Here, it is assumed that the spread range Q of the subject image is determined by scattered radiation, and many scattered radiation is generated at a site having a high density such as bone. Therefore, it is possible to estimate the state of occurrence of scattered rays by estimating the skeleton of the subject based on various information (gender, weight, age, body thickness) included in the subject information, and to estimate the spread range Q of the subject image. it can.

Further, the radiographic imaging apparatus 10 obtains image portions I _AP and I _CP as correction images based on X-ray irradiation conditions such as tube voltage, tube current, and SID (source-image distance) notified from the console 70. It may be extracted. For example, the higher the tube voltage, the higher the X-ray linearity, the less the influence of scattered radiation, and the smaller the subject image expansion range Q. Moreover, since the tube current is proportional to the X-ray dose, it affects the density of the radiation image. Further, the incident angle of the X-ray on the subject changes according to the SID. That is, the larger the SID, the closer the X-ray incident angle to the subject is near the vertical. As a result, it becomes difficult to be affected by scattering, and the spread range Q of the subject image becomes small. On the other hand, the smaller the SID, the oblique incident on the end side of the subject. As a result, it becomes easy to be affected by scattering, and the spread range Q of the subject image becomes large.

[Modification]
The radiographic imaging system according to the embodiment of the present invention has been described above. However, the present invention is not limited to the above-described embodiments, and various modifications can be made.

  In each of the above-described embodiments, the display target image is designated based on the pixel value of the irradiation detection pixel 32, but the present invention is not limited to this. For example, the radiographic image capturing apparatus 10 includes the sex, age, height, target region, and image of the patient as the subject included in the subject information transmitted from the console 70 in step S13 of the imaging preparation process (see FIG. 9). The display target image may be designated based on subject attribute information such as posture. For example, as shown in FIG. 1, in the case where the radiographic imaging device 10 is arranged for standing imaging, when the patient who is the subject is an adult male and the imaging region is the chest, the imaging unit 11A. , 11B, and 11C, the radiographic image generated in the uppermost imaging unit 11A and the central imaging unit 11B may be designated as the display target image. When the display target image is designated based on the subject information as described above, subject attribute information such as the gender, age, height, photographing target part, posture at the time of photographing, etc. of the subject patient and photographing used for photographing. A table that defines the correspondence with the unit 11 may be used. In this way, by specifying the display target image using the subject attribute information and the table, the processing is performed in comparison with the case where the display target image is specified based on the pixel value of the irradiation detection pixel 32. Time can be shortened.

  In addition, when the user specifies the imaging unit 11 to be used for imaging prior to imaging, a radiographic image generated in the specified imaging unit 11 may be specified as a display target image. For example, in step S13 of the imaging preparation process (see FIG. 9), specification information specifying the display target image or the imaging unit 11 to be used may be transmitted from the console 70 to the radiographic imaging apparatus 10 together with the subject information. The radiographic imaging device 10 may designate a display target image based on the designation information. Thus, by specifying the display target image based on the user specification, it is possible to shorten the processing time related to the display target image specification, and it is possible to specify a more appropriate image as a display-to-image. .

  Further, in the display target image designation process (see FIG. 11), when the CPU 51 of each photographing unit 11 determines that the subject detection based on the pixel value of the irradiation detection pixel 32 has failed (error case), the photographing unit. All the radiographic images generated in each of 11A, 11B, and 11C may be designated as display target images. As described above, in the case of an error case, the processing for additionally displaying the non-display target image is not performed by setting all the images as display target images. As a result, the display waiting time of a desired image is reduced. The possibility of shortening is high. Further, when the subject is detected in the imaging units 11A and 11C at both ends, it is assumed that the subject is also detected in the central imaging unit 11B, and all the radiographic images generated in each of the imaging units 11A, 11B, and 11C are detected. May be designated as the display target image.

  In each of the above embodiments, the transmission order of the display target image to the console 70 is derived based on the estimated area of the subject image derived based on the pixel value of the irradiation detection pixel 32. However, the present invention is not limited to this. For example, the radiographic imaging device 10 includes the sex, age, height, imaging target region, and imaging time of the patient as the subject included in the subject information transmitted from the console 70 in step S13 of the imaging preparation process (see FIG. 9). The transmission order of display target images may be derived based on subject attribute information such as the posture of the subject. For example, as shown in FIG. 1, in the case where the radiographic imaging device 10 is arranged for standing imaging, when the patient who is the subject is an adult male and the imaging region is the chest, the radiographic imaging device 10 is located at the uppermost position. The transmission order may be determined so that the radiographic image generated in the imaging unit 11A arranged is first transmitted to the console 70, and the radiographic image generated in the imaging unit 11B arranged in the center is transmitted second. Good. As described above, when the transmission order of the display target images is determined based on the subject attribute information, the subject attribute information such as the subject's sex, age, height, shooting target part, and posture at the time of shooting, and the display target image transmission are transmitted. A table that defines the correspondence with the order may be used. Thus, by deriving the transmission order of the display target image using the subject attribute information and the table, the processing time can be reduced as compared with the case of deriving the transmission order based on the pixel value of the irradiation detection pixel 32. It can be shortened.

  Prior to imaging, when the user specifies the imaging unit 11 used for imaging and the transmission order of the display target image, the radiographic image generated in the specified imaging unit 11 is specified as the display target image. The transmission order of the display target images to the console 70 may be determined according to the specified order. For example, in step S13 of the shooting preparation process (see FIG. 9), together with subject information, designation information for specifying the display target image or the shooting unit 11 to be used and transmission order information indicating the transmission order of each of the plurality of display target images are consoled. You may transmit to the radiographic imaging apparatus 10 from 70. The radiographic imaging device 10 may specify the display target image based on the designation information and the transmission order information and may determine the transmission order of the display target image. Thus, by determining the transmission order of the display target images based on the user designation, the processing time of the transmission control process (see FIG. 12) can be shortened, and the image desired by the user can be quickly displayed on the display unit of the console 70. 71 can be displayed.

  Further, when the CPU 51 of each photographing unit 11 determines that the subject detection based on the pixel value of the irradiation detection pixel 32 has failed (error case), all of the information generated in each of the photographing units 11A, 11B, and 11C. May be designated as display target images. In this case, the transmission order of the display target images may be transmitted in a predetermined order. Further, when the subject is detected in the imaging units 11A and 11C at both ends, it is assumed that the subject is also detected in the central imaging unit 11B, and all the radiographic images generated in each of the imaging units 11A, 11B, and 11C are detected. May be designated as a display target image. In this case, the radiographic images generated in the imaging units 11A and 11C are transmitted to the console 70 in advance, and the radiographic image generated in the imaging unit 11B is finally consoled. 70 may be transmitted.

  When the display target images generated in the two adjacent shooting units 11A and 11B or the shooting units 11B and 11C are transmitted to the console 70, the display targets generated by the shooting unit 11B arranged in the center. Images may always be sent to the console 70 first. In general, since there is a high possibility that the region of interest is arranged on the central photographing unit 11B, by determining the transmission order as described above, an image with higher importance is transmitted to the console 70 in advance. be able to.

  Further, in each of the above-described embodiments, the designation of the display target image and the derivation of the transmission order of the display target image are performed based on the pixel value of the irradiation detection pixel 32 provided in each radiation detection panel 20. However, the present invention is not limited to this. For example, it is possible to use a known radiation detection device such as an ion chamber provided outside the radiation image capturing apparatus 10 in place of the irradiation detection pixel 32. The ion chamber is configured by disposing a high voltage electrode and a signal electrode in a metal container filled with an inert gas such as xenon gas having a large X-ray absorption coefficient. When X-rays enter the metal container of the ion chamber, the sealed gas is ionized and a current flows between the high voltage electrode and the signal electrode, so that X-rays can be detected. When an ion chamber is used instead of the irradiation detection pixel 32, it is preferable that a plurality of ion chambers be arranged for each of the imaging units 11A, 11B, and 11C. In this case, by defining the positional relationship between each ion chamber and the radiation detection panel 20, the ion chamber can have the same role as the irradiation detection pixel 32. That is, it is possible to specify a display target image and derive a transmission order of display target images based on the output of each ion chamber. By using the ion chamber, even in a radiographic imaging apparatus that does not have irradiation detection pixels, it is possible to designate a display target image based on the X-ray irradiation dose and to derive the transmission order of the display target image.

  Further, in the display control processing according to each of the embodiments described above, the necessity of displaying the non-display target image is determined based on the result of the image analysis of the display target image performed on the console 70. It is not limited to. For example, the necessity of displaying the non-display target image may be determined based on an instruction given by the user via the operation input unit 72 of the console 70. That is, the user confirms the display target image displayed on the display unit 71 of the console 70 and performs an operation for requesting the display of the non-display target image on the operation input unit 72 as necessary. In response to such a user operation, in the aspect of the display control process (FIG. 13) according to the first embodiment, a transmission request for a non-display target image is transmitted from the console 70 to the radiographic image capturing apparatus 10, and the second implementation. In the form of the display control process (see FIG. 17) according to the form, the non-display target image is read from the RAM 74 or the HDD 75 of the console 70.

  Further, in each of the above-described embodiments, the console 70 displays the display target image on the display unit 71 in the order in which the display target images are received (that is, the transmission order set in the radiation image capturing apparatus 10). It is not limited to. For example, the console 70 may perform image analysis before displaying the display target image, and display the display target image in the display order derived according to the analysis result.

  Moreover, in each above-mentioned embodiment, although the case where the radiographic image produced | generated in the radiographic imaging apparatus 10 was displayed on the display part 71 of the console 70 was illustrated, it is not limited to this aspect. For example, the radiographic image generated in the radiographic imaging device 10 may be displayed on a display screen of a device separate from the console 70 such as a portable display terminal device. In this case, the portable display terminal device or the like may have substantially the same function as the console 70, and may perform the display control process according to each of the above-described embodiments. Further, the console 70 may perform the display control processing according to each of the above-described embodiments, and the mobile display terminal device or the like may perform only the image display based on the control by the console 70. That is, the portable display terminal device or the like may have a function as the display unit 71 of the console 70.

  Further, in each of the above-described embodiments, the radiographic images generated in the radiographing units 11A, 11B, and 11C are stored in the image memory 43 of the radiographic image capturing device 10, the RAM 74 of the console 70, or the HDD 75. It is not limited to this aspect. For example, the radiographic images generated in the radiographing units 11A, 11B, and 11C may be stored in an external storage medium that is communicably connected to both the radiographic image capturing apparatus 10 and the console 70. In this case, in response to a transmission request from the console 70, the non-display target image is read from the external storage medium.

  Moreover, in each said embodiment, although the case where the radiation detection panel which employ | adopted the indirect conversion system was illustrated, the radiation detection panel which employ | adopted the direct conversion system may be used. Further, in each of the above embodiments, the case where X-rays are used as the radiation to be irradiated at the time of capturing a radiographic image is exemplified, but other radiations such as gamma rays, ultraviolet rays, and neutron rays may be used. In addition, the processes in the embodiments described above can be performed in combination with each other.

DESCRIPTION OF SYMBOLS 10 Radiation imaging device 11, 11A, 11B, 11C Imaging unit 20, 20A, 20B, 20C Radiation detection panel 31 Imaging pixel 32 Irradiation detection pixel 34 TFT
35 Gate line 36 Signal line 43 Image memory 50 Imaging unit controller 51 CPU
55 Shooting Control Program 56 Display Image Designation Program 57 Transmission Control Program 70 Console 71 Display Unit 73 CPU
74 RAM
75 HDD
82 Imaging Preparation Program 83 Display Control Program 90 Radiation Irradiation Apparatus 100 Radiation Image Imaging System Y1, Y2 Overlapping R _A , R _B , R _C Imaging Area

Claims (30)

Radiation that has a plurality of radiographic image capturing units and a control unit that controls the plurality of radiographic image capturing units, and generates a composite image based on radiation simultaneously irradiated to the plurality of radiographic image capturing units An image capturing system,
The plurality of radiation imaging units include a first radiation imaging unit and a second radiation imaging unit, and each of the plurality of radiation imaging units includes:
A sensor for detecting radiation and obtaining a radiation image signal;
A signal processing unit for reading out and processing the radiation image signal;
A communication unit that outputs a radiation image based on the radiation image signal,
In response to the completion of transmission of the radiation image from the first radiation imaging unit, the control means notifies the second radiation imaging unit,
The second radiographic imaging unit outputs a radiographic image in response to the notification.   The radiographic image capturing system according to claim 1, wherein the second radiographic imaging unit limits transmission of radiographic images until the notification is received after the radiographic image signal is read.   2. The display control unit according to claim 1, further comprising: a display control unit configured to display a combined image obtained by combining the radiographic images when the reception of the radiographic images from the plurality of radiographic units is completed. Or the radiographic imaging system of Claim 2.   The said display control means displays the image based on the received radiographic image on the said display part, when reception of the radiographic image from the said 1st radiography part is completed. Radiation imaging system.   The control unit transmits a radiographic image transmission request to the second radiographic unit after an image based on the radiographic image transmitted from the first radiographic unit is displayed on the display unit. The radiographic imaging system according to claim 4, wherein A radiographic imaging device,
A plurality of radiation detection panels each detecting radiation incident through the subject to generate image data of a radiation image and juxtaposed in a direction intersecting the radiation incident direction;
A designation unit for designating image data of a display target image among image data of a plurality of radiation images generated by each of the plurality of radiation detection panels;
A transmission unit for transmitting image data of at least the display target image to the outside of the radiation image capturing apparatus among the plurality of radiation images;
Different from the first radiation detection panel of the plurality of radiation detection panels in response to completion of transmission of the display target image from the first radiation detection panel of the plurality of radiation detection panels. A control unit for notifying the radiation detection panel 2;
Including
The second radiation detection panel outputs a display target image in response to the notification. The designation unit is provided for each of the plurality of radiation detection panels and outputs the detection target based on a detection signal from each of the sensors that outputs a detection signal having a magnitude corresponding to the dose of the irradiated radiation. The radiographic imaging device according to claim 6 which specifies an image. The radiographic image capturing apparatus according to claim 6, wherein the designation unit designates the display target image based on attribute information indicating an attribute of the subject. The radiographic imaging apparatus according to claim 6, wherein the designation unit designates the display target image based on information for designating the display target image supplied from outside the radiographic imaging apparatus. Each of an external device provided outside the radiographic imaging device is provided corresponding to each of the plurality of radiation detection panels and outputs a detection signal having a magnitude corresponding to the dose of irradiated radiation. Based on the detection signal from, determine the presence or absence of the subject on each radiation detection panel,
The radiographic imaging apparatus according to claim 6, wherein the designation unit designates the display target image based on a determination result of the presence or absence of a subject by the external device. The transmission unit derives the transmission order of the image data of the plurality of display target images when a plurality of images are designated as display target images, and the image data of the plurality of display target images is derived according to the derived transmission order. The radiographic image capturing apparatus according to claim 6, which is sequentially transmitted to the outside of the radiographic image capturing apparatus. The transmission unit is provided corresponding to each of the plurality of radiation detection panels and outputs the detection signal having a magnitude corresponding to the dose of the irradiated radiation based on the detection signals from the sensors. The radiographic imaging apparatus according to claim 11, wherein the transmission order of the image data of the display target image is derived. The radiographic image capturing apparatus according to claim 10, wherein the transmission unit derives a transmission order of image data of the plurality of display target images based on attribute information indicating an attribute of the subject. When the plurality of images are designated as display target images, the transmission unit is indicated by information designating the transmission order of the image data of each of the plurality of display target images supplied from the outside of the radiographic image capturing apparatus. The radiographic image capturing apparatus according to any one of claims 6 to 10, wherein image data of the plurality of display target images is sequentially transmitted to the outside of the radiographic image capturing apparatus in accordance with a transmission order to be transmitted. When a plurality of images are designated as display target images, an external device provided outside the radiation image capturing apparatus is provided corresponding to each of the plurality of radiation detection panels and irradiated radiation dose Deriving the transmission order of the image data of the plurality of display target images based on the detection signals from each of the sensors that output a detection signal having a magnitude according to
11. The transmission unit according to claim 6, wherein the transmission unit sequentially transmits image data of the plurality of display target images to the outside of the radiographic imaging device according to a transmission order derived by the external device. Radiographic imaging device. Each of the plurality of radiation detection panels is arranged so that adjacent radiation detection panels and end portions of imaging regions capable of generating a radiation image overlap each other,
The transmission unit is configured to admit image data to be transmitted later among image data of two display target images generated by two radiation detection panels adjacent to each other to an image indicated by the previously transmitted image data. The radiographic imaging apparatus of any one of Claims 11-15 which transmits to the exterior of the said radiographic imaging apparatus in an order from the part corresponding to the edge part on the side to perform. Each of the plurality of radiation detection panels is arranged so that adjacent radiation detection panels and end portions of imaging regions capable of generating a radiation image overlap each other,
The transmitting unit transmits, to the outside of the radiographic imaging device, image data of an image portion included in a predetermined range starting from an end on a side adjacent to the display target image among radiographic images other than the display target image. The radiographic image capturing apparatus according to claim 6, wherein the radiographic image capturing apparatus is transmitted. Each of the plurality of radiation detection panels shares detection information indicating that radiation is detected by any of the radiation detection panels, and shifts to a radiographic image capturing operation based on the detection information. The radiographic imaging apparatus according to any one of 17. Each of the plurality of radiation detection panels is disposed so that adjacent radiation detection panels and an end of an imaging region capable of generating a radiation image overlap each other in the radiation irradiation direction,
The transmission unit is adjacent to a first radiation detection panel arranged on the downstream side in the radiation irradiation direction for generating image data of the display target image among the plurality of radiation detection panels and other than the display target image. Of the image data of the radiation image generated by the second radiation detection panel arranged on the upstream side in the radiation direction for generating the image data of the radiation image, at least the imaging region of the first radiation detection panel and the The image data of an image portion corresponding to an overlapping portion overlapping with the imaging region of the second radiation detection panel is transmitted to the outside of the radiographic imaging device as image data of a correction image. The radiographic imaging apparatus of item 1. The transmission unit specifies a range of a subject image based on a point spread function based on information indicating at least one of a subject attribute, the plurality of radiation images, and imaging conditions, and the specified range of the subject image Is included in a radiographic image other than the display target image, the image data of the image portion including at least the expansion range of the subject image is included in the radiographic image other than the display target image. The radiographic image capturing apparatus according to any one of claims 6 to 18, wherein the radiographic image capturing apparatus transmits image data of the image to the outside of the radiographic image capturing apparatus. A storage medium that stores at least image data of a radiation image other than the display target image among the plurality of radiation images;
The radiographic imaging apparatus according to any one of claims 6 to 20, wherein the transmission unit transmits image data of the display target image among the plurality of radiographic images to the outside of the radiographic imaging apparatus. The radiographic imaging device according to any one of claims 6 to 18,
A storage medium for storing image data of at least a radiation image other than the display target image among the plurality of radiation images;
The display target image indicated by the image data received from the radiographic imaging device is displayed on a display unit, and when there is a display request, radiation other than the display target image indicated by the image data stored in the storage medium A control device having a display control unit for displaying an image on the display unit together with the display target image;
Including radiographic imaging system. The radiographic imaging device according to claim 19,
A storage medium for storing image data of at least a radiation image other than the display target image among the plurality of radiation images;
The display target image indicated by the image data received from the radiographic imaging device is displayed on a display unit, and when there is a display request, radiation other than the display target image indicated by the image data stored in the storage medium A display control unit configured to display the image together with the display target image on the display unit, and to correct the display target image indicated by the image data generated by the first radiation detection panel using the correction image; A control device;
Including radiographic imaging system. The display control unit includes the display target image indicated by the image data generated by the first radiation detection panel, except for the image portion corresponding to the overlapping portion, before the image portion corresponding to the overlapping portion. The radiographic imaging system according to claim 23, wherein the radiographic image capturing system according to claim 23, wherein the radiographic image capturing system is displayed on the display unit, and an image portion corresponding to the overlapping portion is corrected using the correction image and then displayed on the display unit. The radiographic imaging device according to claim 20,
A storage medium for storing image data of at least a radiation image other than the display target image among the plurality of radiation images;
The display target image indicated by the image data received from the radiographic imaging device is displayed on a display unit, and when there is a display request, radiation other than the display target image indicated by the image data stored in the storage medium A control device having a display control unit for displaying an image together with the display target image on the display unit, and correcting the display target image using the correction image;
Including radiographic imaging system. A radiographic imaging device according to claim 21;
The display target image indicated by the image data received from the radiographic image capturing apparatus is displayed on a display unit, and when there is a display request, image data of a radiographic image other than the display target image stored in the storage medium A control device having a display control unit that requests transmission to the radiographic imaging device and causes the display unit to display a radiographic image other than the display target image indicated by the image data received from the radiographic imaging device;
Including radiographic imaging system. 27. The display control unit, when image data of a plurality of display target images is transmitted from the radiation image capturing apparatus, causes the display unit to display the plurality of display target images in the order received. The radiographic imaging system of any one of Claims. The display control unit recognizes the shape based on the display target image indicated by the image data received from the radiographic image capturing apparatus and sets each pixel value of the display target image indicated by the image data received from the radiographic image capturing apparatus. The radiographic imaging system according to any one of claims 22 to 27, wherein the display request is issued based on the radiation request. The radiographic imaging system according to any one of claims 22 to 28, wherein after the control device receives image data of a display target image, the image data of the display target image is erased from the storage medium. The radiographic imaging system according to any one of claims 22 to 28, wherein image data stored in the storage medium is erased based on an instruction from the control device.