JP2020022587A - Photographing control device and radiographic image photographing system - Google Patents

Abstract

To allow for easy switching of a radiographic image photographing system from one dedicated for still image photographing to one corresponding to moving image photographing.SOLUTION: An photographing control device 3 is connected to at least one of a radiation generator 1 and a radiographic image photographing apparatus 2 and can control the connected apparatuses. The photographing control device 3 comprises: at least a first control unit 3a which performs processing necessary for still image photographing; and a second control unit 3b which is configured to be attachable to/detachable from the first control unit 3a and performs processing necessary for moving image photographing. When the second control unit 3b is fitted to the first control unit 3a, the photographing control device 3 performs control in such a manner that the connected apparatuses can perform both still image photographing and moving image photographing. When the second control unit 3b is removed from the first control unit 3a, the photographing control device 3 performs control in such a manner that connected apparatuses perform still image photographing.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an imaging control device and a radiographic imaging system.

Radiation images widely used for diagnosis include still images and moving images.
Irrespective of whether a still image or a moving image is to be captured, a radiation generating device that generates radiation, an image capturing device that generates a radiation image corresponding to the received radiation, and a control device that controls these components are provided. Although a system is required, it is known that the control performed by each device differs between the case of performing still image shooting and the case of performing moving image shooting.

  In the case of still image capturing, radiation irradiation and image generation are performed only once per image capturing. For this reason, in still image shooting, control as described in Patent Document 1, for example, is performed. Specifically, when the image processing apparatus that generates an image completes its preparation, it sets the busy signal input to the X-ray controller to low. Then, when the exposure switch is pressed in this state, the X-ray control device sets the exposure signal input to the image processing device to high, and transmits the activation signal to the X-ray generation device. While the exposure signal is high, the image processing device accumulates electric charges in each image sensor, and the X-ray generator generates X-rays. When the exposure switch is released and the exposure signal goes low, the image processing device ends the accumulation of the charges and reads the image.

On the other hand, since a moving image is composed of a plurality of frames, in the case of moving image capturing, control for linking the operation of the radiation generating apparatus and the operation of the radiation image capturing apparatus is required. For this reason, in moving image shooting, control as described in, for example, Patent Documents 2 and 3 is performed.
The X-ray imaging apparatus described in Patent Literature 2 is of a continuous irradiation type in which radiation is continuously irradiated during an imaging period, and a flat panel X-ray detector accumulates electric charges based on a set frame rate. And reading of the image are alternately repeated.
The radiation imaging apparatus described in Patent Document 3 is of a pulse irradiation type that irradiates radiation intermittently, and the control unit keeps the imaging unit in an accumulation state while the radiation pulse from the radiation generation device is rising. Then, the imaging unit is caused to read an image during a period from when the radiation pulse has passed to when the radiation pulse has risen again.

JP-A-7-153590 JP 2002-301053 A JP 2006-122667A

As described above, since the control to be performed is different between still image shooting and moving image shooting, a shooting system dedicated to still image shooting and shooting corresponding to moving image shooting (both still image shooting and moving image shooting can be performed) Each system required a dedicated controller.
For this reason, in the case of introducing moving image shooting in a facility using a shooting system dedicated to still images, a large-scale remodeling of the control device (for example, replacing the board of the control device, etc.) is required, It takes time and effort.
Further, if the modification is difficult, it is necessary to newly introduce a control device corresponding to the moving image shooting, which also increases the cost.

  On the other hand, the number of diagnoses using moving images is on the rise, and it is expected that the number of users who want to introduce a shooting system compatible with moving image shooting will increase in the future, and that introduction will become easier. However, a shooting system that supports video shooting is still more expensive than a shooting system dedicated to still images. However, the introduction cost is high due to the extra function of the moving image shooting function.

  The present invention has been made in view of the above problems, and has as its object to easily switch a radiographic image capturing system from one dedicated to still image capturing to one compatible with moving image capturing.

In order to solve the above problems, the present invention provides:
A radiation control device capable of connecting to at least one of a radiation generating device capable of generating radiation and a radiation image capturing device capable of generating a radiation image corresponding to received radiation, and controlling the connected device. So,
A first control unit that performs at least processing required for still image shooting,
A second control unit configured to be detachably attached to the first control unit and performing a process required for moving image shooting,
If the second control unit is attached to the first control unit, the connected device is controlled to be able to perform both still image shooting and moving image shooting,
When the second control unit is removed from the first control unit, the connected device is controlled to perform still image shooting.

  ADVANTAGE OF THE INVENTION According to this invention, a radiographic imaging system can be easily switched from the thing only for still image imaging to the thing corresponding to moving image imaging.

FIG. 1 is a block diagram illustrating a schematic configuration of a radiation image capturing system according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating a specific configuration of an imaging control device included in the radiation image imaging system of FIG. 1. FIG. 3 is a block diagram illustrating a state in which a moving image photographing function is omitted from the photographing control device in FIG. 2. FIG. 3 is a schematic diagram illustrating an example of an opening provided in a housing of the imaging control device in FIG. 2. FIG. 3 is a front view of a shielding member attached to a housing of the imaging control device in FIG. 2. FIG. 6 is a front view showing an opening when the shielding member of FIG. 5 is attached. FIG. 7 is a sectional view taken along line VII-VII of FIG. 6. It is a front view showing an example of how to attach a shielding member to an opening. It is sectional drawing which shows an example of how to attach a shielding member to an opening part.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the scope of the present invention is not limited to the following embodiments and illustrated examples.

[Radiation imaging system]
First, the configuration of the radiographic image capturing system (hereinafter, image capturing system 100) according to the present embodiment will be described. FIG. 1 is a block diagram illustrating a schematic configuration of the imaging system 100.

As shown in FIG. 1, for example, an imaging system 100 according to the present embodiment includes a radiation generation device (hereinafter, generation device 1), a radiation image imaging device (hereinafter, imaging device 2), and an imaging control device (hereinafter, control device). The apparatus includes a device 3) and a console 4.
Further, the imaging system 100 can be connected to a radiology information system (RIS), an image storage communication system (Picture Archiving and Communication System: PACS) and the like (not shown).

The generator 1 includes a generator 11, an exposure switch 12, and a radiation source (tube) 13, and is configured to generate radiation (such as X-rays).
The generating device 1 is configured to be able to communicate with the imaging device 2, the control device 3, and the console 4 by wire or wirelessly.
In addition, the generator 1 may be a fixed type installed in a photography room or a mobile type provided with wheels.

The generator 11 is configured to be able to apply a voltage to the radiation source 13 in accordance with preset radiation exposure conditions (tube voltage, tube current, irradiation time (mAs value), etc.).
The exposure switch 12 has a two-stage push button. Note that the exposure switch 12 may be connected to the control device 3 described later.
The radiation source 13 is configured to, when a voltage is applied from the generator 11, generate radiation (X-rays or the like) at a dose corresponding to the applied voltage.

When the generator 1 configured as described above detects that the first stage of the exposure switch 12 has been pressed, it has a function of transmitting a signal to that effect to the controller 3.
Further, the generator 1 detects that the second stage of the exposure switch 12 has been pressed, and outputs the radiation based on the reception of the preparation completion signal indicating that the preparation for imaging has been completed from the controller 3. and it has a function of generating.
When the still image capturing is set in the capturing system 100, the generator 1 irradiates the radiation with a predetermined time width only once in response to one pressing of the exposure switch 12.
On the other hand, when moving image capturing is set in the capturing system 100, the generator 1 emits (pulse-shaped) radiation having a shorter time width than the above-described predetermined time in a predetermined cycle in response to one press of the exposure switch 12. Irradiate several times repeatedly.
When moving image shooting is set, the radiation may be continuously applied for a longer period of time (during the shooting period) than the predetermined time.

The imaging device 2 includes a radiation detection unit, a scanning unit, a reading unit, and the like (not shown), and is configured to be able to generate a radiation image according to received radiation.
Further, the imaging device 2 is configured to be able to communicate with the generation device 1, the control device 3, and the console 4.
Although FIG. 1 illustrates a portable imaging device 2 having a panel shape as an example, a fixed imaging device installed in an imaging room may be a portable imaging device having another shape. You may.

The radiation detection unit is a radiation detection element that directly or indirectly generates an amount of electric charge according to the radiation dose by receiving radiation, and a radiation detection element and a wiring provided between each radiation detection element and the wiring. Any known pixel may be used as long as it has a substrate in which a plurality of pixels each having a switch element that can be switched to an ON state where current can be supplied or an OFF state where current cannot be supplied are arranged in a two-dimensional plurality. be able to.
That is, the imaging device 2 may be a so-called indirect type that includes a scintillator and detects light emitted when the scintillator receives radiation, or a so-called direct type that directly detects radiation without passing through a scintillator or the like. May be used.

The scanning unit is configured to be able to control the state of each switch element.
The reading unit reads out the amount of electric charge stored in each of the plurality of radiation detection elements as a signal value of each pixel constituting the radiation image, and can generate the radiation image in the form of data based on each signal value. What is necessary is just to be comprised, and a conventionally well-known thing can be used.

Upon receiving a preparation instruction signal from the control device 3 in the “standby state” in the “standby state”, the imaging device 2 configured as described above starts the imaging preparation and changes its state to the “capturable state”. Has a function to make a transition to "."
Here, the “standby state” refers to a state in which power supply to the scanning unit and the reading unit is stopped and an image cannot be generated immediately.
On the other hand, the “capturable state” refers to a state in which power can be supplied to the scanning unit and the reading unit to immediately read an image. That is, the photographing apparatus 2 in the photographable state repeats initialization, accumulation, and reading.

Further, the imaging device 2 has a function of transmitting a preparation completion signal to the control device 3 when the state of the imaging device 2 transitions to the “standby state”.
Further, the imaging device 2 has a function of generating a radiation image based on receiving an exposure interlocking signal from the control device 3 described later.
When the still image capturing is set in the capturing system 100, the capturing device 2 generates only one radiation image because it receives the exposure interlocking signal only once.
On the other hand, when moving image capturing is set in the capturing system 100, the capturing device 2 repeatedly receives the exposure interlocking signal, and thus repeatedly generates a plurality of radiation images (frames).
In addition, the imaging device 2 changes the state of the imaging device 2 to the “standby state” based on a predetermined condition being satisfied in the “standby state” (for example, the imaging is completed, a predetermined time has elapsed without operation, or the like). It has a function to make a transition.

The control device 3 is connected to the generator 1, the imaging device 2, and the console 4, respectively, and is configured to be able to control the connected devices 1 and 2.
In addition, it is good also as a structure connected only to any one of the generator 1 and the imaging device 2 as needed.
Details of the control device 3 will be described later.

The console 4 is configured by a PC, a mobile terminal, or a dedicated device, and is configured to be able to communicate with the generation device 1, the imaging device 2, and the control device 3 by wire or wirelessly.
In addition, the console 4 can set imaging conditions for the generator 1 and the imaging device 2 based on an imaging order from another system (such as RIS) or an operation by a user.
The console 4 is configured to receive a radiation image from the imaging device 2 and display the received radiation image.
Note that the console 4 may have the function of the control device 3 and the console 4 and the control device 3 may be integrally configured.

〔Control device〕
Next, details of the control device 3 included in the photographing system 100 will be described. FIG. 2 is a block diagram illustrating a specific configuration of the control device 3.

  The control device 3 includes a housing 31, a first control unit 3a, and a second control unit 3b, for example, as shown in FIG.

The housing 31 is configured to be able to store the first control unit 3a and the second control unit 3b.
Further, the housing 31 according to the present embodiment has an opening that exposes at least a part of the first control unit 3a and at least a part of the second control unit 3b.
Details of this opening will be described later.

The first control unit 3a includes a first board 32, a first control unit 33 mounted on the first board 32, and a connection unit 34.
The first control unit 3a according to the present embodiment also includes a communication unit 35.
Further, each part of the first control unit 3a can be supplied with power by a power cable (not shown) or a built-in battery.

The first control unit 33 includes a CPU, a RAM, a semiconductor memory, and the like.
Then, the CPU reads various programs stored in the semiconductor memory, expands the programs in the RAM, executes various processes according to the expanded programs, and centrally controls the operations of the first control unit 3a and the respective units of the control device 3. It has become.
Note that a hard disk or the like may be connected to the first control unit 33 instead of including the semiconductor memory.

The communication unit 35 is configured by a network interface or the like, and is connected to another device (the generation device 1, the imaging device 2, the console, etc.) connected via a communication network such as a LAN (Local Area Network), a WAN (Wide Area Network), and the Internet. 4) can transmit various information (signals and data).
In addition, the communication unit 35 of the present embodiment includes a cable connector (hereinafter, first connector 35a) into which a cable for connecting to at least one of the generator 1 and the photographing device 2 can be inserted.
For example, when the first control unit 3a performs wireless communication with the generator 1 or the imaging device 2, or when the first control unit 3a is configured to perform communication via the second control unit 3b, The first connector 35a is unnecessary.

The first control unit 33 of the first control unit 3a that is configured in this way, common to necessary processing and still image shooting and moving image shooting, i.e. has the ability to perform processing necessary for at least the still image shooting ing.
For example, when the first stage of the exposure switch 12 is pressed, the first control unit 33 executes a process of instructing the imaging device 2 to start imaging preparation. Specifically, a process of transmitting a preparation instruction signal to the imaging device 2 is performed.
In addition, the first control unit 33 executes a process of transmitting the completion of the imaging preparation of the imaging device 2 to the generation device 1. Specifically, it has a function of transmitting a preparation completion signal to the generation device 1 when receiving a preparation completion signal from the imaging device 2.
Note that the first control unit 33 may perform processing other than those described above, or may execute one of the above-described two processings.

The connection unit 34 is configured to be able to connect the second control unit 3b.
The connection part 34 in the present embodiment is a board connector configured so that a second board 36 of a second control unit 3b described later can be inserted and removed. Can be changed as needed.
When the second control unit 3b is removed from the first control unit 3a, the first control unit 3a remains in the housing 31 as shown in FIG.

The second control unit 3b includes a second board 36 and a second control unit 37 mounted on the second board 36, and is configured to be detachable from the first control unit 3a.
Further, the second control unit 3b according to the present embodiment also includes a communication unit 38.
Each unit of the second control unit 3b can receive power supply via the connection unit 34.
Note that power may be directly supplied from a power cable (not shown) or a built-in battery without using the connection unit 34.

The communication unit 38 is configured by a network interface or the like, and is connected to another device (the generation device 1, the imaging device 2, etc.) via a communication network such as a LAN (Local Area Network), a WAN (Wide Area Network), and the Internet. And various kinds of information (signals and data) can be transmitted.
The communication unit 38 of the present embodiment includes a cable connector (hereinafter, a second connector 38a) into which a cable for connecting to at least one of the generator 1 and the photographing device 2 can be inserted.
For example, if the second control unit is configured to perform wireless communication with the generator 1 or the imaging device 2 or the second control unit is configured to perform communication via the first control unit, the second connector 38a is unnecessary.

The second control unit 37 of the second control unit 3b configured as described above has a function of executing processing required for moving image shooting.
For example, the second control unit 37 executes a process of notifying the imaging device 2 of which of still image shooting and moving image shooting is to be performed. Specifically, a signal instructing the setting of the photographing mode is transmitted to the photographing device 2.
Further, the second control unit 37 executes a process of generating an exposure interlocking signal based on at least one of a preset pulse width, a transmission interval, and the number of transmissions and transmitting the signal to the imaging device 2.
Note that the second control unit 37 may perform processing other than those described above, or may execute at least one of the above-described two processings.
Further, at least one of the above-described two processes or a process other than the above-described processes may be executed by the first control unit 3a.

In the imaging system 100 configured as described above, as shown in FIG. 2, the second control unit 3b is attached to the first control unit 3a (the second control unit 3b is connected to the connection unit 34). ,) in the case, the connected device 1, can be controlled to perform both still image photographing and moving image photographing.
On the other hand, when the second control unit 3b is removed from the first control unit 3a (the second control unit 3b is not connected to the connection unit 34), as shown in FIG. The connected devices 1 and 2 are controlled to perform still image shooting. Hereinafter, the imaging control device from which the first control unit 3a is removed is referred to as a control device 3A, and the radiation image imaging system to which the control device 3A is connected is referred to as an imaging system 100A.

(Opening of housing)
Next, details of the opening provided in the housing 31 of the control device 3 will be described. 4 is a front view of the opening 31a, FIG. 5 is a front view of the shielding member, FIG. 6 is a front view of the opening 31a when the shielding member is attached, and FIG. 7 is a cross-sectional view of FIG. .

As described above, the housing 31 according to the present embodiment has the opening 31a that exposes at least a part of the connector of the first control unit 3a and the connector of the second control unit 3b.
The mode (number, shape, size, etc.) of the opening 31a is not particularly limited. For example, as shown in FIG. 4A, the opening 31a faces the connectors 35a, 38a of the control units 3a, 3b. A plurality (e.g., a rectangle) of substantially the same shape as the end surfaces of the connectors 35a and 38a may be provided at the positions, or the connectors 35a of the control units 3a and 3b as shown in FIG. , 38a and one large substrate that exposes a part of each of the substrates 32, 36 together.

Although not shown, the opening 31a may be a plurality of connectors that respectively expose the connectors 35a and 38a of the control units 3a and 3b and a part of the boards 32 and 36, or may include a plurality of connectors. One unit that exposes only 35a and 38a collectively, or one that exposes at least a part of one control unit may be used.
In addition, here, as the opening 31a, only the first and second connectors, or the one that exposes the first and second connectors and a part of the first and second substrates 32 and 36 are illustrated. The whole unit may be exposed. In this way, by passing the second control unit 3b through the opening 31a, the second control unit 3b can be attached and detached without performing a complicated operation such as removing the housing 31.

By the way, when one of the control units is not provided with the connector, the second control unit is removed, or the periphery of the connector is also exposed, the shielding member 5 may be provided.
The shielding member 5 can be attached to the opening 31a and shields at least a part of the opening 31a. Specifically, when the opening 31a exposes only the connectors 35a and 38a as shown in FIG. 3A, for example, as shown in FIG. The entire 31a can be shielded. When the shielding member 5 is attached to the opening 31a, as shown in FIG. 6A, the entire one opening 31a is shielded.

On the other hand, when the opening 31a exposes a plurality of connectors collectively as shown in FIG. 3B, the opening 31a is substantially equal to the end face of the connector as shown in FIG. 5B. It may have a connector window 5a having a shape.
The connector window 5a exposes at least one connector when attached to the opening 31a. That is, as shown in FIG. 6B, there is only one connector window 5a, and as shown in FIGS. 6C and 7, there are a plurality of connector windows 5a.
By using such a shielding member 5, a cable can be inserted into the connectors 35a and 38a while preventing a foreign substance (moisture, dust, or the like) from entering the housing 31.

  As a method of attaching the shielding member 5 to the housing 31, for example, as shown in FIG. 8A, an elongated hole or a cut is formed in the housing 31 and the elongated hole or the cut in the housing 31 is adjacent to the elongated hole or the cut. The part is bent or punched in or out of the housing 31 by a predetermined angle (90 ° or less) to form a rail-shaped locking part 31b (the slot or cut becomes the opening 31a). 8B, the shielding member 5 is slid along the locking portion 31b, and as shown in FIG. 8B, the shielding member 5 is sandwiched between the locking portion 31b and other portions of the housing 31. No.

For example, as shown in FIG. 9A, a screw hole 31 c is formed in the housing 31, and a hole 5 b is also formed in a corresponding portion of the shielding member 5. The screw S may be screwed into the screw hole 31c such that the hole 31b overlaps the hole 31b.
Further, for example, as shown in FIG. 9B, a bolt shaft B is provided on the housing 31 so as to extend perpendicular to the surface of the housing 31, and a hole 5 b is provided at a corresponding position of the shielding member 5. May be formed, the shielding member 5 may be brought into contact with the housing 31 so that the shaft portion B passes through the hole 5b, and the nut N may be screwed into the shaft portion B.

In FIG. 5, the locking portion 31b is formed by forming a substantially H-shaped elongated hole. However, as long as the shielding member 5 can be sandwiched between the locking portion 31b and another portion, other locking portions 31b are formed. It may be shaped.
Further, although a part of the housing 31 is the locking portion 31b, another member (not shown) may be attached near the opening, and the shielding member 5 may be sandwiched between the housing and the other member.
Further, FIG. 6 illustrates the case where the shielding member 5 is screwed or nuted at two places, but may be one place or three or more places.
FIGS. 5 and 6 illustrate the case where the shielding member 5 is detachably attached to the housing 31. However, if it is not anticipated that the second control unit will be attached or detached in the future, the shielding member 5 may be detached. It may be adhered to the housing 31 or welded.

As described above, the control device 3 or the imaging system 100 according to the present embodiment can be configured as the control device 3A dedicated to still image shooting simply by removing the second control unit 3b from the first control unit 3a. Therefore, it is possible to cope with a user who desires the photographing system 100A dedicated to photographing still images.
On the other hand, the control device 3A or the photographing system 100A according to the present embodiment can be a control device 3 corresponding to moving image photographing simply by attaching the second control unit 3b to the first control unit 3a. Even in a facility where the photographing system 100A is introduced only for photographing, even if moving image photographing is to be introduced, it is possible to easily switch to the photographing system 100 that supports moving image photographing.
Further, the control device 3A dedicated to still image shooting and the control device 3 corresponding to moving image shooting according to the present embodiment share a first control unit 3a that controls still image shooting. For this reason, the maker can reduce the labor and cost of manufacturing and developing a control device dedicated to still image shooting and a control device compatible with moving image shooting.

REFERENCE SIGNS LIST 100, 100A radiation image capturing system 1 radiation generating device 11 generator 12 exposure switch 13 radiation source 2 radiation image capturing device 3, 3A imaging control device 31 housing 31a opening 31b locking portion 31c screw hole 3a first control unit 32 First board 33 First control unit 34 Connection unit 35 Communication unit 35a First connector 3b Second control unit 36 Second board 37 Second control unit 38 Communication unit 38a Second connector 4 Console 5 Shielding member 5a Connector window 5b Hole B Bolt Shaft N Nut S Screw

Claims (11)

A radiation control device capable of connecting to at least one of a radiation generating device capable of generating radiation and a radiation image capturing device capable of generating a radiation image corresponding to received radiation, and controlling the connected device. So,
A first control unit that performs at least processing required for still image shooting,
A second control unit configured to be detachably attached to the first control unit and performing a process required for moving image shooting,
If the second control unit is attached to the first control unit, the connected device is controlled to be able to perform both still image shooting and moving image shooting,
When the second control unit is removed from the first control unit, the connected device is controlled so as to perform still image shooting. Connectable to the radiation generating device and the radiation image capturing device,
The first control unit transmits, to the radiation generating apparatus, processing for instructing the radiation image capturing apparatus to start capturing preparation and processing completion of capturing of the radiation image capturing apparatus to the radiation generating apparatus, as the processing required for at least the still image capturing. The photographing control device according to claim 1, wherein at least one of the processes is executed. At least connectable to the radiation image capturing apparatus,
The method according to claim 1, wherein the second control unit executes a process of notifying the radiographic image capturing apparatus of which of a still image capturing and a moving image capturing is to be performed, as a process required for the moving image capturing. Or the imaging control device according to 2.   The second control unit generates an exposure interlocking signal based on at least one of a preset pulse width, a transmission interval, and the number of transmissions as a process required for the moving image capturing, and sends the signal to the radiation image capturing apparatus. The photographing control device according to claim 1, wherein the photographing control device performs transmission processing. The second control unit includes a board, and a control unit mounted on the board,
The photographing control device according to any one of claims 1 to 4, wherein the first control unit includes a board connector configured to be able to insert and remove the board. Comprising a housing for storing the first control unit and the second control unit,
The said housing | casing has the opening which exposes at least one part of at least one control unit of the said 1st control unit and the said 2nd control unit, The any one of Claim 1 to 5 characterized by the above-mentioned. 9. The photographing control device according to claim 1.   The photographing control device according to claim 6, wherein a plurality of the openings are provided corresponding to the positions of the respective control units. At least one control unit of the first control unit and the second control unit includes a cable connector capable of inserting a cable for connecting to at least one of the radiation generating device and the radiation image capturing device,
The photographing control device according to claim 6, wherein the opening exposes the cable connector.   The photographing control device according to claim 8, further comprising a shielding member that can be attached to the opening and that shields at least a part of the opening when attached to the opening. A radiation control device capable of connecting to at least one of a radiation generating device capable of generating radiation and a radiation image capturing device capable of generating a radiation image corresponding to received radiation, and controlling the connected device. So,
A first control unit that performs at least processing required for still image shooting,
A connection unit that is provided in the first control unit and that can connect a second control unit that executes processing required for moving image shooting,
When the second control unit is connected to the connection unit, the connected device is controlled to be able to perform both still image shooting and moving image shooting,
When the second control unit is not connected to the connection unit, the control unit controls the connected device to perform still image shooting. A radiation generator capable of generating radiation,
A radiation image capturing device capable of generating a radiation image according to the received radiation,
Radiation image capturing system characterized by and a photographing control apparatus according to any one of claims 1 to 10.

Images