JP6562683B2 - Radiographic apparatus, radiographic method, and program - Google Patents

Description

  The present invention relates to a radiation imaging apparatus having a plurality of imaging modes, a radiation imaging method, and a program.

  A radiographic apparatus using a sensor for detecting radiation such as X-rays is widely used in industrial and medical fields. In such a radiographic apparatus, radiographic images (X-ray images) can be captured in a plurality of imaging modes in accordance with purposes such as moving image shooting and still image shooting (see, for example, Patent Document 1). When radiographic images are captured in a plurality of imaging modes, offset correction and gain correction are performed in order to obtain a radiographic image suitable for diagnosis.

  As an offset correction method, image data acquired without radiation is used as offset correction data, and a radiation image is shot by irradiating the subject with radiation, and then offset correction is performed on the radiation image using the offset correction data. The method is known.

  In addition, as a gain correction method, image data acquired by irradiating radiation in the absence of a subject is used as gain correction data, and a radiation image is shot by irradiating the subject with radiation. A method for performing gain correction on an image is known.

  A radiation imaging apparatus having a plurality of imaging modes needs to acquire correction data for each imaging mode, and preparation for imaging is completed after acquiring correction data for all imaging modes. In particular, since the offset correction data easily changes its characteristics depending on the environment such as temperature, the offset correction data is collected based on image data that is taken without irradiation after the power is turned on and the radiation imaging apparatus is started.

JP 2005-287773 A

  A radiographic apparatus having a moving picture imaging function needs to optimize the size, frame rate, gain setting, and the like in accordance with the imaging technique, and may have dozens of imaging modes. In this case, it is necessary to collect correction data for each shooting mode and deploy it to a high-speed memory.Therefore, when preparation for shooting is completed after acquiring correction data for all shooting modes, shooting is performed after the device is turned on. It takes a long time to become possible.

  The present invention has been made in view of the above-described problem, and an object thereof is to shorten a waiting time until photographing becomes possible.

The radiation imaging apparatus of the present invention includes an imaging mode selection means for selecting at least one of a first imaging mode and a second imaging mode from a plurality of imaging modes;
A first correction data acquisition means for acquiring the pre-Symbol image data captured by the first imaging mode as the first offset correction data,
A second correction data acquisition means for acquiring the pre-Symbol image data taken by the second imaging mode as the second offset correction data,
Notification means for notifying that the first or the second offset correction data has been acquired,
When the first imaging mode is selected by the imaging mode selection unit, the first correction data acquisition unit acquires the first offset correction data after powering on the radiation imaging apparatus,
After the notification means notifies that the first offset correction data has been acquired, the second correction data acquisition means acquires the second offset correction data .

  According to the present invention, it is possible to shorten the waiting time until shooting is possible by preferentially shooting in a predetermined shooting mode and sequentially allowing shooting from the shooting mode in which shooting preparation is completed. .

It is a schematic diagram which shows an example of schematic structure of the radiography system which concerns on this embodiment. It is a schematic diagram which shows an example of the detailed schematic structure of a radiography apparatus and a system control apparatus. It is a figure which shows an example of imaging | photography mode information. It is a figure which shows an example of an imaging | photography mode table. It is a sequence diagram which shows an example of operation | movement of a radiography apparatus. It is a schematic diagram which shows an example of schematic structure of the radiography system which selects imaging | photography mode according to the input order from an input part. It is a sequence diagram which shows an example of operation | movement of the radiography apparatus which selects imaging | photography mode according to the input order from an input part.

  The radiation image processing system according to the embodiment of the present invention will be described below with reference to the drawings. In the present embodiment, the radiation image processing system is a radiation imaging system capable of capturing radiation images in a plurality of imaging modes. FIG. 1 is a schematic diagram illustrating an example of a schematic configuration of a radiation imaging system according to the present embodiment. As shown in FIG. 1, the radiation imaging system includes a radiation imaging apparatus 101, a top plate 201, a radiation generation apparatus 401, a radiation control apparatus 402, a system control apparatus 501, a display apparatus 502, a radiation irradiation switch 503, and an input apparatus 504. Prepare.

  The radiation imaging apparatus 101 corresponds to a radiation image processing apparatus, and performs imaging in a plurality of imaging modes in a state where radiation is irradiated or a state where radiation is not irradiated, and generates radiation image data. The top plate 201 carries a subject 301 as a subject. The radiation generator 401 irradiates the subject 301 with radiation according to the control of the radiation controller 402.

  The system control device 501 is electrically connected to the outside of the radiation imaging apparatus 101 and controls the radiation image processing system. The display device 502 is a display that displays image-processed radiographic image data or a GUI. The radiation irradiation switch 503 executes the start and end of radiation irradiation according to instructions from the operator 601. The input device 504 is an operation panel for inputting an instruction from the operator 601.

  FIG. 2 is a schematic diagram illustrating an example of a detailed schematic configuration of the radiation imaging apparatus 101 and the system control apparatus 501. As shown in FIG. 2, the radiation imaging apparatus 101 includes a photoelectric conversion element (light receiving unit) 102, a drive unit 103, an A / D conversion unit 104, a drive control unit 105, an imaging mode memory 107, an arithmetic processing unit 106, a RAM 108, A ROM 109, a shooting mode control unit 110, a communication unit 111, and an image correction unit 112 are provided. The drive control unit 105, the arithmetic processing unit 106, and the shooting mode control unit 110 may be configured as an electric circuit by a processing device such as a CPU or MPU, and may be configured integrally with the processing device.

  The arithmetic processing unit 106 includes a shooting mode setting unit 116. The shooting mode control unit 110 includes a shooting mode selection unit 120, a first correction data acquisition unit 121, a notification unit 122, and a second correction data acquisition unit 123.

  The system control apparatus 501 includes a radiation generation control unit 505, an imaging control unit 506, an external storage unit 507, a communication unit 508, an input control unit 509, a display control unit 510, a RAM 511, and an arithmetic processing unit 512. The radiation generation control unit 505, the imaging control unit 506, the communication unit 508, the input control unit 509, the display control unit 510, and the arithmetic processing unit 512 are configured as an electric circuit by a processing device such as a CPU or an MPU, and the processing device May be configured integrally.

  Next, functions of the radiation imaging system will be described. The input device 504 inputs subject information such as the ID and name of the subject 301 to the system control device 501. The input device 504 inputs a shooting mode according to the shooting technique. After inputting the imaging mode, the subject 301 is laid on the top plate 201 and the subject 301 is aligned for radiation imaging. When the positioning of the subject 301 is completed, the operator 601 presses the radiation irradiation switch 503. When the radiation irradiation switch 503 is pressed, the radiation control device 402 controls the radiation generation device 401 so that the radiation generation device 401 irradiates the subject 301 with radiation.

  The irradiated radiation passes through the subject and enters the radiation imaging apparatus 101. The radiation imaging apparatus 101 detects the radiation image signal by the photoelectric conversion element 102 after converting the incident radiation into visible light. The radiation imaging apparatus 101 drives the photoelectric conversion element 102 by the driving unit 103 to read out a radiation image signal, and converts an analog signal into a digital signal by the A / D conversion unit 104 to acquire radiation image data. The acquired radiation image data is transmitted to the system control apparatus 501 after being subjected to offset correction and gain correction. The system control device 501 receives the radiation image data, performs image processing, and then displays it on the display device 502.

  Moving image shooting is realized by acquiring radiological image data continuously in time.

  Next, functions of each device will be described. The photoelectric conversion element 102 of the radiation imaging apparatus 101 is configured by two-dimensionally arranging a plurality of pixels (for example, 2688 pixels × 2688 pixels with a resolution of 160 μm), and is formed using amorphous silicon as a main material. The photoelectric conversion element 102 receives the radiation converted into visible light and detects it as a radiation image signal. The drive unit 103 performs a process of driving the photoelectric conversion element 102 and reading out a radiation image signal.

  The A / D conversion unit 104 converts the analog radiographic image signal read out by the driving unit 103 into a digital radiographic image signal, and stores this in the RAM 108 as radiographic image data. The drive control unit 105 controls the drive unit 103 based on commands (instructions) from the shooting mode control unit 110 and the system control device 501.

  The arithmetic processing unit 106 controls the radiation imaging apparatus 101 using programs and various data stored in the RAM 108 and ROM 109. The shooting mode setting unit 116 sets information related to the shooting mode (shooting mode information) and stores it in the shooting mode memory 107. The shooting mode setting unit 116 sets a shooting mode having a high priority (for example, a shooting mode having a high use frequency in an emergency when the subject is transported by ambulance) as shooting mode information. Further, the shooting mode setting unit 116 may set a plurality of shooting modes associated with priorities as shooting mode information.

  FIG. 3 is a diagram illustrating an example of shooting mode information. As shown in FIG. 3, the shooting mode setting unit 116 sets the shooting mode number, size, binning, frame rate, and output gain as shooting mode information. The shooting mode setting unit 116 may assign shooting mode numbers in descending order of shooting mode priority.

  The shooting mode information set by the shooting mode setting unit 116 may be configured by a shooting mode table including one or more shooting modes. FIG. 4 is a diagram illustrating an example of the shooting mode table. As shown in FIG. 4, the shooting mode setting unit 116 sets shooting mode tables A and B corresponding to shooting techniques A and B as shooting mode information.

  When shooting mode numbers 1 to 3 are used by shooting technique A, shooting mode setting unit 116 sets shooting mode table A including shooting mode numbers 1 to 3 as shooting mode information and stores it in shooting mode memory 107. . When shooting mode numbers 4 and 5 are used by shooting technique B, shooting mode setting unit 116 sets shooting mode table B including shooting mode numbers 4 and 5 as shooting mode information and stores it in shooting mode memory 107. Store. Note that the shooting mode information may be stored in another storage device such as the ROM 109 instead of the shooting mode memory 107.

  The shooting mode memory 107 is a non-volatile memory and stores shooting mode information. The shooting mode memory 107 stores a shooting mode having a high priority as shooting mode information. The shooting mode memory 107 may store a plurality of shooting modes associated with priorities as shooting mode information. For example, as shown in FIG. 3, the shooting mode memory 107 assigns shooting mode numbers in descending order of priority of shooting modes.

  The shooting mode information stored in the shooting mode memory 107 may include a shooting mode table including one or more shooting modes. For example, as shown in FIG. 4, the shooting mode memory 107 stores shooting mode tables A and B corresponding to shooting techniques A and B as shooting mode information.

  The RAM 108 is various data obtained by processing of each component of the radiation imaging apparatus 101 and various data input by the input device 504 (for example, radiation image data, offset correction data, gain correction data, defect correction data, etc.). Is temporarily stored. The ROM 109 stores programs and various data (such as gain image correction data and defect correction data). Since the gain correction data is hardly affected by temperature or the like and is relatively stable, the gain correction data is collected in advance and stored in a nonvolatile memory such as the ROM 109. After the power is turned on, the gain correction data is stored in the RAM 108 (high-speed memory for calculation). Expanded and used.

  Here, the offset correction data is image data captured in a state in which radiation is not irradiated in the same imaging mode as the radiation image data to be offset corrected. For example, when the subject (subject) 301 is imaged by the imaging mode number 1 in FIG. 3, the image data captured in the imaging mode 1 without irradiation with radiation is the offset correction data.

  The gain correction data is image data obtained by irradiating with radiation in the same imaging mode as the radiographic image data to be gain-corrected and without the subject (subject) 301. For example, when the subject (subject) 301 is imaged by the imaging mode number 1 in FIG. 3, the image data acquired by irradiating radiation in the imaging mode 1 without the subject (subject) 301 becomes the gain correction data. . The defect correction data is defect information such as position information of an element (defective element) that cannot detect radiation in the photoelectric conversion element 102.

  The shooting mode control unit 110 controls the drive control unit 105 based on the shooting mode information. The imaging mode selection unit 120 selects an imaging mode for imaging the subject 301 from a plurality of imaging modes. The shooting mode selection unit 120 selects at least one of the first shooting mode and the second shooting mode from a plurality of shooting modes. Further, the shooting mode selection unit 120 may select shooting modes (including a shooting mode table) in descending order of priority in accordance with shooting mode information stored in the shooting mode memory 107.

  By controlling the drive control unit 105, the first correction data acquisition unit 121 acquires offset correction data and gain correction data according to the imaging mode selected by the imaging mode selection unit 120 after the radiation imaging apparatus 101 is turned on. To do. For example, when the first imaging mode is selected by the imaging mode selection unit 120, the first correction data acquisition unit 121 sets the first image data captured in the first imaging mode after the radiation imaging apparatus is turned on. Obtained as offset correction data. The first correction data acquisition unit 121 acquires defect correction data of the photoelectric conversion element 102.

  The notification unit 122 obtains that the correction data has been acquired, and notifies the operator 601 through the communication unit 111 and the system control device 501 that the preparation for shooting in the shooting mode selected by the shooting mode selection unit 120 has been completed. Notify

  By controlling the drive control unit 105, the second correction data acquisition unit 123 acquires offset correction data and gain correction data according to the shooting mode selected by the shooting mode selection unit 120 after the notification by the notification unit 122. The second correction data acquisition unit 123 acquires defect correction data for the photoelectric conversion element 102. The communication unit 111 communicates with the system control device 501 and transmits and receives various information such as image data and commands.

  The image correction unit 112 performs offset correction and gain correction of the radiation image data stored in the RAM 108. The image correction unit 112 performs offset correction by subtracting the offset correction data from the radiation image data. Further, the image correction unit 112 performs gain correction by dividing the image data subjected to the offset correction by the gain correction data. In addition, the image correction unit 112 performs defect correction by complementing the pixel value of the defective pixel with the peripheral pixels based on the defect correction data of the photoelectric conversion element 102.

  The radiation generation control unit 505 controls radiation generation by the radiation generation apparatus 401 based on an imaging instruction from the operator 601. The imaging control unit 506 controls radiation imaging on the radiation imaging apparatus 101 based on an imaging instruction from the operator 601. The external storage unit 507 is configured by a hard disk or the like, and stores programs, various data, various information, and the like. A communication unit 508 communicates with the radiation imaging apparatus 101 and transmits and receives various types of information such as image data and commands.

  The arithmetic processing unit 512 controls the system control device 501 using programs and various data stored in the external storage unit 507 and the RAM 511. The RAM 511 temporarily stores various data and various information necessary for the processing of the system control apparatus 501. The display control unit 510 performs control related to display on the display device 502. The input control unit 509 controls the input device 504 such as switching the input display of the input device 504 according to the operation of the input device 504 by the operator 601.

  The input device 504 is an operation panel or the like operated by the operator 601, and inputs an instruction input by the operator 601 to the system control device 501. The radiation irradiation switch 503 is a button or the like operated by the operator 601. When the operator 601 presses the switch, an imaging instruction for starting and ending radiation imaging is given to the radiation generation control unit 505 and the imaging control unit. Enter in 506. The display device 502 displays various images and information based on the control by the display control unit 510.

  Next, the operation of each device will be described. FIG. 5 is a sequence diagram illustrating an example of the operation of the radiation imaging apparatus 101. In the present embodiment, the shooting mode setting unit 116 sets shooting mode information and stores it in the shooting mode memory 107. For example, as illustrated in FIG. 4, the shooting mode setting unit 116 includes a plurality of shooting modes (shooting modes) included in the shooting mode table A (first shooting mode) and the shooting mode table B (second shooting mode), respectively. Numbers 1 to 3 and shooting mode numbers 4 and 5) are set.

  In step S <b> 11, the operator 601 turns on the radiation imaging apparatus 101 to turn on the radiation imaging apparatus 101. In step S12, the shooting mode selection unit 120 selects the first shooting mode from the plurality of shooting modes stored in the shooting mode memory 107, and instructs the drive control unit 105 to prepare for shooting in the selected shooting mode. . The shooting mode selection unit 120 compares priorities of a plurality of shooting modes, and selects a shooting mode with a higher priority as the first shooting mode.

  For example, the shooting mode selection unit 120 selects the shooting mode table A (shooting mode with shooting mode numbers 1 to 3) having the highest priority as the first shooting mode, and drives and controls the preparation for shooting by the shooting mode table A. The unit 105 is instructed. Further, the shooting mode selection unit 120 may select the shooting mode with shooting mode number 1 having the highest priority as the first shooting mode, and instruct the drive control unit 105 to prepare for shooting with shooting mode number 1. .

  Preparation for photographing in step S12 includes acquisition of offset correction data. The first correction data acquisition unit 121 acquires, as first offset correction data, image data captured in a state in which radiation is not emitted in the first imaging mode selected by the imaging mode selection unit 120. The acquired first offset correction data is stored in the RAM 108. For example, the first correction data acquisition unit 121 acquires offset correction data for each of the shooting modes (shooting mode numbers 1 to 3) in the shooting mode table A and stores the offset correction data in the RAM 108.

  The first correction data acquisition unit 121 collects a plurality of offset correction data in the first shooting mode, and stores image data obtained by averaging these pixel values in the RAM 108 as first offset correction data. Also good. Random noise included in the image data is reduced by averaging the image data, and random noise in the radiation image data can be reduced by using the averaged image data for offset correction.

  The preparation for shooting in step S12 includes acquisition of gain correction data. The first correction data acquisition unit 121 uses the first imaging mode selected by the imaging mode selection unit 120 as a first gain for image data acquired by irradiating radiation in the absence of the subject (subject) 301. Obtained as correction data. The acquired first gain correction data is stored in the RAM 108. For example, the first correction data acquisition unit 121 acquires gain correction data for each of the shooting modes (shooting mode numbers 1 to 3) in the shooting mode table A and stores the gain correction data in the RAM 108.

  The gain correction data may be collected in advance and stored in the ROM 109. In this case, the first correction data acquisition unit 121 reads the first gain correction data from the ROM 109 and stores it in the RAM 108.

  In addition, the preparation for photographing in step S12 includes acquisition of defect correction data of the photoelectric conversion element (light receiving unit) 102. The defect correction data is collected in advance and stored in the ROM 109. The first correction data acquisition unit 121 reads defect correction data from the ROM 109 and stores it in the RAM 108.

  In general, since the RAM 108 has a higher access speed than the ROM 109, offset correction data, gain correction data, and defect correction data are stored in the RAM 108 and read from the RAM 108 in order to perform correction processing at high speed. When the first offset correction data, the second gain correction data, and the defect correction data are stored in the RAM 108, the preparation for shooting in the first shooting mode is completed.

  In step S13, the notification unit 122 notifies the operator 601 that the first offset correction data, the first gain correction data, and the defect correction data have been acquired via the communication unit 111 and the system control device 501. To do. The notification unit 122 notifies the operator 601 of the shooting mode information of the first shooting mode via the communication unit 111 and the system control device 501. In this way, the notification unit 122 notifies the operator 601 that the preparation for shooting in the first shooting mode has been completed.

  For example, the notification unit 122 notifies the operator 601 that the offset correction data, gain correction data, and defect correction data of the shooting modes (shooting mode numbers 1 to 3) in the shooting mode table A have been acquired, and shooting. The operator 601 is notified of the shooting mode information in the mode table A. As a result, the notification unit 122 notifies the operator 601 that the preparation for shooting in the shooting mode of the shooting mode table A has been completed. In response to the notification from the notification unit 122, the system control apparatus 501 enables shooting in the first shooting mode in which shooting preparation is completed.

  In step S <b> 14, the operator 601 operates the input device 504 to determine the imaging mode and presses the radiation irradiation switch 503. In step S <b> 15, the system control apparatus 501 transmits an imaging start (radiation irradiation start) command to the radiation imaging apparatus 101. In step S <b> 16, the radiation imaging apparatus 101 starts radiography of the subject 301.

  In step S <b> 17, when the operator 601 stops pressing the radiation irradiation switch 503, the system control apparatus 501 transmits an imaging end (radiation irradiation end) command to the radiation imaging apparatus 101. In step S18, the radiation imaging apparatus 101 ends the radiation imaging of the subject 301.

  In step S19, the shooting mode selection unit 120 selects the second shooting mode from the plurality of shooting modes stored in the shooting mode memory 107, and instructs the drive control unit 105 to prepare for shooting in the selected shooting mode. . The shooting mode selection unit 120 compares priorities of a plurality of shooting modes, and selects a shooting mode having a lower priority than the first shooting mode as the second shooting mode.

  For example, the shooting mode selection unit 120 selects the shooting mode table B (shooting mode with shooting mode numbers 4 and 5) having the second highest priority after the shooting mode table A as the second shooting mode. The drive control unit 105 is instructed to prepare for shooting.

  The preparation for photographing in step S19 includes acquisition of offset correction data. The second correction data acquisition unit 123 acquires, as second offset correction data, image data captured in a state in which radiation is not emitted in the second imaging mode selected by the imaging mode selection unit 120. The acquired second offset correction data is stored in the RAM 108. For example, the first correction data acquisition unit 123 acquires offset correction data for each of the shooting modes (shooting mode numbers 1 to 3) in the shooting mode table B and stores the offset correction data in the RAM 108.

  As described above, a plurality of offset correction data may be collected, and image data obtained by averaging these pixel values may be stored in the RAM 108 as second offset correction data.

  Also, the preparation for photographing in step S19 includes acquisition of gain correction data. The second correction data acquisition unit 123 obtains the second gain of image data obtained by irradiating radiation in the absence of the subject (subject) 301 in the second imaging mode selected by the imaging mode selection unit 120. Obtained as correction data. The acquired second gain correction data is stored in the RAM 108. For example, the first correction data acquisition unit 123 acquires gain correction data for each of the shooting modes (shooting mode numbers 4 and 5) in the shooting mode table B and stores the gain correction data in the RAM 108.

  The gain correction data may be collected in advance and stored in the ROM 109. In this case, the second correction data acquisition unit 123 reads the second gain correction data from the ROM 109 and stores it in the RAM 108.

  In addition, the preparation for photographing in step S19 includes acquisition of defect correction data of the photoelectric conversion element (light receiving unit) 102. Since the defect correction data is already stored in the RAM 108 in step S <b> 12, the second correction data acquisition unit 123 may read the defect correction data from the RAM 108. The second offset correction data, the second gain correction data, and the defect correction data are stored in the RAM 108, whereby the shooting preparation for the second shooting mode is completed.

  In step S20, the notification unit 122 notifies the operator 601 that the second offset correction data, the second gain correction data, and the defect correction data have been acquired via the communication unit 111 and the system control device 501. To do. The notification unit 122 notifies the operator 601 of the shooting mode information of the second shooting mode via the communication unit 111 and the system control device 501. In this way, the notification unit 122 notifies the operator 601 that the preparation for shooting in the second shooting mode has been completed.

  For example, the notification unit 122 notifies the operator 601 of the offset correction data, the gain correction data, and the defect correction data of the shooting modes (shooting mode numbers 4 and 5) of the shooting mode table B, and the shooting of the shooting mode table B. The mode information is notified to the operator 601. As a result, the notification unit 122 notifies the operator 601 that the preparation for shooting in the shooting mode of the shooting mode table B has been completed. Based on the notification from the notification unit 122, the system control apparatus 501 enables shooting in the second shooting mode in which shooting preparation is completed.

  After that, when there is no imaging start (radiation irradiation start), the imaging mode selection unit 120 selects an imaging mode from the plurality of imaging modes stored in the imaging mode memory 107 in descending order of priority, and the selected imaging is performed. The drive control unit 105 is sequentially instructed to prepare for shooting in the mode. The notification unit 122 transmits shooting mode information to the system control device 501 each time the shooting preparation in the shooting mode is sequentially completed, and notifies the operator 601 that the shooting preparation is completed.

  For example, the shooting mode selection unit 120 selects the shooting mode table C having the second highest priority after the shooting mode tables A and B, and instructs the drive control unit 105 to prepare for shooting using the shooting mode table C. The notification unit 122 notifies the operator 601 that the preparation for shooting by the shooting mode table C has been completed. In this way, the radiation imaging apparatus 101 sequentially completes preparations for imaging according to the priority using the time period excluding the time from the imaging start (radiation irradiation start) to the imaging end (radiation irradiation end). Every time shooting preparation is completed, the operator 601 is notified that shooting preparation has been completed.

  As a result, the radiation imaging apparatus 101 completes imaging preparations for all imaging modes (including the imaging mode table) stored in the imaging mode memory 107. For example, the radiation imaging apparatus 101 completes preparation for imaging of all imaging mode tables A to Z stored in the imaging mode memory 107. In this case, the radiation imaging apparatus 101 may sequentially complete imaging preparation for imaging modes not described in the imaging mode tables A to Z after completing imaging preparations for all the imaging mode tables A to Z.

  When the radiation imaging apparatus 101 completes preparations for imaging in all imaging modes, it transmits to the system control apparatus 501 that preparations for all imaging modes are completed, and notifies the operator 601 via the system control apparatus 501.

  Note that the priority order of the shooting modes (including the shooting mode table) may be set in advance. Based on the past use history of the radiation imaging system, the order of the imaging modes may be set in descending order of use frequency. Further, the order of imaging modes may be set in descending order of usage correlation based on the past usage history of the radiation imaging system. For example, when shooting is performed in the first shooting mode, the rank may be set with the shooting mode in which the frequency of use (degree of use correlation) is equal to or higher than a predetermined threshold as the second selection mode. In this case, a plurality of shooting modes having a use correlation degree equal to or higher than a predetermined threshold may be set as the shooting mode table.

  As described above, the shooting mode setting unit 116 may set the first shooting mode and the second shooting mode according to the use frequency and the use correlation of the plurality of shooting modes. Further, the shooting mode selection unit 120 may select the first shooting mode and the second shooting mode according to the use frequency and the use correlation degree of the plurality of shooting modes.

  According to the present embodiment, it is not necessary to wait for completion of shooting preparation in all shooting modes by performing shooting preparation with priority given to a predetermined shooting mode and sequentially allowing shooting from the shooting mode in which shooting preparation is completed. Therefore, it is possible to reduce the waiting time until photographing becomes possible.

  Although the embodiments according to the present invention have been described, the present invention is not limited to these embodiments, and can be changed and modified within the scope of the claims. For example, the present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus execute the program. It can also be realized by a process of reading and executing. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

  In the present embodiment, the second correction data acquisition unit 123 acquires the second offset correction data after imaging the subject (subject) 301 in the first imaging mode (step S19). However, if it is after the notification of the notification unit 122 (step S13), preparation for shooting in the second shooting mode may be performed before starting shooting. That is, preparation for photographing in the second photographing mode may be performed using a time period excluding time from the start of photographing (starting of radiation irradiation) to the end of photographing (end of radiation irradiation).

  Further, the shooting mode selection unit 120 may select the first shooting mode and the second shooting mode in accordance with the input order of the shooting modes input from the input unit. FIG. 6 is a schematic diagram illustrating an example of a schematic configuration of a radiation imaging system that selects an imaging mode according to an input order from an input unit. Note that the description of the same configuration, function, and operation as in the above embodiment is omitted, and differences from the present embodiment are mainly described.

  In FIG. 6, compared with FIG. 2, the imaging mode memory 107 and the imaging mode setting unit 116 are removed from the radiation imaging apparatus 101, and an imaging mode input unit 513 is added to the system control apparatus 501.

  The shooting mode input unit 513 controls the display device 502 and the input device 504 to display information for inputting a shooting technique on the display device 502. The input device 504 inputs a shooting technique. The shooting mode input unit 513 holds a plurality of shooting modes used according to the shooting technique, and determines a shooting mode based on the shooting technique input from the input device 504. Imaging mode information regarding the determined imaging mode is transmitted to the radiation imaging apparatus 101 via the communication unit 508.

  FIG. 7 is a sequence diagram illustrating an example of the operation of the radiation imaging apparatus 101 that selects an imaging mode according to the input order from the input unit. In step S <b> 21, the operator 601 turns on the radiation imaging apparatus 101 to turn on the radiation imaging apparatus 101. In step S <b> 22, the radiation imaging apparatus 101 notifies the system control apparatus 501 that the radiation imaging apparatus 101 has been powered on.

  In step S <b> 23, upon receiving a power-on notification from the radiation imaging apparatus 101, the imaging mode input unit 513 displays information for inputting an imaging technique on the display device 502. In step S24, the operator 601 browses the display on the display device 502, selects a shooting technique, and the input device 504 inputs the shooting technique. In step S <b> 25, the imaging mode input unit 513 determines an imaging mode based on the input imaging technique, and transmits imaging mode information to the radiation imaging apparatus 101.

  In step S26, the shooting mode selection unit 120 selects the first shooting mode according to the shooting mode information input from the shooting mode input unit 513, and prepares for shooting in the selected shooting mode. To instruct. For example, the shooting mode selection unit 120 selects the first shooting mode and the second shooting mode in the input order of the shooting modes. Here, the imaging mode selection unit 120 selects, as the first imaging mode, the imaging mode (including the imaging mode table) input earliest after the radiation imaging apparatus 101 is turned on.

  In step S27, the notification unit 122 notifies the operator 601 that the first offset correction data, the first gain correction data, and the defect correction data have been acquired via the communication unit 111 and the system control device 501. To do. In this way, the notification unit 122 notifies the operator 601 that the preparation for shooting in the first shooting mode has been completed. In response to the notification from the notification unit 122, the system control apparatus 501 enables shooting in the first shooting mode in which shooting preparation is completed.

  In step S28, the operator 601 presses the radiation irradiation switch 503. In step S <b> 29, the system control apparatus 501 transmits an imaging start (radiation irradiation start) command to the radiation imaging apparatus 101. In step S <b> 30, the radiation imaging apparatus 101 starts radiography of the subject 301.

  In step S <b> 31, when the operator 601 stops pressing the radiation irradiation switch 503, the system control apparatus 501 transmits an imaging end (radiation irradiation end) command to the radiation imaging apparatus 101. In step S <b> 32, the radiation imaging apparatus 101 ends the radiation imaging of the subject 301.

  In step S33, the shooting mode selection unit 120 selects the second shooting mode according to the shooting mode information input from the shooting mode input unit 513, and prepares for shooting in the selected shooting mode. To instruct. For example, the shooting mode selection unit 120 selects the shooting mode (including the shooting mode table) input next to the first shooting mode as the second shooting mode in the input order of the shooting modes.

  In step S33, when the next imaging technique is not input from the input device 504 to the imaging mode input unit 513, the imaging mode input unit 513 selects a plurality of imaging modes to be used according to the imaging technique. Sequentially transmitted to the apparatus 101 The shooting mode input unit 513 may hold a plurality of shooting modes associated with priorities and sequentially transmit the shooting modes in descending order of priority. The shooting mode selection unit 120 selects the shooting mode (including the shooting mode table) input next to the first shooting mode as the second shooting mode in the input order of the shooting modes.

  In FIG. 6, the radiation imaging apparatus 101 may include an imaging mode memory 107 as in the above embodiment. In step S33, when the next shooting technique is not input from the input device 504 to the shooting mode input unit 513, the shooting mode selection unit 120 sets the shooting modes (second shooting modes) in the shooting mode memory in descending order of priority. 107 may be selected.

  In step S34, the notification unit 122 notifies the operator 601 that the second offset correction data, the second gain correction data, and the defect correction data have been acquired via the communication unit 111 and the system control device 501. To do. In this way, the notification unit 122 notifies the operator 601 that the preparation for shooting in the second shooting mode has been completed.

  Thereafter, when there is no imaging start (radiation irradiation start), the imaging mode selection unit 120 selects an imaging mode according to the imaging mode input from the imaging mode input unit 513 in descending order of priority, and the imaging mode imaging is performed. Preparation is sequentially instructed to the drive control unit 105. The notification unit 122 notifies the operator 601 that the preparation for photographing has been completed each time the preparation for photographing in the photographing mode is sequentially completed.

  As a result, the radiation imaging apparatus 101 completes imaging preparations for all imaging modes (including the imaging mode table) held by the imaging mode input unit 513. When the radiation imaging apparatus 101 completes preparations for imaging in all imaging modes, it transmits to the system control apparatus 501 that preparations for all imaging modes are completed, and notifies the operator 601 via the system control apparatus 501.

  Note that, after the notification of the notification unit 122 (step S27), preparation for shooting in the second shooting mode may be performed before starting shooting. That is, preparation for photographing in the second photographing mode may be performed using a time period excluding time from the start of photographing (starting of radiation irradiation) to the end of photographing (end of radiation irradiation).

  As described above, according to the present embodiment, according to the input order of the shooting modes input from the input unit, the shooting preparation is performed by giving priority to the predetermined shooting mode, and the shooting is sequentially permitted from the shooting mode in which the shooting preparation is completed. can do. As a result, it is not necessary to wait for completion of shooting preparations in all shooting modes, so that the waiting time until shooting is possible can be reduced.

101 Radiation Imaging Device 102 Photoelectric Conversion Element 103 Drive Unit 104 A / D Conversion Unit 105 Drive Control Unit 106 Arithmetic Processing Unit 107 Imaging Mode Memory 108 RAM
109 ROM
DESCRIPTION OF SYMBOLS 110 Imaging mode control part 111,508 Communication part 112 Image correction part 116 Imaging mode setting part 120 Imaging mode selection part 121 1st correction data acquisition part 122 Notification part 123 2nd correction data acquisition part 201 Top plate 401 Radiation generator 402 Radiation Control Device 501 System Control Device 502 Display Device 503 Radiation Irradiation Switch 504 Input Device 505 Radiation Generation Control Unit 506 Imaging Control Unit 507 External Storage Unit 509 Input Control Unit 510 Display Control Unit 511 RAM
512 arithmetic processing unit 513 shooting mode input unit

Claims (11)

A shooting mode selection means for selecting at least one of a first shooting mode and a second shooting mode from a plurality of shooting modes;
A first correction data acquisition means for acquiring the pre-Symbol image data captured by the first imaging mode as the first offset correction data,
A second correction data acquisition means for acquiring the pre-Symbol image data taken by the second imaging mode as the second offset correction data,
Notification means for notifying that the first or the second offset correction data has been acquired,
When the first imaging mode is selected by the imaging mode selection unit, the first correction data acquisition unit acquires the first offset correction data after powering on the radiation imaging apparatus,
The radiation imaging apparatus , wherein the second correction data acquisition unit acquires the second offset correction data after the notification unit notifies that the first offset correction data has been acquired . Before power-up of the radiographic apparatus, in advance, the radiation imaging apparatus according to claim 1, characterized in that more first photographing mode is selected in the shooting mode selecting means. The shooting mode selection unit compares priorities of the plurality of shooting modes, selects a shooting mode with a higher priority as the first shooting mode, and sets a shooting mode with a lower priority as the second shooting mode. the radiographic apparatus according to claim 1 or 2, characterized in that selection. The first correction data acquisition means acquires, as first gain correction data, image data obtained by irradiating with radiation in a state where there is no subject in the first mode,
The second correction data acquisition unit, according to claim 1 to 3, characterized in that acquires image data captured by irradiating radiation at the second state in which no object using mode as the second gain correction data The radiation imaging apparatus according to any one of the above. The first correction data obtaining means and the second correction data acquisition unit, according to claim 1 or any one of the 4 and acquires the defect information of the light receiving means for receiving the radiation Radiography equipment. The radiographic imaging according to any one of claims 1 to 5 , further comprising imaging mode setting means for setting a plurality of imaging modes respectively included in the first imaging mode and the second imaging mode. apparatus. The photographing mode selection means, characterized in that after power-on of the radiation imaging device in accordance with the input order of the shooting mode that has been input from the input means, selects the first photography mode and the second imaging mode of The radiation imaging apparatus according to any one of claims 1 to 6 . The imaging mode selection unit selects the first imaging mode and the second imaging mode according to at least one of a usage frequency and a usage correlation of the plurality of imaging modes. The radiation imaging apparatus according to any one of 6 . The said 2nd correction data acquisition means acquires the said 2nd offset correction data after the imaging | photography of the to-be-photographed object by the said 1st imaging | photography mode, The any one of Claim 1 thru | or 8 characterized by the above-mentioned. Radiography equipment. Selecting at least one of a first shooting mode and a second shooting mode from a plurality of shooting modes;
When the first imaging mode is selected , after turning on the radiation imaging apparatus, obtaining image data captured in the first imaging mode as first offset correction data;
Notifying that the first offset correction data has been acquired;
And a step of acquiring image data captured in the second imaging mode as second offset correction data after notifying that the first offset correction data has been acquired. . The program for functioning a computer as each means of the radiography apparatus of any one of Claim 1 thru | or 9 .

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