JP2021010560A - Radiography control apparatus and method of controlling the same, radiography system, and program - Google Patents

Abstract

To provide a mechanism capable of performing suitable radiation stop control when radiography is performed using a radiation detection device that includes a plurality of sensor arrays arranged side by side.SOLUTION: In a radiography control apparatus 200 for controlling radiation imaging communicatable with a radiation detection device 100 comprising a sensor array group 1201 that includes a plurality of sensor arrays 110 for detecting radiation R arranged side by side, an exposure dose measuring region for measuring an exposure dose to stop the projection of radiation R is determined from among a plurality of radiation detection regions preset in the sensor array group 1201 on the basis of input information of the imaging site of a subject H that undergoes radiography.SELECTED DRAWING: Figure 12

Description

The present invention relates to a radiography control device for controlling radiography using radiation, a control method thereof, a radiography system configured including the radiography control device, and a program for causing a computer to execute the control method. It is a thing.

Currently, in the medical field, the subject is irradiated with radiation, the radiation transmitted through the subject is detected by a sensor array to acquire a digital image signal, and then various image processing is performed. A radiation detector capable of acquiring a radiographic image for diagnosis is widely used. Further, in recent years, a radiation imaging system capable of so-called one-shot long imaging, which can capture a wider range of a subject with one irradiation of radiation, has been proposed. As a conventional technique related to this one-shot long imaging, for example, Patent Document 1 describes a radiation imaging system including a radiation detection device in which a plurality of sensor arrays for detecting radiation are arranged side by side in a predetermined direction.

Japanese Unexamined Patent Publication No. 2016-198122

Furthermore, in recent years, automatic exposure control (Automatic Exposure Control) has been performed by detecting the integrated irradiation dose of radiation transmitted through the subject and stopping the irradiation of radiation by the radiation source when the detected integrated irradiation dose reaches an appropriate amount. : AEC) is also being studied.

In this regard, for example, it is considered to apply the above-mentioned AEC function to a radiation imaging system including a radiation detection device in which a plurality of sensor arrays are arranged side by side in a predetermined direction, which is described in Patent Document 1 relating to one-shot long imaging. In this case, since the imaging area covers a wide area and the radiation transmittance differs depending on the internal structure of the subject, etc., depending on the setting of the irradiation dose measurement area for measuring the radiation dose, radiation stop control based on AEC Can not be done properly.

The present invention has been made in view of such a problem, and provides a mechanism capable of performing appropriate radiation stop control when performing radiation imaging using a radiation detection device in which a plurality of sensor arrays are arranged side by side. With the goal.

The radiography control device of the present invention is a radiography control device that is configured to be communicable with a radiation detection device including a sensor array group in which a plurality of sensor arrays for detecting radiation are arranged side by side, and controls radiography using the radiation. Therefore, the radiological imaging is performed from the input means for inputting the information of the imaging region of the subject to be radiographed and the plurality of radiological detection regions set in the sensor array group based on the information of the imaging region. In order to stop the irradiation of the radiation, there is a determination means for determining an irradiation dose measuring region for measuring the irradiation dose of the radiation.
The present invention also includes a radiography system including the above-mentioned radiography control device, a control method of the above-mentioned radiography control device, and a program for causing a computer to execute the control method.

According to the present invention, it is possible to perform appropriate radiation stop control when performing radiography using a radiation detection device in which a plurality of sensor arrays are arranged side by side.

It is a figure which shows the embodiment of this invention and shows an example of the schematic structure of the radiography system. It is a figure which shows an example of the schematic structure of the sensor array, the drive part and the reading part shown in FIG. It is a figure which shows an example of the internal structure of the unit of the reading part shown in FIG. It is a figure which shows an example of the internal structure of the processing part shown in FIG. It is a figure which shows an example of the internal structure of the radiography control apparatus shown in FIG. It is a timing chart which shows an example of the operation of the radiography system shown in FIG. FIG. 5 is a diagram showing an example of AEC setting information stored in the storage unit of the radiography control device shown in FIG. 5 in the radiography imaging system shown in FIG. It is a flowchart which shows the 1st example of the processing procedure in the control method of the radiography control apparatus shown in FIG. It is a figure which shows the embodiment of this invention, and shows an example of the positional relationship between the radiation image which concerns on the imaging part of the subject and the reference area (irradiation dose measurement area) at the time of actually performing the radiation imaging. It is a flowchart which shows the 2nd example of the processing procedure in the control method of the radiography control apparatus shown in FIG. It is a figure for demonstrating the processing example of step S204 of FIG. It is a figure which shows an example of the basic structure of the radiography system which concerns on embodiment of this invention. FIG. 5 is a diagram showing an example of AEC setting information stored in the storage unit of the radiography control device shown in FIG. 5 in the radiography imaging system shown in FIG. 12. It is a flowchart which shows an example of the processing procedure in the control method of the radiography control apparatus shown in FIG. It is a figure for demonstrating the processing example of step S301 of FIG.

Hereinafter, embodiments (embodiments) for carrying out the present invention will be described with reference to the drawings. In the embodiment of the present invention described below, the radiation includes α-rays, β-rays, γ-rays, which are beams produced by particles (including photons) emitted by radiation decay, and more than the same degree. It also includes beams having energy, such as X-rays, particle beams, and cosmic rays.

FIG. 1 is a diagram showing an embodiment of the present invention and showing an example of a schematic configuration of a radiography system 10. As shown in FIG. 1, the radiography system 10 includes a radiation detection device 100, a radiography control device (console) 200, an input device 210, a display device 220, a radiation source control device 300, an exposure switch 310, and a radiation source. It is configured to have 320.

The radiation detection device 100 includes a sensor array 110, a drive unit 120, a read unit 130, a processing unit 140, a control unit 150, and a voltage supply unit 160. The sensor array 110 is a component that detects the radiation R (including the radiation R that has passed through the subject H) emitted from the radiation source 320, and is a sensor that detects the incident radiation R (hereinafter, referred to as “sensor S”). (Described) are arranged in a matrix. The drive unit 120 is a component unit that drives a plurality of sensors S in row units. The reading unit 130 is a component that reads, for example, an electric signal (sensor signal) from the sensor S driven by the driving unit 120 among the sensors S in each row in the sensor array 110. The processing unit 140 is, for example, a component unit that processes the sensor signal read by the reading unit 130. The control unit 150 is a component unit that synchronously controls each component unit of the radiation detection device 100 by using a reference signal such as a clock signal. The voltage supply unit 160 is a component unit that supplies a power supply voltage for appropriately operating each component unit to each component unit of the radiation detection device 100.

In the embodiment of the present invention, a radiation detection device 100 in which a plurality of sensor arrays 110 are arranged side by side in a predetermined direction (for example, in the vertical direction of the subject H in the radiation imaging system 10 shown in FIG. 1) is assumed. In FIG. 1, only one sensor array 110 is illustrated for the purpose of simplifying the following description of FIGS. 2 to 11. Further, in FIG. 1, the radiation incident surface of the sensor array 110 is shown parallel to the paper surface for the purpose of clearly showing each component of the radiation detection device 100, but in reality, the sensor array 110 The radiation incident surface is arranged so as to face the radiation source 320.

The radiography control device (console) 200 is a device that is configured to be communicable with the radiation detection device 100 and controls radiography using radiation R. The radiography control device 200 generates radiographic image data based on a sensor signal from the radiological detection device 100, and additionally performs necessary image processing to display the radiation on the display device 220 (display). A radiographic image based on image data is displayed. The radiography control device 200 may be, for example, a personal computer in which a program or software for realizing each operation described in the present specification is stored, but is an arithmetic unit including an integrated circuit (for example, ASIC, FPGA, etc.). It may be.

The input device 210 relates to, for example, imaging information (information on an imaging site in subject H (subject such as a patient), personal information on subject H, and irradiation dose of target radiation R, based on user's operation input. It is a device that inputs various information including reference threshold information and other information necessary for radiography to the radiography control device 200. Here, when the radiography information is input from the input device 210, the radiography control device 200 controls, for example, the radiation detection device 100 and the radiation source control device 300 based on the radiography information, and also by radiography. The obtained radiographic image data is managed.

The display device 220 is a device that displays various information, various images, and the like based on the control of the radiography control device 200.

The radiation source control device 300 is a device that controls the drive of the radiation source 320. Specifically, when the radiation source control device 300 is pressed by the user while receiving an irradiation permission signal indicating that irradiation of radiation R is permitted from, for example, the radiation imaging control device 200. , The radiation source 320 is started to be irradiated with the radiation R. Further, when the radiation source control device 300 receives, for example, an irradiation stop signal indicating that the irradiation of the radiation R is stopped from the radiography control device 200, the radiation source control device 300 stops the irradiation of the radiation R to the radiation source 320.

The radiation source 320 irradiates and stops the radiation R based on the control of the radiation source control device 300. Specifically, the radiation source 320 irradiates the subject H with radiation. Then, the radiation R emitted from the radiation source 320 passes through the subject H, enters the sensor array 110 of the radiation detection device 100, and is detected by each sensor S of the sensor array 110.

The radiography system 10 is not limited to the configuration shown in FIG. 1, and a part of the configuration shown in FIG. 1 may be changed or deleted depending on the purpose or the like, and other components may be added. May be done. Further, a part of the functions of a certain component shown in FIG. 1 may be configured to be possessed by the other component, or some components may be integrated. For example, in FIG. 1, a case where the processing unit 140 and the radiography control device 200 are configured independently is illustrated, but these may be realized as a single unit.

Further, the communication means for performing communication between the radiation detection device 100 and the radiation imaging control device 200, communication between the radiation imaging control device 200 and the radiation source control device 300, etc. is realized by wire such as LAN. It may be realized by radio such as Wi-Fi.

FIG. 2 is a diagram showing an example of a schematic configuration of the sensor array 110, the drive unit 120, and the read unit 130 shown in FIG.

In the sensor array 110, a plurality of sensors S are arranged in a matrix. Specifically, in FIG. 2, sensors S11 to S33 arranged in 3 rows × 3 columns (hereinafter, these are simply referred to as “sensor S” when not particularly distinguished) are configured in the sensor array 110. ing. At this time, with i and j as integers 1 to 3, the sensor Sij indicates that it is located in the i-th row and the j-th column, and for example, the sensor S11 is located in the first row and the first column. Shown, the sensor S23 indicates that it is located in the second row and the third column. In the example shown in FIG. 2, the sensors S11 to S33 having 3 rows and 3 columns are illustrated for the sake of ease of explanation and due to the space on the paper, but in reality, the number is larger than this number, for example, 17. In the example of the inch sensor panel, the sensor S is composed of about 2800 rows × about 2800 columns.

As shown in FIG. 2, each sensor S includes, for example, a detection element D for detecting radiation R and a transistor T for connecting the detection element D and the column signal line LC. Regarding the code of the column signal line LC, for the sake of distinction in the figure, those corresponding to the first column to the third column are designated as LC1 to LC3, respectively. However, in the following, when these are not particularly distinguished, simply "column signal" is used. Line LC "is described. When the sensor S has a configuration in which the radiation R is converted into light and the light is photoelectrically converted (so-called indirect conversion type), a scintillator that converts the radiation R into light may be arranged on the sensor array 110. In this case, a photoelectric conversion element such as a PIN sensor or a MIS sensor may be used for the detection element D, and a thin film transistor or the like may be used for the transistor T. In another example, the sensor S may have a configuration that directly converts the radiation R into an electric signal (so-called direct conversion type).

The drive unit 120 drives the sensor S in units of rows by controlling the transistors T of each sensor S using the control lines VG1 to VG3 arranged for each row. Specifically, for example, an activation signal is supplied to each sensor S in the first row via the control line VG1 to drive each sensor S in the first row. As a result, for example, the sensor signals of the sensors S11, S12 and S13 are read out by the reading unit 130 via the column signal lines LC1, LC2 and LC3, respectively.

As shown in FIG. 2, the reading unit 130 includes a unit 131, a multiplexer 132, and an output unit 133 corresponding to each row of the sensor array 110. The unit 131, for example, amplifies the sensor signal from the corresponding sensor S and then samples it. The multiplexer 132 transfers the sensor signals sampled by the unit 131 to the output unit 133 in order for each column. The output unit 133 includes, for example, a buffer circuit, an analog-to-digital converter (ADC), and the like, and outputs each sensor signal as a digital signal to the processing unit 140.

FIG. 3 is a diagram showing an example of the internal configuration of the unit 131 of the reading unit 130 shown in FIG. As shown in FIG. 3, the unit 131 includes, for example, a signal amplification unit A1, a noise removal unit LPF, a first sampling unit USH1, and a second sampling unit USH2.

As shown in FIG. 3, the signal amplification unit A1 includes a differential amplifier A11, an input capacitance CIN, feedback capacitances CFB1 and CFB2, and switch elements SW10 to SW12. The input capacitance CIN is arranged between the inverting input terminal of the differential amplifier A11 (the input terminal indicated by “−” in the figure) and the column signal line LC. The non-inverting input terminal (input terminal indicated by "+" in the figure) of the differential amplifier A11 is fixed to the reference voltage VREF. The switch element SW10 is arranged in the first feedback path between the inverting input terminal and the output terminal of the differential amplifier A11. The switch element SW11 and the feedback capacitance CFB1 are connected in series and arranged in a second feedback path which is a path parallel to the first feedback path. Further, the switch element SW12 and the feedback capacitance CFB2 are connected in series and arranged in a third feedback path which is a path parallel to the first and second feedback paths. By controlling the switch elements SW11 and SW12, it is possible to change the signal amplification factor of the signal amplification unit A1. When the switch element SW10 is turned on, the signal amplification unit A1 is reset (initialized). When the switch element SW11 and / or SW12 is turned ON while the switch element SW10 is OFF, the signal amplification unit A1 amplifies the sensor signal at a signal amplification factor corresponding to the state of the switch elements SW11 and SW12.

The noise removing unit LPF is a low-pass filter for removing a high-frequency noise component from the signal from the signal amplification unit A1, and a resistance element or the like is used for the noise removing unit LPF.

The first and second sampling units USH1 and USH2 are sampling circuits for performing correlated double sampling (CDS). Specifically, the first sampling unit USH1 includes a sampling switch SWSH1 and a sampling capacitance CSH1, and samples a signal (so-called N signal) from the signal amplification unit A1 reset by the switch element SW10. The second sampling unit USH2 includes a sampling switch SWSH2 and a sampling capacitance CSH2, and samples a signal (so-called S signal) amplified by the signal amplification unit A1. Then, the multiplexer 132 of FIG. 2 transfers these N signals and S signals to the output unit 133, respectively, and in the output unit 133 of FIG. 2, the difference between these N signals and the S signal is analog-to-digital converted as a signal component ( AD conversion).

FIG. 4 is a diagram showing an example of the internal configuration of the processing unit 140 shown in FIG. As shown in FIG. 4, the processing unit 140 includes a memory ME, a first processing unit 410, and a second processing unit 420. The details will be described later with reference to FIG. 6, but the radiation detection device 100 includes a read operation mode and a storage operation / AEC mode as operation modes, and the processing unit 140 receives a digital signal from the output unit 133 in these operation modes. Is stored in the memory ME.

Specifically, in the read operation mode, sensor signals (digital signals) for forming a radiographic image are read from sensors S11 to S33 by the read unit 130 and stored in the memory ME. Then, the first processing unit 410 reads the sensor signal from the memory ME, performs signal processing (for example, correction processing) on the sensor signal, and outputs a group of the sensor signals to which the signal processing has been performed to the radiography control device 200. To do.

Further, in the accumulation operation / AEC mode, the reference threshold value is set so that the irradiation dose of the radiation R is within an appropriate range after the irradiation of the radiation R is started and before the sensor signal is read from each sensor S by the read operation mode. When it reaches (exceeds), the irradiation of radiation R is stopped. In this mode, a digital signal is read from a part of the sensors S11 to S33 as a monitor signal for performing AEC, and is temporarily stored in the memory ME (note that the other sensors S are irradiated). Charges are accumulated according to the radiation R). In the following, for the sake of simplification of description, the monitor signal read out for performing AEC will be simply referred to as a “monitor signal”.

The second processing unit 420 reads a monitor signal from the memory ME, and performs processing for performing the AEC according to the present embodiment on the monitor signal. As shown in FIG. 4, the second processing unit 420 includes, for example, an input unit 421, a setting unit 422, and a determination unit 423. The input unit 421 receives AEC setting information from the radiography control device 200 (for example, information on a reference region (irradiation dose measurement region) for measuring the irradiation dose of radiation R, and information on a reference threshold value related to the irradiation dose in the irradiation dose measurement region. And the information of the determination method) is received, and this is set in the setting unit 422. In the present embodiment, the configuration in which the radiography control device 200 inputs to the input unit 421 has been described, but the input method is not limited to this example. For example, the parameters defined by the radiation source control device 300 may be input. The setting unit 422 reflects the set AEC setting information in the determination unit 423. Whether or not the determination unit 423 stops the irradiation of the radiation R from the monitor signal value (that is, the estimated value of the signal value of the sensor S in the irradiation dose measurement region) based on the AEC setting information set by the setting unit 422. To judge. Specifically, the monitor signal value is cumulatively added (integrated) in the determination unit 423 (or in another calculation means). Then, the determination unit 423 stops the irradiation of the radiation R when the cumulative addition value reaches the reference threshold value based on the information of the irradiation dose measurement area included in the AEC setting information and the information of the determination method. The signal for this is output to the radiography control device 200.

FIG. 5 is a diagram showing an example of the internal configuration of the radiography control device 200 shown in FIG. As shown in FIG. 5, the radiography control device 200 includes a radiation irradiation control unit 201, an image generation unit 202, a display control unit 203, an input unit 204, a storage unit 205, and a determination unit 206.

The radiation irradiation control unit 201 is a component unit that controls irradiation of radiation R by the radiation source 320 via the radiation source control device 300. For example, when the radiation irradiation control unit 201 receives a signal for stopping the irradiation of the radiation R from the determination unit 423 of the processing unit 140, the radiation source control unit 300 instructs the radiation source control device 300 to stop the irradiation of the radiation R. In the present embodiment, the radiation irradiation control unit 201 is exemplified as a part of the radiography control device 200, but may exist independently of the radiography control device 200.

The image generation unit 202 receives the sensor signal that has been signal-processed by the first processing unit 410, and generates radiographic image data based on the sensor signal.

The display control unit 203 controls to display various information and various images on the display device 220. For example, the display control unit 203 causes the display device 220 to display a radiation image based on the radiation image data generated by the image generation unit 202, and causes the display device 220 to display the information input by the input unit 204.

The input unit 204 can be used from the input device 210 for information on the imaging portion of the subject H to be subjected to radiographic imaging, personal information on the subject H (subject information), information on a reference threshold related to the irradiation dose of radiation R, and other radiographic imaging. It is a component that inputs various information such as shooting information including necessary information. In the present embodiment, the input unit 204 exemplifies the input of information from the input device 210, but for example, an external device (for example, a shooting information input device (RIS terminal device)) and a bar code reader (not shown). It may receive input from a reader (such as a reader).

The storage unit 205 stores the AEC setting information associated with the shooting information input by the input unit 204.

The determination unit 206 acquires the AEC setting information associated with the shooting information from the storage unit 205 based on the shooting information input by the input unit 204, corrects the AEC setting information as necessary, and then obtains the AEC setting information. It is determined and transmitted to the input unit 421 of the second processing unit 420.

FIG. 6 is a timing chart showing an example of the operation of the radiography system 10 shown in FIG. In FIG. 6, with the horizontal axis as the time axis, from the top, the state of the exposure switch 310, the radiation source drive signal (signal level) for driving the radiation source 320, the radiation amount (intensity) from the radiation source 320, and so on. The operation mode, the state of the power supply voltage, and each signal (signal level) are shown.

Regarding the state of the exposure switch 310, a low level (L level) indicates that the exposure switch 310 is not pressed, and a high level (H level) indicates that the exposure switch 310 is pressed. When the radiation source drive signal reaches the H level, the radiation source 320 is driven and radiation R is emitted from the radiation source 320. The radiation amount indicates the intensity (irradiation amount per unit time) of the radiation R actually emitted by the radiation source 320 according to the H level of the radiation source driving signal. The operation mode is the operation mode of the radiation detection device 100, and in addition to the above-mentioned read operation mode and storage operation / AEC mode, it is possible to start radiography after supplying a power supply voltage to the radiation detection device 100. Includes the preparatory operation mode until the state becomes.

The signal RST is a control signal of the switch element SW10 of the signal amplification unit A1 in the unit 131, and the signal amplification unit A1 is reset when the signal RST reaches the H level. The signal CDS1 is a control signal of the switch element SWSH1 of the first sampling unit USH1 in the unit 131, and when the signal CDS1 reaches the H level, sampling is executed by the first sampling unit USH1. The signal CDS2 is a control signal of the switch element SWSH2 of the second sampling unit USH2, and when the signal CDS2 reaches the H level, sampling is executed by the second sampling unit USH2. The signals VG1 to VG3 correspond to the signals of the control lines VG1 to VG3 shown in FIG. 2, and the same reference numerals as those of the control lines VG1 to VG3 are used for easy understanding. For example, in FIG. 6, each sensor S in the second row is targeted for monitoring the monitor signal by the second processing unit 420, and when the signal VG2 reaches the H level, each sensor S in the second row is driven. Will be done. In addition, the signal CLK is a clock signal used for AD conversion in the ADC of the output unit 133, and the signal ADCOUT indicates a digital signal obtained by the AD conversion.

In FIG. 6, in the preparatory operation mode from the time t50 to the time t52, the signals VG1 to VG3 are activated in order while supplying the signal RST of the H level pulse at a predetermined cycle, and the sensors S in the first to third rows are activated. To reset in order. Here, the mode in which the sensors S in the first to third rows are reset once is shown, but in reality, the sensors S are reset a plurality of times (for example, about 10 seconds). Although not shown here, when all the sensors S are sufficiently reset, the user is notified that the irradiation of the radiation R can be started, and the user is notified based on the notification. Press the exposure switch 310. The time when the user presses the exposure switch 310 is set to time t51.

At time t52 in FIG. 6, in response to the completion of the reset of the sensor S in the third row, the operation mode shifts to the accumulation operation / AEC mode, and the radiation source drive signal is set to the H level. In response to this, the signals CDS1 and CDS2 are alternately activated, and the signal VG2 is activated in the meantime, and the above-mentioned monitor signal is read from the sensors S (S21 to S23) in the second row. More specifically, the monitor signal is AD-converted by the output unit 133, stored in the memory ME, and then processed by the second processing unit 420 to perform AEC. In the example shown in FIG. 6, in the storage operation / AEC mode, the sensors S (S11 to S13 and S31 to S33) in the first row and the third row accumulate charges according to the radiation.

At time t53 in FIG. 6, the radiation amount of radiation R from the radiation source 320 increases in response to the radiation source driving signal reaching the H level at time t52. Therefore, in this example, the signal value of the monitor signal read out between the times t52 and t53 is substantially zero.

At time t54 in FIG. 6, the determination unit 423 determines that the irradiation dose of the radiation R has reached the reference threshold value, and sets the radiation source drive signal to the L level. Specifically, the value obtained by cumulatively adding the estimated values of the signal values of the sensor S as the reference region based on the result of the processing by the second processing unit 420 described above reached the reference threshold value. (Accordingly), the radiation source drive signal is set to L level. Along with this, the radiation amount becomes L level, and the irradiation of radiation ends (stops).

At time t55 in FIG. 6, the operation mode shifts to the read operation mode, and the sensor signals are read out in order from all the sensors S. Specifically, the signals CDS1 and CDS2 are alternately activated while supplying the signal RST of the H level pulse at a predetermined cycle, and the signals VG1 to VG3 are activated in order during that time, whereby the first row to the third row are activated. The sensor signals are read out in order from the sensor S in the row. As described above, the sensor signal read in this way is stored in the memory ME, and after being subjected to predetermined signal processing by the first processing unit 410, it is output to the radiography control device 200. At this time, with respect to the sensor signal of the sensor S in the second row, since most of the signal components are lost by reading out the monitor signal for AEC described above (time t52 to t54), the sensor signal of the adjacent sensor S It should be corrected or complemented based on.

FIG. 7 is a diagram showing an example of AEC setting information stored in the storage unit 205 of the radiography control device 200 shown in FIG. 5 in the radiography imaging system 10 shown in FIG. Specifically, FIG. 7A shows the sensor array 110 shown in FIGS. 1 and 2, and FIG. 7B shows the AEC setting information stored in the storage unit 205.

In FIG. 7A, the regions GR01 to GR05 are radiation detection regions (hereinafter referred to as radiation detection regions) in which targets to be read as monitor signals among the sensors S11 to S33 are grouped when the operation mode shown in FIG. 6 is the storage operation / AEC mode. It is described as "reference area" if necessary). For example, the reference regions GR01 to GR05 include a radiation detection region including the sensor S11 shown in FIG. 2, a radiation detection region including the sensor S13, a radiation detection region including the sensor S22, a radiation detection region including the sensor S31, and a sensor S33, respectively. It is a radiation detection area including. Here, the region including one sensor S is used as the reference region, but the present embodiment is not limited to this, and the region including a plurality of sensors S may be used as the reference region, and is not necessarily limited to this. It is not necessary to include the adjacent sensors S in the reference area.

FIG. 7B shows the AEC setting information stored in the storage unit 205. In FIG. 7B, a reference area and a determination method are defined according to the imaged portion of the subject H. The reference region shown in FIG. 7B is irradiated with radiation R selected from the reference regions GR01 to GR05, which are radiation detection regions shown in FIG. 7A, according to the imaging portion of the subject H. This is an irradiation dose measurement area for measuring the irradiation dose of radiation H in order to stop. Further, in the determination method shown in FIG. 7B, AND stops the irradiation of radiation H when all the irradiation doses in the reference region (irradiation dose measurement region) shown in FIG. 7B reach the reference threshold value. Indicates that the judgment is made. Further, in the determination method shown in FIG. 7 (b), OR is the radiation H when the irradiation dose reaches the reference threshold even in one of the reference regions (irradiation dose measurement regions) shown in FIG. 7 (b). Indicates that the irradiation stop is determined.

For example, when the "chest" is input from the input unit 204 as the information of the imaging portion of the subject H, the determination unit 206 selects the reference areas GR01, GR02, and GR03 from the reference areas GR01 to GR05, which are the radiation detection areas. Determined as the irradiation dose measurement area. That is, the sensor S included in each of the reference areas GR01, GR02, and GR03 is the target for monitoring the monitor signal. Further, since the determination method in the case of "chest" in FIG. 7B is AND in the determination unit 423, all the irradiation doses of the reference regions GR01, GR02, and GR03 reach the reference threshold value as compared with the reference threshold value. If this is the case, the stop of irradiation of radiation H is determined.

FIG. 8 is a flowchart showing a first example of a processing procedure in the control method of the radiography control device 200 shown in FIG. Further, FIG. 9 shows an embodiment of the present invention, and is a diagram showing an example of the positional relationship between the radiation image related to the imaged portion of the subject H and the reference area (irradiation dose measurement area) when the radiation image is actually taken. Is. Specifically, FIG. 9A shows a radiation image when the imaging site of the subject H is the “chest” and a plurality of reference regions (irradiation dose measurement regions) GR01, GR02 and GR03 set in the sensor array 110. An example of the positional relationship with is shown. Further, in FIG. 9B, the positional relationship between the radiation image when the imaged portion of the subject H is the “knee” and the reference areas (irradiation dose measurement areas) GR02, GR03 and GR05 set in the sensor array 110. An example is shown. Hereinafter, the flowchart of FIG. 8 will be described with reference to FIG. 9 as necessary.

First, in step S101 of FIG. 8, for example, the determination unit 206 acquires the length between the set reference regions (irradiation dose measurement regions). Specifically, when the imaging region of the subject H shown in FIG. 9A is the “chest”, for example, the determination unit 206 may be used between the reference regions (between GR01 and GR02, between GR01 and GR03, and GR02. And GR03) get the length. At this time, the acquired length may be the actual length (cm, inch, etc.) connecting the center points of each reference region, or the value (pixel) using the pixel value on the radiographic image may be used. Good.

Subsequently, in step S102, for example, the determination unit 206 determines whether or not any one of the lengths between the reference regions acquired in step S101 exceeds a predetermined value.

As a result of the determination in step S102, if the length between the reference areas acquired in step S101 exceeds a predetermined value at any one (S102 / YES), the process proceeds to step S103. When proceeding to step S103, the length between the reference regions exceeds a predetermined value (that is, the reference region covers a wide area), and there is a possibility that a large difference in the transmittance of the imaging region in each reference region occurs. is there. Therefore, in step S103, for example, the determination unit 206 specifies one or more reference regions. Here, for example, a reference region near the center point of the sensor array 110 is specified. In this case, in the examples shown in FIGS. 9A and 9B, the reference region GR03 closest to the center point of the sensor array 110 is specified. The specific process in step S103 is not limited to this aspect, and for example, a reference region far from the center point of the sensor array 110 may be specified, and as shown in FIG. 9, the imaging region is concerned. The reference area may be specified by the positional relationship between the radiographic image taken by radiography and each reference area. In FIG. 9, it is shown that the portion closer to white in the radiographic image has a lower transmittance, and the portion closer to black has a higher transmittance. For example, when the imaging site shown in FIG. 9A is the “chest”, the reference region GR03 can be estimated to be the portion having the lowest transmittance, so that the reference region GR03 can also be specified. Further, for example, when the imaging region shown in FIG. 9A is the “knee”, the reference region GR05 can be estimated to be the portion having the lowest transmittance, so that the reference region GR05 can also be specified. Here, an example of specifying the reference region estimated to have the lowest transmittance has been described, but since the sensor S in the portion having the high transmittance may be saturated, the transmittance is high or intermediate. A reference area may be specified.

Subsequently, in step S104, for example, the determination unit 206 determines the irradiation dose measurement region only in the reference region specified in step S103.

When the process of step S104 is completed, or when it is determined in step S102 that the lengths between the reference regions are all within the predetermined values (S102 / NO), the process proceeds to step S105. Proceeding to step S105, for example, the determination unit 206 acquires the AEC setting information of the reference area related to the irradiation dose measurement area (when the processing of step S104 is performed, the AEC setting information of the limited reference area). Then, this is input to the input unit 421 of the second processing unit 420.

When the process of step S105 is completed, the process of the flowchart of FIG. 8 is completed. By processing the flowchart of FIG. 8, the determination unit 423 of the second processing unit 420 determines whether or not to stop the irradiation of the radiation R by using the AEC setting information input to the input unit 421. Become.

In the processing of the flowchart of FIG. 8, when it is determined that the irradiation dose measurement area for measuring the irradiation dose of the radiation R in order to stop the irradiation of the radiation R in radiography is determined to be a wide range, the target area is limited. (S104), AEC is performed in the limited area. As a result, even when the irradiation dose measurement area covers a wide area and there is a large difference in the transmittance of the imaging site in each irradiation dose measurement area, appropriate radiation stop control can be performed. As a result, it becomes possible to acquire a radiographic image suitable for diagnosis.

FIG. 10 is a flowchart showing a second example of the processing procedure in the control method of the radiography control device 200 shown in FIG.

First, in step S201 of FIG. 10, for example, the determination unit 206 acquires the length between each reference region (each irradiation dose measurement region) by the same processing as in step S101 of FIG.

Subsequently, in step S202, for example, the determination unit 206 determines whether or not the length between the reference regions acquired in step S201 exceeds a predetermined value at any one and the determination method is OR. to decide.

As a result of the determination in step S202, if the length between the reference areas acquired in step S201 exceeds a predetermined value in any one of them and the determination method is OR (S202 / YES), the step. Proceed to S203. Proceeding to step S203, for example, the determination unit 206 acquires the length of the center point of each reference region from the center points of all the sensors S.

When proceeding to step S203, the length between the reference regions exceeds a predetermined value (that is, the reference regions extend over a wide area), and the irradiation dose of the radiation R in each reference region may vary. Further, in the case of proceeding to this step S203, since the determination method is OR, the irradiation of radiation R is performed when the irradiation dose that has reached the reference threshold (exceeds the reference threshold) is detected in any one of the reference regions. It will stop. Therefore, in step S204, for example, the determination unit 206 corrects the reference threshold value of each reference region (each irradiation dose measurement region). Specifically, in step S204, for example, the determination unit 206 corrects the reference threshold value of each reference region (each irradiation dose measurement region) based on the length acquired in step S203.

FIG. 11 is a diagram for explaining a processing example of step S204 of FIG. FIG. 11 shows a plurality of reference regions GR01 to GR05 set in the sensor array 110. Further, FIG. 11 also shows the center point 1101 of the reference area GR01, the center point 1102 of the reference area GR02, the center point 1103 of the reference area GR03, the center point 1104 of the reference area GR04, and the center point 1105 of the reference area GR05. There is. Further, in the example shown in FIG. 11, it is assumed that the center of the irradiation field where the radiation source 320 irradiates the radiation R is the center point of the sensor array 110 and the center point 1103 of the reference region GR03. Then, in the example shown in FIG. 11, a predetermined correction coefficient is stored in the storage unit 205 as a percentage (%) based on the length from the center point 1103, which is the center of the irradiation field where the radiation source 320 irradiates the radiation R. Take the form of Specifically, in the example shown in FIG. 11, the correction coefficient for correcting the reference threshold value of the reference region is determined depending on which percentage (%) of the center points 1101 to 1105 of the reference regions GR01 to GR05 belong to. Will be done. More specifically, in the example shown in FIG. 11, the correction coefficient for correcting the reference threshold value of the reference region GR01 is 110%, and the correction coefficient for correcting the reference threshold value of the reference region GR02 to is 90%.

Here, the description of FIG. 10 is returned to again.
When the process of step S204 of FIG. 10 is completed, or when it is determined in step S202 that the lengths between the reference regions are all within the predetermined values or the determination method is not OR (AND). (S202 / NO), the process proceeds to step S205. Proceeding to step S205, for example, the determination unit 206 acquires the AEC setting information of the reference region related to the irradiation dose measurement region (information including the corrected reference threshold value when the processing of step S204 is performed). , This is input to the input unit 421 of the second processing unit 420.

When the process of step S205 is completed, the process of the flowchart of FIG. 10 is completed. By the processing of the flowchart of FIG. 10, the determination unit 423 of the second processing unit 420 uses the AEC setting information (including the information in which the reference threshold has been corrected) input to the input unit 421 to irradiate the radiation R. It will be determined whether or not to stop.

In the processing of the flowchart of FIG. 10, when it is determined that the irradiation dose measurement area for measuring the irradiation dose of the radiation R is wide in order to stop the irradiation of the radiation R in the radiography, the radiation source 320 generates the radiation R. The reference threshold of the irradiation dose measurement area is corrected according to the length from the center of the irradiation field to be irradiated (S204), and AEC is performed using the corrected reference threshold. As a result, even when the irradiation dose measurement area covers a wide range and the irradiation dose of the radiation R in each irradiation dose measurement area varies, appropriate radiation stop control can be performed. As a result, it becomes possible to acquire a radiographic image suitable for diagnosis.

FIG. 12 is a diagram showing an example of a basic configuration of the radiography system 10 according to the embodiment of the present invention. In FIG. 12, the same reference numerals are given to the configurations similar to those shown in FIG. 1, and detailed description thereof will be omitted.

The radiation detection device 100 shown in FIG. 12 has a sensor array group 1201 in which a plurality of sensor arrays 110 for detecting radiation R are arranged side by side in a predetermined direction (for example, in the vertical direction of the subject H in the radiation imaging system 10 shown in FIG. 12). It is configured as a device to be equipped. Specifically, in the example shown in FIG. 12, the sensor array group 1201 is composed of a plurality (three) sensor arrays 110-1 to 110-3. Although FIG. 12 shows the radiation incident surface of the sensor arrays 110-1 to 110-3 parallel to the paper surface for the purpose of ensuring consistency with FIG. 1, the sensor array 110 is actually shown. The radiation incident surfaces of -1 to 110-3 are arranged so as to face the radiation source 320. Further, in the example shown in FIG. 12, only a plurality of sensor arrays 110-1 to 110-3 are illustrated inside the radiation detection device 100 due to the space on the paper surface, but in reality, a plurality of sensors are shown. A drive unit 120, a read unit 130, a processing unit 140, a control unit 150, and a voltage supply unit 160 shown in FIG. 1 are also configured for each sensor array 110 in the arrays 110-1 to 110-3. Further, as shown in FIG. 4, the internal configuration of the processing unit 140 in this case includes the memory ME, the first processing unit 410, the input unit 421, the setting unit 422, and the determination unit 423, and includes the second processing unit 420. It is configured to prepare.

The radiation photographing system 10 shown in FIG. 12 is a system capable of taking a one-shot long image of the subject H. Therefore, the radiation source 320 shown in FIG. 12 is configured so that the plurality of sensor arrays 110-1 to 110-3 constituting the sensor array group 1201 can be simultaneously irradiated with radiation H.

The radiography control device 200 shown in FIG. 12 is configured to be communicable with the radiation detection device 100 and controls radiography using radiation R, and its internal configuration is as shown in FIG. .. That is, the radiography control device 200 shown in FIG. 12 includes a radiation irradiation control unit 201, an image generation unit 202, a display control unit 203, an input unit 204, a storage unit 205, and a determination unit 206 shown in FIG. ing.

FIG. 13 is a diagram showing an example of AEC setting information stored in the storage unit 205 of the radiography control device 200 shown in FIG. 5 in the radiography imaging system 10 shown in FIG. Specifically, FIG. 13A shows the sensor array group 1201 shown in FIG. 12, and FIG. 13B shows the AEC setting information stored in the storage unit 205.

As shown in FIG. 13A, the plurality of sensor arrays 110-1, 110-2 and 110-3 in the sensor array group 1201 have a plurality of reference regions (radiation detection regions) GR11 to GR15 and GR21 to 1, respectively. GR25 and GR31 to GR35 are set. In the present embodiment, each of the plurality of reference regions GR11 to GR15, GR21 to GR25, and GR31 to GR35 are regions corresponding to the plurality of reference regions GR01 to GR05 shown in FIG. 7A. That is, each of the plurality of reference areas GR11 to GR15, GR21 to GR25, and GR31 to GR35 targets to be read as a monitor signal among the sensors S11 to S33 when the operation mode shown in FIG. 6 is the accumulation operation / AEC mode. Grouped radiation detection areas.

FIG. 13B shows the AEC setting information stored in the storage unit 205. In FIG. 13B, a reference area and a determination method are defined according to the imaged portion of the subject H. The reference region shown in FIG. 13B is irradiated with radiation R selected from the reference regions GR11 to GR35, which are radiation detection regions shown in FIG. 13A, according to the imaging portion of the subject H. This is an irradiation dose measurement area for measuring the irradiation dose of radiation H in order to stop. Further, in the determination method shown in FIG. 13B, AND stops the irradiation of radiation H when all the irradiation doses in the reference region (irradiation dose measurement region) shown in FIG. 13B reach the reference threshold value. Indicates that the judgment is made. Further, in the determination method shown in FIG. 13 (b), the OR is the radiation H when the irradiation dose reaches the reference threshold value even in one of the reference regions (irradiation dose measurement regions) shown in FIG. 13 (b). Indicates that the irradiation stop is determined.

For example, when "whole spine" is input from the input unit 204 as the information of the imaging site of the subject H, the determination unit 206 uses the reference areas GR13, GR23, and GR33 from the reference areas GR11 to GR35, which are radiation detection areas. Is determined as the irradiation dose measurement area. That is, the sensor S included in each of the reference areas GR13, GR23, and GR33 is the target for monitoring the monitor signal. Further, since the determination method in the case of "whole spine" in FIG. 13B is AND in the determination unit 423, the radiation H is obtained when all the irradiation doses of the reference regions GR13, GR23 and GR33 reach the reference threshold value. Judgment of stop of irradiation. Then, when the radiation irradiation control unit 201 receives the signal for stopping the irradiation of the radiation R from the determination unit 423, the radiation source control unit 300 instructs the radiation source control device 300 to stop the irradiation of the radiation R.

Further, for example, when the "total length of the lower limbs" is input from the input unit 204 as the information of the imaging portion of the subject H, the determination unit 206 uses the reference areas GR23 and GR33 from the reference areas GR11 to GR35, which are radiation detection areas. Is determined as the irradiation dose measurement area. That is, the sensor S included in each of the reference areas GR23 and GR33 is the target for monitoring the monitor signal. Further, since the determination method in the case of "total length of lower limbs" in FIG. 13B is OR, the determination unit 423 emits radiation when the irradiation dose reaches the reference threshold value even in one of the reference regions GR23 and GR33. It is determined that the irradiation of H is stopped. Then, when the radiation irradiation control unit 201 receives the signal for stopping the irradiation of the radiation R from the determination unit 423, the radiation source control unit 300 instructs the radiation source control device 300 to stop the irradiation of the radiation R.

Further, in the radiography system 10 shown in FIG. 12, the sensor array group 1201 is configured by superimposing and arranging a part of the regions of the plurality of sensor arrays 110-1 to 110-3. Specifically, the sensor array group 1201 shown in FIG. 12 is arranged at a position farther than the first sensor array with respect to the radiation source 320 and the sensor arrays 110-1 and 110-3 corresponding to the first sensor array. It is configured to include a sensor array 110-2 corresponding to the second sensor array. Then, in the present embodiment, as shown in FIG. 13B, the determination unit 206 has the sensor arrays 110-1 and 110-3 (first sensor array) in the sensor array 110-2 (second sensor array). A process is performed to exclude a part of the regions GR41 and GR42 that overlap with the sensor array) from the irradiation dose measurement region. Specifically, the determination unit 206 excludes the portion of the reference regions GR21, GR22, GR24 and GR25 set in the sensor array 110-2 that overlaps with the regions GR41 and GR42 from the reference region (irradiation dose measurement region). To be determined.

Then, in the radiography system 10 shown in FIG. 12, the image generation unit 202 first obtains a plurality of sensor signals based on the sensor signals read from the respective sensor arrays 110 of the plurality of sensor arrays 110-1 to 110-3. Generate radiographic image data. Then, the image generation unit 202 combines the generated plurality of radiation image data into one to generate long radiation image data related to the imaged portion of the subject H. Then, the display control unit 203 causes the display device 220 to display a long radiation image related to the imaged portion of the subject H based on the long radiation image data generated by the image generation unit 202.

FIG. 14 is a flowchart showing an example of a processing procedure in the control method of the radiography control device 200 shown in FIG.

First, in step S301 of FIG. 14, for example, the determination unit 206 acquires the length (distance) between the radiation source 320 and each reference region (each irradiation dose measurement region). For example, in the present embodiment, the distance between the radiation source 320 and each sensor array 110-1 to 110-3, and each sensor in relation to the imaging site, with reference to the center point of each sensor array 110-1 to 110-3. The distance between the center point of the arrays 110-1 to 110-3 and the center point of each reference area (each irradiation dose measurement area) is stored in advance in the storage unit 205. For example, the determination unit 206 is stored in the storage unit 205. Using the stored distance information, the length (distance) between the radiation source 320 and each reference region is calculated and acquired.

FIG. 15 is a diagram for explaining a processing example of step S301 of FIG. FIG. 15 shows an example of the positional relationship between the sensor arrays 110-1 to 110-3 constituting the sensor array group 1201 and the radiation source 320. In FIG. 15, the radiation incident surfaces of the sensor arrays 110-1 to 110-3 are shown parallel to the paper surface for the purpose of ensuring consistency with FIGS. 12 and the like, but in reality, the sensor array is shown. The radiation incident surfaces of 110-1 to 110-3 are arranged so as to face the radiation source 320.

As shown in FIG. 15, the length (distance) between the radiation source 320 and the center point (center point of the sensor array 110-2) 1502 of the sensor array group 1201 is 200 cm, and the center point 1502 of the sensor array 110-2. When the length (distance) between the sensor array 110-1 and the center point 1501 (for example, the center point of the sensor array 110-3 is also the same) is 40 cm, the distance between the radiation source 320 and the reference region GR13 is set. The length (distance) can be calculated to be about 204 cm. In addition, the radiation source control device 300 may input the measured distance to the radiography control device 200, or the distance measured by an external device (not shown) may be used.

Here, the description of FIG. 14 is returned to again.
When the process of step S301 of FIG. 14 is completed, the process proceeds to step S302. Proceeding to step S302, for example, in the determination unit 206, the length between the radiation source 320 and the reference region (irradiation dose measurement region) acquired in step S301 exceeds a predetermined value in any one of them, and , It is determined whether or not the determination method is OR.

As a result of the determination in step S302, if any one of the lengths acquired in step S301 exceeds the predetermined value and the determination method is OR (S302 / YES), the process proceeds to step S303. Proceeding to step S303, for example, the determination unit 206 corrects the reference threshold value of the reference region (irradiation dose measurement region) according to the length acquired in step S301, and the reference threshold value of the reference region (irradiation dose measurement region). To determine. In general, the amount of radiation reached is inversely proportional to the square of the distance. Therefore, in the example shown in FIG. 15, it can be calculated that the amount of radiation reaching the reference region GR23 is about 4% larger than that of the reference region GR13. , A correction is made to increase the reference threshold of the reference region GR23 by 4%.

When the process of step S303 is completed, or in step S302, the length between the radiation source 320 and the reference area (irradiation dose measurement area) is within a predetermined value, or the determination method is not OR (AND). If it is determined that there is (S302 / NO), the process proceeds to step S304. Proceeding to step S304, for example, the determination unit 206 acquires the AEC setting information of the reference region related to the irradiation dose measurement region (information including the corrected reference threshold value when the processing of step S303 is performed). , This is input to the input unit 421 of the second processing unit 420.

When the process of step S304 is completed, the process of the flowchart of FIG. 14 is completed. By the processing of the flowchart of FIG. 14, the determination unit 423 of the second processing unit 420 uses the AEC setting information (including the information in which the reference threshold has been corrected) input to the input unit 421 to irradiate the radiation R. It will be determined whether or not to stop.

In the processing of the flowchart of FIG. 14, even when it is determined that the reference area that can be set as the irradiation dose measurement area extends over a plurality of sensor arrays 110-1 to 110-3 and the irradiation dose measurement area extends over a wide range. The reference threshold value of the irradiation dose measurement area is corrected according to the length (distance) between the radiation source 320 and the irradiation dose measurement area (S303), and AEC is performed using the corrected reference threshold value. As a result, even when the irradiation dose measurement area covers a wide range and the irradiation dose of the radiation R in each irradiation dose measurement area varies, appropriate radiation stop control can be performed. As a result, it becomes possible to acquire a radiographic image suitable for diagnosis.

(Other embodiments)
The present invention supplies a program that realizes one or more functions of the above-described embodiment to a system or device via a network or storage medium, and one or more processors in the computer of the system or device reads and executes the program. It can also be realized by the processing to be performed. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.
This program and a computer-readable storage medium that stores the program are included in the present invention.

It should be noted that the above-described embodiments of the present invention merely show examples of embodiment in carrying out the present invention, and the technical scope of the present invention should not be construed in a limited manner by these. Is. That is, the present invention can be implemented in various forms without departing from the technical idea or its main features.

10: Radiation imaging system, 100: Radiation detection device, 110-1 to 110-3: Sensor array, 200: Radiation imaging control device (console), 210: Input device, 220: Display device, 300: Radiation source control device, 310: Exposure switch, 320: Radiation source, 1201: Sensor array group, H: Subject, R: Radiation

Claims (12)

A radiation imaging control device that is configured to be communicable with a radiation detection device including a sensor array group in which a plurality of sensor arrays for detecting radiation are arranged side by side, and controls radiography using the radiation.
An input means for inputting information on the imaging portion of the subject to be radiographed, and
Irradiation dose measurement that measures the irradiation dose of the radiation in order to stop the irradiation of the radiation in the radiography from a plurality of radiation detection regions set in the sensor array group based on the information of the imaging site. Determining means to determine the area and
A radiography control device characterized by having. The radiography control device according to claim 1, wherein a plurality of the radiation detection regions are set in each of the plurality of sensor arrays in the sensor array group. The determination means is a reference threshold value of the irradiation dose measurement region according to the length between the radiation source capable of simultaneously irradiating the sensor array group with the radiation and the irradiation dose measurement region, and the irradiation of the radiation. The radiography control device according to claim 1 or 2, wherein a reference threshold value to be compared with the irradiation dose in the irradiation dose measurement region is further determined when determining whether or not to stop. Control to stop the irradiation of the radiation when it is determined that the irradiation dose of at least one of the irradiation dose measuring regions reaches the reference threshold value of the irradiation dose measuring region and the irradiation of the radiation is stopped. The radiography control device according to claim 3, further comprising means. When the sensor array group is configured by superimposing and arranging a part of the regions in the plurality of sensor arrays, the determination means excludes the part of the region from the irradiation dose measurement region. The radiography control device according to any one of claims 1 to 4. The first sensor array and the first sensor array with respect to a radiation source capable of simultaneously irradiating the sensor array group with the radiation on the plurality of sensor arrays in which the partial regions are overlapped and arranged. When a second sensor array located farther away is included, the determining means captures the portion of the second sensor array that overlaps the first sensor array. The radiography control device according to claim 5, wherein the radiography control device is excluded from the irradiation dose measurement region. A method 1 to claim 1, further comprising a generating means for generating a long radiographic image by combining a plurality of radiographic images generated based on sensor signals obtained by the plurality of sensor arrays by the radiography. 6. The radiography control device according to any one of 6. A radiography system including a radiation detection device that detects radiation and a radiography control device that is configured to be communicable with the radiation detection device and controls radiography using the radiation.
The radiation detection device has a sensor array group in which a plurality of sensor arrays for detecting the radiation are arranged side by side.
The radiography control device is
An input means for inputting information on the imaging portion of the subject to be radiographed, and
Irradiation dose measurement that measures the irradiation dose of the radiation in order to stop the irradiation of the radiation in the radiography from a plurality of radiation detection regions set in the sensor array group based on the information of the imaging site. Determining means to determine the area and
A radiography system characterized by having. The radiation detection device further includes a determination means for determining whether or not to stop the irradiation of the radiation by using the irradiation dose in the irradiation dose measurement region determined by the determination means. Item 8. The radiography system according to item 8. The radiography system according to claim 8 or 9, wherein the sensor array group further includes a radiation source capable of simultaneously irradiating the radiation. It is a control method of a radiography control device which is configured to be communicable with a radiation detection device including a sensor array group in which a plurality of sensor arrays for detecting radiation are arranged side by side and controls radiography using the radiation.
An input step for inputting information on the imaging part of the subject to be radiographed, and
Irradiation dose measurement that measures the irradiation dose of the radiation in order to stop the irradiation of the radiation in the radiography from a plurality of radiation detection regions set in the sensor array group based on the information of the imaging site. The decision step to determine the area and
A control method for a radiography control device, which comprises. A computer is configured to be able to communicate with a radiation detection device including a sensor array group in which a plurality of sensor arrays for detecting radiation are arranged side by side, and to cause a computer to execute a control method of a radiation imaging control device that controls radiography using the radiation. It ’s a program
An input step for inputting information on the imaging part of the subject to be radiographed, and
Irradiation dose measurement that measures the irradiation dose of the radiation in order to stop the irradiation of the radiation in the radiography from a plurality of radiation detection regions set in the sensor array group based on the information of the imaging site. The decision step to determine the area and
A program that lets a computer run.